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Kidney cancer includes renal cell carcinoma, renal pelvis carcinoma, and Wilms' tumor, which is a type of kidney cancer that usually develops in children under age 5. Learn about childhood kidney cancer and find information on how we support and care for children with kidney cancer before, during, and after treatment.
The Solid Tumor Center at Dana-Farber/Boston Children's Cancer and Blood Disorders Center treats children and teens with a variety of solid malignancies, including bone and soft tissue tumors, liver and kidney tumors, neuroblastomas, retinoblastomas and rare tumors. Our doctors provide unparalleled expertise in the diagnosis, treatment and management of these diseases.
Your child's care team will include pediatric oncologists, radiation oncologists, surgeons, pathologists, radiologists, and nurses with expertise in treating your child's specific type of cancer.
Our physicians are focused on family-centered care: From your first visit, you'll work with a team of professionals who are committed to supporting your family's needs. We consider you and your child integral parts of the care team. Our specialists will collaborate with you to customize a treatment plan that takes the needs of your child and your family into account.
As well as providing access to a range of innovative clinical trials through Dana-Farber/Boston Children's, we are New England's Phase I referral center for the Children's Oncology Group, which means we're able to offer clinical trials unavailable at other regional centers.
Your child will have access to long-term treatment and childhood cancer survivor support through Dana-Farber's David B. Perini, Jr. Quality of Life Clinic.
From diagnosis through treatment and survivorship, our team will be able to answer all of your questions about your child's care.
Find out more about our Solid Tumor Center, including the diseases we treat and our specialized programs for bone and soft tissue tumors, liver tumors, neuroblastoma, rare tumors, and retinoblastoma.
Wilms’ tumor and other kidney tumors are diseases in which malignant (cancer) cells are found in the kidney. In Wilms’ tumor, one or more tumors may be found in one or both kidneys. There are two kidneys, one on each side of the backbone, above the waist. Tiny tubules in the kidneys filter and clean the blood, taking out waste products and making urine. The urine passes from each kidney through a long tube called a ureter into the bladder. The bladder holds the urine until it is passed from the body.Wilms’ tumor may spread to the lungs, liver, or nearby lymph nodes.Nephroblastomatosis is a condition in which abnormal tissue grows on the outer part of one or both kidneys. Children with this condition are at risk for developing a type of Wilms’ tumor that grows quickly. Frequent follow-up testing is important for at least seven years after the child is treated.
Other childhood kidney tumors, which are diagnosed and treated in different ways, include:
Anything that increases the risk of getting a disease is called a risk factor. Having a risk factor does not mean that you will get cancer; not having risk factors doesn't mean that you will not get cancer. Parents who think their child may be at risk should discuss this with the child's doctor.Wilms’ tumor may be part of a genetic syndrome that affects growth or development. A genetic syndrome is a set of symptoms or conditions that occur together and is usually caused by abnormal genes. Certain birth defects can also increase a child's risk for developing Wilms’ tumor. The following genetic syndromes and birth defects have been linked to Wilms’ tumor:
Children with these genetic syndromes and birth defects should be screened for Wilms’ tumor every three months until age 8. An ultrasound test may be used for screening.Having certain conditions may be associated with renal cell carcinoma.Renal cell carcinoma may be related to the following conditions:
Possible signs of Wilms’ tumor and other childhood kidney tumors include a lump in the abdomen and blood in the urine.These and other symptoms may be caused by kidney tumors. Other conditions may cause the same symptoms. A doctor should be consulted if any of the following problems occur in the child:
The following tests and procedures may be used:
Once a kidney tumor is found, surgery is done to find out whether or not the tumor is cancer. If the tumor is only in the kidney, the surgeon will remove the whole kidney (nephrectomy). If there are tumors in both kidneys or if the tumor has spread outside the kidney, a piece of the tumor will be removed. In any case, a sample of tissue from the tumor is sent to a pathologist, who looks at it under a microscope to check for signs of cancer.
The prognosis (chance of recovery) and treatment options depend on the following:
Cancer in children and adolescents is rare, although the overall incidence of childhood cancer has been slowly increasing since 1975. Children and adolescents with
cancer need to be referred to medical centers that have multidisciplinary teams
of cancer specialists with experience treating the cancers that occur during
childhood and adolescence. This multidisciplinary team approach incorporates
the skills of the primary care physician, pediatric surgical subspecialists,
radiation oncologists, pediatric medical oncologists/hematologists,
rehabilitation specialists, pediatric nurse specialists, social workers, and
others to ensure that children receive treatment, supportive care, and
rehabilitation that will achieve optimal survival and quality of life. (Refer to the PDQ Supportive and Palliative Care summaries for more information.)
Guidelines for pediatric cancer centers and their role in the treatment of
pediatric patients with cancer have been outlined by the American Academy of
Pediatrics. At these pediatric cancer centers, clinical trials are
available for most of the types of cancer that occur in children and
adolescents, and the opportunity to participate in these trials is offered to
most patients/families. Clinical trials for children and adolescents with
cancer are generally designed to compare potentially better therapy with
therapy that is currently accepted as standard. Most of the progress
made in identifying curative therapies for childhood cancers has been achieved
through clinical trials under the auspices of cooperative groups such as the Children's Oncology Group (COG), the Children's Cancer and Leukaemia Group (CCLG), and the Société Internationale d’Oncologie Pédiatrique (SIOP). Information about ongoing clinical trials is
available from the NCI Web site.
Dramatic improvements in survival have been achieved for children and adolescents with cancer. Between 1975 and 2010, childhood cancer mortality decreased by more than 50%. For children younger than 15 years with Wilms tumor, the 5-year survival rate has increased over the same time from 74% to 88%. Childhood and adolescent cancer survivors require close monitoring because cancer therapy side effects may persist or develop months or years after treatment. (Refer to the PDQ summary on Late Effects of Treatment for Childhood Cancer for specific information about the incidence, type, and monitoring of late effects in childhood and adolescent cancer survivors.)
Childhood kidney cancers account for about 7% of all childhood cancers. Most childhood kidney cancers are Wilms tumor, but in the 15- to 19-year age group, most tumors are renal cell carcinoma. Wilms tumor can affect one kidney (unilateral) or both kidneys (bilateral). Other types of childhood kidney tumors include rhabdoid tumors, clear cell sarcoma, congenital mesoblastic nephroma, neuroepithelial tumors, desmoplastic small round cell tumor, cystic partially differentiated nephroblastoma, multilocular cystic nephroma, primary renal synovial sarcoma, and anaplastic sarcoma. Nephroblastomatosis of the kidney is a type of nonmalignant neoplasia.
Smith MA, Seibel NL, Altekruse SF, et al.: Outcomes for children and adolescents with cancer: challenges for the twenty-first century. J Clin Oncol 28 (15): 2625-34, 2010.
Guidelines for the pediatric cancer center and role of such centers in diagnosis and treatment. American Academy of Pediatrics Section Statement Section on Hematology/Oncology. Pediatrics 99 (1): 139-41, 1997.
Smith MA, Altekruse SF, Adamson PC, et al.: Declining childhood and adolescent cancer mortality. Cancer 120 (16): 2497-506, 2014.
Ahmed HU, Arya M, Levitt G, et al.: Part I: Primary malignant non-Wilms' renal tumours in children. Lancet Oncol 8 (8): 730-7, 2007.
Ahmed HU, Arya M, Levitt G, et al.: Part II: Treatment of primary malignant non-Wilms' renal tumours in children. Lancet Oncol 8 (9): 842-8, 2007.
The incidence of Wilms tumor is 7.1 cases per 1 million children younger than 15 years. Approximately 500 cases of Wilms tumor are diagnosed in the United States each year. The incidence is substantially lower in Asians. The male to female ratio in unilateral cases of Wilms tumor is 0.92:1.00, but in bilateral cases it is 0.60:1.00. The mean age at diagnosis is 44 months in unilateral cases of Wilms tumor and 31 months in bilateral cases. About 10% of children with Wilms tumor have an associated congenital malformation syndrome.
Wilms tumor typically develops in otherwise healthy children; however, approximately 10% of children with Wilms tumor have been reported to have a congenital anomaly. Of 295 consecutive patients with Wilms tumors seen at the Institute Curie in Paris, 52 (17.6%) had anomalies or syndromes, 43 of which were considered major, and 14 of which were genetically proven tumor predisposition syndromes. Children with Wilms tumors may have associated hemihypertrophy and urinary tract anomalies, including cryptorchidism and hypospadias. Children may have a recognizable phenotypic syndrome (including overgrowth, aniridia, genetic malformations, and others). These syndromes have provided clues to the genetic basis of the disease. The phenotypic syndromes and other conditions have been grouped into overgrowth and nonovergrowth categories. Overgrowth syndromes and conditions are the result of excessive prenatal and postnatal somatic
9q22.3 microdeletion syndrome
Familial Wilms tumor
Fanconi anemia with biallelic mutations in BRCA2 (FANCD1) or PALB2 (FANCN)
WAGR = Wilms tumor, aniridia, genitourinary anomaly, and mental retardation.
For information about the genes associated with Wilms tumor, including Wilms tumor 1 (WT1) and Wilms tumor 2 (WT2), refer to the Genes Associated With Wilms Tumor section of this summary.
Nonsyndromic causes of Wilms tumor include the following:
Two familial Wilms tumor genes have been localized to FWT1 (17q12-q21) and FWT2 (19q13.4). There are occasional Wilms tumor families with a germline mutation in WT1. In these families, most, but not all, family members have genitourinary tract malformations.
Wilms tumor (hereditary or sporadic) appears to result from changes in one or
more of at least ten genes. The changes may be somatic or germline. Several genes, but not all, will be discussed here.
Aberrations in germline or clonal WT1, WT2, and Wnt activation, when combined with stage of development of the nephron, characterize different subsets of Wilms tumor that can be differentiated by using gene expression profiling. This genetic/ontogenic categorization describes some of the heterogeneity among Wilms tumors.
The WT1 gene is located on the short arm of chromosome 11 (11p13). The normal function of WT1 is required for normal genitourinary development and is important for differentiation of the renal blastema.
When modern molecular genetic techniques are used in testing, the incidence of germline WT1 mutations is about 11%. Most of these mutations may be diagnosed, or at least highly suspected, on the basis of clinical syndromic findings at or before diagnosis of Wilms tumor. In a United Kingdom Children's Cancer Study Group study of patients entered in clinical trials, about 2% of Wilms tumor patients had germline mutations in WT1 but no genitourinary abnormalities, as detected by WT1 heteroduplex DNA screen followed by sequencing. These were mostly de novo mutations in children presenting before age 2 years, and the tumors were mostly unilateral with stromal histology. The relatively low number of reports of parent and child pairs with Wilms tumors and WT1 mutations may be the result of decreased fertility. However, the offspring of a child who has a parent with Wilms tumor and WT1 mutation will be at risk for developing Wilms tumor.
Germline WT1 mutations in children with Wilms tumors do not confer poor prognoses per se.
Because deletion of WT1 was the first mutation found to be associated with Wilms tumor, WT1 was assumed to be a conventional tumor suppressor gene. However, non-inactivating mutations can result in altered WT1 protein function that also results in Wilms tumor, such as in Denys-Drash syndrome.
WT1 mutations are more common in children with Wilms tumor and one of the following:
The observation that led to the discovery of WT1 was that children with WAGR syndrome (Wilms tumor, aniridia, genitourinary anomalies, and mental retardation) were at high risk (>30%) for developing Wilms tumor. Germline mutations were then identified at chromosome 11p13 in children with WAGR syndrome. Deletions involved a set of contiguous genes that included WT1 and the PAX6 gene.
Inactivating mutations or deletions in the PAX6 gene lead to aniridia, while deletion of WT1 confers the increased risk of Wilms tumor. Some of the sporadic cases of aniridia are caused by large chromosomal deletions that also include WT1. This results in a 67-fold increased relative risk (95% confidence interval [CI], 8.1–241) of developing Wilms tumor in children with sporadic aniridia. The incidence of Wilms tumor in children with sporadic aniridia is estimated to be about 5%. Seventy-seven percent of aniridia patients with submicroscopic WT1 deletions detectable by high-resolution fluorescence in situ hybridization (FISH) analysis presented with Wilms tumor compared with 42.5% of aniridia patients with visible deletions detected by microscopy. Patients with sporadic aniridia and a normal WT1 gene, however, are not at increased risk of developing Wilms tumor. Children with familial aniridia, generally occurring for many generations, and without renal abnormalities, have a normal WT1 gene and are not at an increased risk of Wilms tumor.
Children with WAGR syndrome or other germline WT1 mutations are at increased risk of
developing hypertension, nephropathy, and renal failure and are monitored throughout their lives. Patients with
Wilms tumor and aniridia without genitourinary abnormalities are at less
risk but are monitored for nephropathy or renal failure. Children with Wilms tumor and any genitourinary anomalies are also at increased risk for late renal failure and are monitored. Features associated with germline WT1 mutations that increase the risk of developing renal failure include the following:
Age at tumor diagnosis, frequency of bilaterality, and risk of late-onset renal compromise may vary with the type of mutation.
The mental retardation in WAGR syndrome may be secondary to deletion of other genes, including SLC1A2 or BDNF (brain-derived neurotrophic factor).
WT1 mutations and 11p15 loss of heterozygosity were associated with relapse in patients with very low-risk Wilms tumor in one study of 56 patients who did not receive chemotherapy. These findings await validation but may provide biomarkers by which to stratify patients in the future.
Activating mutations of the beta-catenin gene (CTNNB1) have been reported to occur in 15% of Wilms tumor patients. In one study, all but one tumor with a beta-catenin mutation had a WT1 mutation, and at least 50% of the tumors with WT1 mutations had a beta-catenin mutation. Activation of beta-catenin in the presence of intact WT1 protein appears to be inadequate to promote tumor development because CTNNB1 mutations are rarely found in the absence of a WT1 or WTX mutation. About one-third of Wilms tumors have a somatic mutation in WT1, WTX, and/or CTNNB1.
When modern molecular genetic techniques are used in testing, the incidence of germline WT2 aberrations is about 8%. Most of these aberrations may be diagnosed, or at least highly suspected, on the basis of clinical syndromic findings at or before diagnosis of Wilms tumor.
However, when 437 children with nonsyndromic Wilms tumor were screened for germline mutations in the WT2 locus, 13 mutations (3% of patients) were found. None of these children had signs of Beckwith-Wiedemann syndrome, although they did have a higher frequency of bilateral tumors and perilobar nephrogenic rests. All were de novo abnormalities, except one novel microdeletion in one child, and their mother was not affected. A similar mutation at the WT2 locus was found in 1 of 22 familial Wilms tumor families tested.
A second Wilms tumor locus, WT2, maps to an imprinted region of chromosome 11p15.5, which, when it is a germline mutation, causes the Beckwith-Wiedemann syndrome. About 3% of children with Wilms tumors have germline epigenetic or genetic changes at the 11p15.5 growth regulatory locus without any clinical manifestations of overgrowth. Like children with Beckwith-Wiedemann syndrome, these children have an increased incidence of bilateral Wilms tumor or familial Wilms tumor.
Several candidate genes at the WT2 locus comprise the two independent imprinted domains IGF2/H19 and KIP2/LIT1. Loss of heterozygosity, which exclusively affects the maternal chromosome, has the effect of upregulating paternally active genes and silencing maternally active ones. A loss or switch of the imprint for genes (change in methylation status) in this region has also been frequently observed and results in the same functional aberrations. A study of 35 sporadic primary Wilms tumors suggests that more than 80% have somatic loss of heterozygosity or loss of imprinting at 11p15.5. The mechanism resulting in loss of imprinting can be either genetic mutation or epigenetic change of methylation. Loss of imprinting or gene methylation is rarely found at other loci, supporting the specificity of loss of imprinting at 11p15.5. Interestingly, Wilms tumors in Asian children are not associated with either nephrogenic rests or IGF2 loss of imprinting.
Beckwith-Wiedemann syndrome results from loss of imprinting or heterozygosity of WT2 germline mutations. Observations suggest genetic heterogeneity in the etiology of Beckwith-Wiedemann syndrome, with differing levels of association with risk of tumor formation. Approximately one-fifth of patients with Beckwith-Wiedemann
syndrome who develop Wilms tumor present with bilateral disease, and metachronous bilateral disease is also observed. The prevalence of Beckwith-Wiedemann syndrome is about 1% among children with Wilms tumor reported to the National Wilms Tumor Study (NWTS).
A relationship between epigenotype and phenotype has been shown in Beckwith-Wiedemann syndrome, with a different rate of cancer in Beckwith-Wiedemann syndrome according to the type of alteration of the 11p15 region. The overall tumor risk in Beckwith-Wiedemann syndrome was estimated between 5% and 10%, with a risk between 1% (loss of imprinting at IC2) and 30% (gain of methylation at IC1 and paternal 11p15 isodisomy). Patients with IC1 gain of methylation only developed Wilms tumor, whereas other tumors such as neuroblastoma or hepatoblastoma could occur in patients with paternal 11p15 isodisomy.
A third gene, WTX, has been identified on the X chromosome and plays a role in normal kidney development. This gene is inactivated in approximately one-third of Wilms tumors, but germline mutations have not been observed in patients with Wilms tumor.WTX mutations are equally distributed between males and females. WTX inactivation is a frequent, but late, event in tumorigenesis and has no apparent effect on clinical presentation or prognosis.
Additional genes have been implicated in the pathogenesis and biology of Wilms tumor, including the following:
In an analysis of 212 patients from NWTS-4 and the Pediatric Oncology Group Wilms Biology study, 27% of patients displayed 1q gain. A strong relationship between 1q gain and 1p/16q loss was observed. The 8-year event-free survival (EFS) rate was 76% (95% CI, 63%–85%) for patients with 1q gain and 93% (95% CI, 87%–96%) for those lacking 1q gain (P = .0024). The 8-year overall survival (OS) rate was 89% (95% CI, 78%–94%) for those with 1q gain and 98% (95% CI, 94–99%) for those lacking 1q gain (P = .0075). Gain of 1q was not found to correlate with disease stage. After stratification for stage of disease, 1q gain was associated with a significantly increased risk of disease recurrence (risk ratio estimate, 2.72; P = .0089).
Similar results have been reported by European investigators.
These conflicting results may arise from the greater prognostic significance of 1q gain described above. The loss of heterozygosity of 16q and 1p appear to arise from complex chromosomal events that result in 1q loss of heterozygosity or 1q gain. The change in 1q appears to be the critical tumorigenic genetic event.
The pathology of WT1-associated and DICER1-associated Wilms tumors appears to differ. WT1-associated Wilms tumors are often stromal rich, with rhabdomyomatous differentiation and intralobar nephrogenic rests that are thought to occur early in renal development, while DICER1-associated Wilms tumors are triphasic with abundant blastema and are not associated with nephrogenic rests.
Approximately 5% to 10% of individuals with Wilms tumor have bilateral or multicentric tumors. The prevalence of bilateral involvement is higher in individuals with genetic predisposition syndromes than in those without predisposition syndromes; however, 85% of individuals with WAGR or Beckwith-Wiedemann syndrome have unilateral tumors.
Only 16% of persons with bilateral Wilms tumor have a WT1 germline mutation, and only 3% of persons with bilateral Wilms tumors have affected family members. Bilateral Wilms tumor with WT1 mutations are associated with early presentation in pediatric patients (age 10 months vs. age 39 months for those without a mutation) and a high frequency of WT1 nonsense mutations in exon 8. The presence of bilateral or multifocal disease implies that a patient has a genetic predisposition for Wilms tumor.
Children with a significantly increased predisposition to develop Wilms tumor (e.g.,
most children with Beckwith-Wiedemann syndrome or other overgrowth syndromes, WAGR syndrome, Denys-Drash syndrome, sporadic aniridia, or isolated hemihypertrophy) are usually screened with ultrasound every 3
months at least until they reach age 8 years. Early-stage, asymptomatic, small Wilms tumors may be discovered and potentially removed with renal-sparing surgery.
Tumor screening programs for each overgrowth syndrome have been suggested, based on published age and incidence of tumor type. Approximately 10% of patients with Beckwith-Wiedemann syndrome will develop a malignancy, with the most common being either Wilms tumor or hepatoblastoma, although adrenal tumors can also occur. Children with hemihypertrophy are also at risk for developing liver and adrenal tumors. Screening with abdominal ultrasound and serum alpha-fetoprotein is suggested until age 4 years. After age 4 years, most hepatoblastomas will have occurred, and imaging may be limited to renal ultrasound, which is quicker and does not require fasting before the exam.
Newborns born with sporadic aniridia should undergo molecular testing for deletion analysis of PAX 6 and WT1. If a deletion of WT1 is observed, the child should be screened with ultrasound every 3 months until age 8 years, and the parents should be educated about the need to identify and treat early Wilms tumor.
Although the risk for Wilms tumor in the children of survivors of bilateral Wilms tumor is unknown and likely varies with the gene in which the mutation occurred, some experts recommend screening such children with serial ultrasound examinations every 3 months until age 8 years.
The risk of Wilms tumor in children with Klippel-Trénaunay syndrome (a unilateral limb overgrowth syndrome) was no different than the risk in the general population when assessed using the NWTS database. Routine ultrasound surveillance is not recommended.
The frequency of malformations observed in patients with Wilms tumor underlines the need for genetic counseling, molecular and genetic explorations, and follow-up.
A French study  concluded that patients need to be referred for genetic counseling if they have one of the following:
Simple oncological follow-up is indicated when there is no malformation or when there is only one minor malformation.
After genetic counseling takes place, a search for WT1 mutations should be considered for patients who have the following:
A search for an 11p15 abnormality should be considered for patients exhibiting any symptoms of Beckwith-Wiedemann syndrome, hemihypertrophy, or bilateral or familial Wilms tumor.
The following symptoms may be caused by Wilms or other childhood kidney tumors:
Children with Wilms tumors or other renal malignancies may also come to medical attention as a result of the following:
About 5% of renal masses thought to be Wilms tumor on the basis of clinical and radiological findings are diagnosed as another condition. The German Pediatric Oncology study group entered 188 patients on the SIOP-9 trial from 1988 to 1991. However, only 136 patients received preoperative chemotherapy because imaging was regarded as atypical on central review. Nine of the 188 patients (5%) had other diagnoses, including benign tumors and renal cell carcinoma.
Tests and procedures used to evaluate and stage Wilms tumor and other childhood kidney tumors include the following:
Biopsy of a renal mass may be indicated if the mass is atypical by radiographic appearance for Wilms tumor, and the patient is not going to undergo immediate nephrectomy. Biopsy tissue from inoperable Wilms tumor obtained before chemotherapy may be used for histologic review and initial treatment decisions. The use of biopsy to determine histology in an inoperable tumor remains controversial because biopsy may cause local tumor spread. It is important to recognize that data from NWTS-4 and NWTS-5 have shown conclusively that, because of histologic heterogeneity of Wilms tumor, a significant number of patients have unfavorable histology that is missed during an upfront biopsy but revealed at the time of definitive surgery following chemotherapy.
If the initial imaging studies suggested a possible lesion on the contralateral kidney, the contralateral kidney is formally
explored to rule out bilateral involvement. This is done before nephrectomy to exclude
bilateral Wilms tumor.
Biopsy is also controversial in patients with bilateral tumors because biopsy rarely detects anaplasia in bilateral Wilms tumor, and the incidence of bilateral tumors being other than Wilms is very low. The current COG study of bilateral Wilms tumor and of patients with unilateral Wilms tumor predisposed to developing bilateral tumors tries to avoid initial biopsy and mandates biopsy after 6 weeks of three-drug chemotherapy.
Children with a renal mass are carefully assessed for signs of associated syndromes such as aniridia, developmental delay, hypospadias, cryptorchidism, pseudohermaphrodism, overgrowth, and hemihypertrophy.
For patients with suspected Wilms tumor, preoperative staging studies include a CT or MRI scan of the abdomen/pelvis and chest to assess intravascular extension or rupture of Wilms tumor.
In North America, local staging of Wilms tumor is performed with CT or MRI of the abdomen and pelvis. Contrast-enhanced CT for Wilms tumor patients has high sensitivity and specificity for detection of cavoatrial tumor thrombus that may impact surgical approach. Routine Doppler evaluation after CT has been performed but is not necessarily required. Large tumor thrombi need to be controlled before surgical approach to the renal mass.
Wilms tumor is a curable disease in most affected children.
Since the 1980s, the 5-year survival rate for Wilms tumor with FH has been consistently above 90%. This favorable outcome occurred despite reductions in the length of therapy, dose of radiation, extent of fields irradiated, and the percentage of patients receiving radiation therapy.
The prognosis for patients with Wilms tumor depends on the following:
In an analysis of Wilms tumor patients in the Surveillance, Epidemiology, and End Results (SEER) database, adults (n = 152) had a statistically worse OS (69% vs. 88%, P < .001) than did pediatric patients (n = 2,190), despite previous studies showing comparable outcome with treatment on protocol. The inferior outcome of the adult patients on this study may be the result of differences in tumor biology between children and adults, incorrect diagnosis, inadequate staging (e.g., more likely to be staged as localized disease or to not receive lymph node sampling), or undertreatment (e.g., not receiving radiation therapy). Additional factors in this SEER report that may have contributed to a worse OS in adult patients include the size of the study and lack of central review of pathology. Adolescent and young adult patients up to age 30 years are now eligible for treatment on the COG Wilms tumor protocols.
The inferior outcome of older patients is not explained entirely by inadequate treatment or not being treated according to the pediatric Wilms tumor protocol. In a U.K. study looking at the outcome of patients aged 10 to 16 years (N = 50) registered on the U.K. Wilms Tumor 3 and SIOP 2001 Wilms tumor trials, patients in this age group had a higher percentage of diffuse anaplastic tumors. The overall 5-year survival was 63% for patients aged 10 to 16 years (43% for anaplastic tumors), which is significantly lower than the outcome for younger patients with Wilms tumor. However, SEER 5-year relative survival of nephroblastoma between 2003 and 2009 did not show differences among age groups from younger than 1 year to age 10 to 14 years.
Although most patients with a histologic diagnosis of Wilms tumor do well
with current treatment, approximately 10% of patients have histopathologic
features that are associated with a worse prognosis, and in some types, with
a high incidence of relapse and death. Wilms tumor can be separated into the following two
prognostic groups on the basis of tumor and kidney histopathology:
Histologically, Wilms tumor mimics the triphasic development of a normal kidney
consisting of blastemal, epithelial (tubules), and stromal cell types. Not all tumors are triphasic, and monophasic patterns may present diagnostic difficulties.
While associations between histologic features and prognosis or responsiveness to therapy have been suggested, with the exception of anaplasia, none of these features have reached statistical significance in North American treatment algorithms, and therefore, do not direct the initial therapy.
Anaplastic histology accounts for about 10% of Wilms tumors. Anaplastic histology is the single most important histologic predictor of response and survival in patients with Wilms tumor. Tumors occurring in older patients (aged 10–16 years) have a higher incidence of anaplastic histology. In bilateral tumors, 12% to 14% have been reported to have anaplastic histology in one kidney.
The following two histologic criteria must be present for the diagnosis of anaplasia:
Changes on 17p consistent with mutations in the p53 gene have been associated with foci of anaplastic histology. Focal anaplasia is defined as the presence of one or more sharply localized regions of anaplasia in a primary tumor. All of these factors lend support to the hypothesis that anaplasia evolves as a late event from a subpopulation of Wilms tumor cells that have acquired additional genomic lesions. Focal anaplasia does not confer as poor a prognosis as does diffuse anaplasia.
Anaplasia correlates best with responsiveness to therapy rather than to tumor aggressiveness. It is most consistently associated with poor prognosis when it is diffusely distributed and when
identified at advanced stages. These tumors are more resistant to the chemotherapy traditionally used in children with FH Wilms tumor.
Nephrogenic rests are abnormally retained embryonic kidney precursor cells arranged in clusters. Nephrogenic rests are found in about 1% of unselected pediatric autopsies, 35% of kidneys with unilateral Wilms tumors, and nearly 100% of kidneys with bilateral Wilms tumors.
The term nephroblastomatosis is defined as the presence of diffuse or multifocal nephrogenic rests. There are two types: intralobar nephrogenic rests and perilobar nephrogenic rests. Diffuse hyperplastic perilobar nephroblastomatosis is defined as nephroblastomatosis forming a thick rind around one or both kidneys and is considered a preneoplastic condition.
The type and percentage of nephrogenic rests vary in patients with unilateral or bilateral disease. Patients with bilateral Wilms tumor have a higher proportion of perilobar rests (52%)
than of intralobar or combined rests (32%) and higher relative proportions of rests, compared with patients with unilateral tumors (18% perilobar and 20% intralobar or both).
Patients with any type of nephrogenic rest in a kidney removed for nephroblastoma are considered at increased risk for tumor formation in the remaining kidney. This risk decreases with patient age.
Extrarenal nephrogenic rests are rare and may develop into extrarenal Wilms tumor.
Both the results of the imaging studies and the surgical and pathologic findings at nephrectomy are used to determine the stage of disease. The stage is the same for tumors with FH or anaplastic histology. Thus, the stage
information is characterized by a statement of both criteria (for example, stage II,
FH or stage II, anaplastic histology).
The staging system was originally developed by the NWTS Group and is still used by the COG. The staging system and incidence by stage are outlined below.
In stage I Wilms tumor (43% of patients), all of the following criteria must be met:
For a tumor to qualify for certain therapeutic protocols such as very low-risk stage I, regional lymph nodes must be examined microscopically. Lymph node sampling is recommended for all patients.
In stage II Wilms tumor (20% of patients), the tumor is completely resected, and there is no evidence of tumor at or beyond the margins of resection. The tumor extends beyond the kidney as evidenced by any one of the following criteria:
Rupture or spillage confined to the flank, including biopsy of the tumor, is now included in stage III by the COG Renal Tumor Committee; however, data to support this approach are controversial.
In stage III Wilms tumor (21% of patients), there is postsurgical residual nonhematogenous tumor that is confined to the abdomen. Any one of the following may occur:
Lymph node involvement and microscopic residual disease are highly predictive of outcome in patients with stage III FH Wilms tumor.
In stage IV Wilms tumor (11% of patients), hematogenous metastases (lung, liver, bone, brain) or lymph node metastases outside the abdominopelvic region are present. The presence of tumor within the adrenal gland is not interpreted as metastasis and staging depends on all other staging parameters present. According to the criteria described above, the primary tumor is assigned a local stage, which determines local therapy. For example, a patient may have stage IV, local stage III disease.
In stage V Wilms tumor (5% of patients), bilateral involvement by tumor is present at diagnosis. A previous attempt was made to stage each side according to the above criteria on the basis of the extent of disease. The ongoing COG-AREN0534 protocol is testing the approach of preoperative chemotherapy without local biopsy in hopes of reducing tumor size to allow renal-sparing surgical procedures. In these patients, renal failure rates approach 15% at 15 years posttreatment, making renal-sparing treatment important.
Because of the relative rarity of Wilms tumor, all patients with this tumor
should be considered for entry into a clinical trial. Treatment planning by a
multidisciplinary team of cancer specialists (pediatric surgeon and/or pediatric
urologist, pediatric radiation oncologist, and pediatric oncologist) who have
experience treating Wilms tumor is necessary to determine and implement optimal
Most randomized clinical studies for treatment of children with Wilms tumor have been conducted by two large clinical groups. There are differences between the two groups that affect staging and classification.
This summary focuses on the NWTS (now COG Renal Tumor Committee) results and studies.
The major treatment and study conclusions of
NWTS-1 through NWTS-5 are as follows:
The following operative principles have also evolved from NWTS trials:
Renal-sparing surgery remains controversial and is not recommended, except for children with the following:; [Level of evidence: 3iiB]
The use of renal-sparing surgery for bilateral tumors is under investigation.
Renal-sparing surgery does not appear to be feasible in most patients at the time of diagnosis because of the location of the tumor within the kidney, even in those with very low risk. In North America, renal-sparing surgery (partial nephrectomy) of unilateral Wilms tumor following administration of chemotherapy to shrink the tumor mass is considered investigational.
Hilar and periaortic lymph node sampling is appropriate even if the nodes appear normal. Furthermore, any suspicious node basin is sampled. Margins of
resection, residual tumor, and any suspicious node basins are marked with
Wilms tumor rarely invades adjacent organs; therefore, resection of contiguous organs is rarely indicated. There is an increased incidence of complications occurring in more extensive resections that involve removal of additional organs beyond the diaphragm and adrenal gland. This has led to the recommendation in current COG protocols that these patients should be considered for initial biopsy, neoadjuvant chemotherapy, and then secondary resection. Primary resection of liver metastasis is not recommended.
Preoperative chemotherapy before nephrectomy is indicated in the following situations:
Preoperative chemotherapy follows a biopsy unless the patient is being treated on COG-AREN0534. The biopsy may be
performed through a flank approach. Preoperative chemotherapy includes doxorubicin in addition to vincristine and dactinomycin unless anaplastic histology is present; in such cases, then chemotherapy includes treatment with regimen I (refer to Table 2 below). The chemotherapy generally makes tumor
removal easier by decreasing the size and vascular supply of the tumor; it may also reduce the frequency of surgical
In North America, the use of preoperative chemotherapy in patients with evidence of a contained preoperative rupture has been suggested to avoid intraoperative spill, but this is controversial. The preoperative diagnosis of a contained retroperitoneal rupture on CT is difficult, even for experienced pediatric radiologists. The routine use of preoperative chemotherapy would lead to overtreatment in a significant number of these children.
Newborns and all infants younger than 12 months who will be treated with chemotherapy require a 50% reduction in
chemotherapy dose compared with the dose given to older children. This reduction
diminishes the toxic effects reported in children in this age group enrolled in
NWTS studies while maintaining an excellent overall outcome.
function tests in children with Wilms tumor are monitored closely during
the early course of therapy because hepatic toxic effects (sinusoidal obstructive syndrome, previously called veno-occlusive
disease) have been reported in these patients. Dactinomycin or doxorubicin should not be
administered during radiation therapy. Patients who develop renal failure while undergoing therapy can continue receiving chemotherapy with vincristine, dactinomycin, and doxorubicin. Vincristine and doxorubicin can be given at full doses; however, dactinomycin is associated with severe neutropenia. Reductions in dosing these agents may not be necessary, but accurate pharmacologic and pharmacokinetic studies are needed while the patient is receiving therapy.
Postoperative radiation therapy to the tumor bed is required when a biopsy is performed or in the setting of local tumor stage III.
Table 2 describes the standard chemotherapy regimens used to treat Wilms tumor.
Regimen EE-4A 
Vincristine, dactinomycin × 18 weeks postnephrectomy
Regimen DD-4A 
Vincristine, dactinomycin, doxorubicin × 24 weeks; baseline nephrectomy or biopsy with subsequent nephrectomy
Regimen I 
Vincristine, doxorubicin, cyclophosphamide, etoposide × 24 weeks postnephrectomy
Table 3 provides an overview of the standard treatment and survival data for stage I Wilms tumor, based on published results.
4-Year RFS or EFS
Treatment (refer to Table 2 for chemotherapy regimen descriptions)
Stage I 
FH <24 mo/tumor weight <550g
Surgery only (not standard treatment; should be done only in the context of a clinical trial)
FH >24 mo/tumor weight >550g
Nephrectomy + lymph node sampling followed by regimen EE-4A
Nephrectomy + lymph node sampling followed by regimen EE-4A and XRT
79% (n = 10)
Nephrectomy + lymph node sampling followed by regimen EE-4A and XRT
DA = diffuse anaplastic; EFS = event-free survival; FA = focal anaplastic; FH = favorable histology; OS = overall survival; RFS = relapse-free survival; XRT = radiation therapy.
aFewer than five patients have survived 4 years; therefore, results should be interpreted with caution.
The COG addressed the question of whether a subset of stage I Wilms tumor patients could be treated with surgery alone. The NWTS-5 (COG-Q9401/NCT00002611) trial investigated this approach for children younger than 2 years at diagnosis with stage I FH Wilms tumors that weigh less than 550 g.
Evidence (surgery only for children younger than 24 months at diagnosis with stage I FH tumor that weighed <550 g):
Table 4 provides an overview of the standard treatment and survival data for stage II Wilms tumor, based on published results.
Stage II 
Nephrectomy + lymph node sampling followed by regimen EE-4A
80% (n = 5)
Nephrectomy + lymph node sampling followed by abdominal XRT and regimen DD-4A
Nephrectomy + lymph node sampling followed by abdominal XRT and regimen I
On NWTS-3 through NWTS-5, patients with intraoperative spill were divided into two groups: (1) those with diffuse spillage involving the whole abdominal cavity; and (2) those with local spillage confined to the flank. Patients with diffuse spillage were treated with radiation therapy to the entire abdomen and three-drug chemotherapy (vincristine, dactinomycin, and doxorubicin), whereas patients with local spillage were treated with vincristine and dactinomycin only. On the basis of an analysis of patients treated on NWTS-3 and NWTS-4 indicating that patients with stage II disease and local spillage had inferior OS compared with patients with stage II disease without local spillage, ongoing COG studies treat patients with local spillage with doxorubicin and flank radiation. This approach is controversial and has not been tested; therefore, it should not be considered standard.
In a review of 499 patients from NWTS-4 with stage II, FH Wilms tumor, 95 of the patients experienced tumor spill. The 8-year RFS and OS for patients who experienced tumor spill and were treated with vincristine and dactinomycin without flank radiation therapy was lower, at 75.7% and 90.3%, than the 85% and 95.6% rates for those who did not experience tumor spill. None of these differences achieved statistical significance.
Table 5 provides an overview of the standard treatment and survival data for stage III Wilms tumor, based on published results.
Stage III 
Nephrectomy + lymph node sampling followed by abdominal XRT and regimen DD-4A
100% (n = 8)
FA (preoperative treatment)
71% (n = 7)
Preoperative treatment with regimen DD-4A followed by nephrectomy + lymph node sampling and abdominal XRT
53% (n = 16)
Preoperative treatment with regimen I followed by nephrectomy + lymph node sampling and abdominal XRT
Immediate nephrectomy + lymph node sampling followed by abdominal XRT and regimen I
The outcome of patients with peritoneal implants treated with gross resection, three-drug chemotherapy, and total-abdominal radiation (10.5 Gy) is similar to that of other stage III patients.[Level of evidence: 2A]
For patients classified as stage III purely on the basis of local spill, refer to the Standard treatment options for stage II Wilms tumor section of this summary.
Table 6 provides an overview of the standard treatment and survival data for stage IV Wilms tumor, based on published results.
Stage IV 
Nephrectomy + lymph node sampling, followed by abdominal XRT,a radiation to sites of metastases, bilateral pulmonary XRT,b and regimen DD-4A
72% (n = 11)
33% (n = 15)
Immediate nephrectomy + lymph node sampling followed by abdominal XRT,a radiation to sites of metastases, whole-lung XRT,b and regimen I
DA (preoperative treatment)
44% (n = 13)
Preoperative treatment with regimen I followed by nephrectomy + lymph node sampling, followed by abdominal XRT,a radiation to sites of metastases, and whole-lung XRTb
DA = diffuse anaplasia; EFS = event-free survival; FA = focal anaplasia; FH = favorable histology; OS = overall survival; RFS = relapse-free survival; XRT = radiation therapy.
aAbdominal XRT is planned according to local stage of renal tumor.
bPulmonary XRT is reserved for patients with chest X-ray/chest CT evidence of pulmonary metastases.
Stage IV disease is defined by the presence of hematogenous metastases to the lung, liver, bone, brain, or other sites, with the lung being the most common site. Historically, chest X-rays were used to detect pulmonary metastases. The introduction of CT created controversy because many patients had lung nodules detected by chest CT scans that were not seen on chest X-rays. Management of newly diagnosed patients with FH Wilms tumor who have lung nodules detected only by CT scans (with negative chest X-ray) has elicited controversy as to whether they need to be treated with additional intensive treatment that is accompanied by acute and late toxicities.
Evidence (treatment of pulmonary nodules detected by chest CT scan only):
The issue of whether radiation can be omitted in patients with FH Wilms tumor and pulmonary metastases (identified by chest CT scans) has been studied prospectively in North America in the COG-AREN0533 trial. COG-AREN0533 patients underwent 6 weeks of chemotherapy consisting of vincristine, dactinomycin, and doxorubicin and were reevaluated to assess the response of their pulmonary metastases. Patients whose pulmonary metastases had completely resolved were spared pulmonary irradiation and continued with the same chemotherapy. If the pulmonary metastases were still present at that time, patients were treated with chemotherapy in which cyclophosphamide and etoposide were added, and they also underwent pulmonary irradiation. The trial is closed, and results are pending.
Retrospective studies from Europe have examined the impact of omitting pulmonary radiation in patients with pulmonary metastases diagnosed by chest X-ray. European investigators omitted radiation from the treatment of most patients with Wilms tumor and pulmonary metastases as identified on chest X-ray who were treated on the SIOP-93-01 (NCT00003804) trial. The European approach to renal tumors differs from the approach used in North America. All patients who were shown to have a renal tumor by imaging underwent 9 weeks of prenephrectomy chemotherapy consisting of vincristine, dactinomycin, and doxorubicin.
Evidence (treatment of pulmonary nodules detected by chest X-ray):
It is important to note that patients in Europe receive higher cumulative doses of dactinomycin and doxorubicin before their pulmonary metastases are reevaluated than do patients in North America. The European experience cannot be directly applied to North America, although it suggests that for patients with nonanaplastic histology who are in a complete remission with chemotherapy, radiation may be omitted without impacting outcome.
The presence of liver metastases at diagnosis is not an independent adverse prognostic factor in patients with stage IV Wilms tumor.
Currently, there is not a standard approach for the treatment of stage V Wilms tumor (bilateral Wilms tumor at diagnosis) and those predisposed to developing Wilms tumor.
Management of a child with bilateral Wilms tumor is very challenging. The goals of therapy are to eradicate all tumor and to preserve as much normal renal tissue as possible, with the hope of decreasing the risk of chronic renal failure among these children.
In the NWTS-4 trial, bilateral Wilms tumor patients had a lower EFS and OS than did patients with localized Wilms tumor (including anaplastic histology), except for stage IV disease, in which OS was higher for patients with bilateral Wilms. The NWTS-4 study reported that the 8-year EFS for patients with bilateral FH Wilms tumor was 74% and the OS was 89%; for patients with anaplastic histology, the EFS was 40% and the OS was 45%. The NWTS-5 (COG-Q9401/NCT00002611) study reported the 4-year EFS for bilateral Wilms tumor patients was 61% and the OS was 81%; for patients with anaplastic histology, the EFS was 44% and the OS was 55%. Similar outcomes for patients with bilateral Wilms tumor have been reported in Europe. In a single-institution experience in the Netherlands (N = 41), there was significant morbidity in terms of renal failure (32%) and secondary tumors (20%). The incidence of end-stage renal failure in the Dutch study may be a reflection of a longer follow-up period.
Therapy for stage V Wilms tumor is being studied by the COG. Traditionally, patients have undergone bilateral renal biopsies, with staging of each kidney followed by preoperative chemotherapy. Currently on COG trials, pretreatment biopsies are not required if results of imaging tests are consistent with Wilms tumor. In the past the surgical approach varied according to the size of the tumor, with small tumors being resected and larger tumors being biopsied followed by prenephrectomy chemotherapy. The COG-AREN0534 trial is expected to provide data on whether using vincristine, dactinomycin, and doxorubicin initially is appropriate; in previous studies, approximately 40% of stage V patients did not require anthracyclines.
In the first COG trial to formally study bilateral Wilms tumors (COG-AREN0534), the treatment approach consists of preoperative chemotherapy with vincristine, dactinomycin, and doxorubicin to attempt to shrink the tumor and spare renal parenchyma. As part of this trial, an initial biopsy, laparotomy, or primary tumor excision is not recommended.
Evidence (preoperative chemotherapy):
For patients who are treated with preoperative chemotherapy, the tumor pathology needs to be evaluated after 4 to 8 weeks. For patients not treated on a clinical trial, the ideal time to perform a biopsy or resection is unknown because minimal shrinkage may reflect chemotherapy-induced differentiation or anaplastic histology. A planned attempt at resection or biopsy of apparently unresectable tumor is undertaken no later than 12 weeks from diagnosis. Continuing therapy without evaluating tumor pathology in a patient with bilateral Wilms tumor may miss anaplastic histology or chemotherapy-induced differentiation (including rhabdomyomatous differentiation) and thus increase toxicity for the patient without providing additional benefit for tumor control. Anaplastic histology occurs in 10% of patients with bilateral Wilms tumor, and these tumors respond poorly to chemotherapy.
Once the diagnosis is confirmed, a complete resection is performed. Histologic confirmation of the diagnosis is not straightforward. In a series of 27 patients from NWTS-4, discordant pathology was seen in 20 cases, which highlights the need to obtain tissue from both kidneys. Seven children who were later diagnosed with diffuse anaplastic tumors had core biopsies performed to establish the diagnosis; however, anaplasia was not found. Anaplasia was identified in only three of the nine patients when an open-wedge biopsy was performed and in seven of nine patients who had a partial or complete nephrectomy.
The decision to administer chemotherapy and/or radiation therapy following biopsy or second-look
operation is dependent on the tumor's response to initial therapy. More aggressive
therapy is required for patients with inadequate response to initial therapy
observed at the second procedure or in the setting of anaplasia.
Renal transplantation for children with stage V Wilms tumor is usually delayed until 1 to 2 years have passed without evidence of malignancy. Similarly, renal transplantation for children with Denys-Drash syndrome and Wilms tumor, all of whom require bilateral nephrectomy, is generally delayed 1 to 2 years after completion of initial treatment.
The following treatment option is currently under investigation in COG clinical trials. Information about ongoing clinical trials is available from the NCI Web site.
Patients with multicentric tumors, patients with high-risk bilateral tumors, and patients with diffuse hyperplastic nephrogenic rests are being treated on the following protocol:
Upfront intensification with three drugs (vincristine, doxorubicin, and dactinomycin) will be used in large part to move patients to definitive surgery earlier. Repeat imaging will be mandated at 6 weeks. On the basis of patient response to treatment, surgery, definitive surgery, biopsy, or continued chemotherapy will be performed. If biopsy or surgery is performed, chemotherapy or radiation therapy will be given on the basis of histology. Patients undergoing biopsy or continued chemotherapy will have repeat imaging performed at 12 weeks, with definitive surgery performed if results of imaging studies are at all positive.
This approach will identify patients with anaplasia, rhabdomyomatous differentiation, complete necrosis, or stromal differentiation; select them for early surgery; and define the intensity of chemotherapy to be administered. The decision to administer chemotherapy and/or radiation therapy following the second-look operation is dependent on the response to initial therapy, with more aggressive therapy required for patients with inadequate response to initial therapy observed at the second procedure.
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with stage I Wilms tumor, stage II Wilms tumor, stage III Wilms tumor, stage IV Wilms tumor and stage V Wilms tumor. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
General information about clinical trials is also available from the NCI Web site.
For patients who have completed therapy for Wilms tumor and exhibit features consistent with genetic predisposition, such as bilateral Wilms tumor, screening involves renal ultrasound examination every 3 months for metachronous tumors during the risk period for that particular syndrome (5 years for WT1-related syndromes; 8 years for Beckwith-Wiedemann syndrome).
Children treated for Wilms tumor are
at increased risk of developing the following:
The cumulative incidence of end-stage renal disease due to chronic renal failure at 20 years from diagnosis of Wilms tumor is low at 3.1% for patients with bilateral Wilms tumor and less than 1% for those with unilateral Wilms tumor. Efforts, therefore, have been aimed
toward reducing the intensity of therapy when possible.
(Refer to the PDQ summary on Late Effects of Treatment for Childhood Cancer for a full discussion of the late effects of cancer treatment in children and adolescents.)
Breslow N, Olshan A, Beckwith JB, et al.: Epidemiology of Wilms tumor. Med Pediatr Oncol 21 (3): 172-81, 1993.
Horner MJ, Ries LA, Krapcho M, et al.: SEER Cancer Statistics Review, 1975-2006. Bethesda, Md: National Cancer Institute, 2009. Also available online. Last accessed May 29, 2014.
Scott RH, Stiller CA, Walker L, et al.: Syndromes and constitutional chromosomal abnormalities associated with Wilms tumour. J Med Genet 43 (9): 705-15, 2006.
Narod SA, Hawkins MM, Robertson CM, et al.: Congenital anomalies and childhood cancer in Great Britain. Am J Hum Genet 60 (3): 474-85, 1997.
Dumoucel S, Gauthier-Villars M, Stoppa-Lyonnet D, et al.: Malformations, genetic abnormalities, and Wilms tumor. Pediatr Blood Cancer 61 (1): 140-4, 2014.
Gracia Bouthelier R, Lapunzina P: Follow-up and risk of tumors in overgrowth syndromes. J Pediatr Endocrinol Metab 18 (Suppl 1): 1227-35, 2005.
Lapunzina P: Risk of tumorigenesis in overgrowth syndromes: a comprehensive review. Am J Med Genet C Semin Med Genet 137 (1): 53-71, 2005.
Clericuzio CL: Clinical phenotypes and Wilms tumor. Med Pediatr Oncol 21 (3): 182-7, 1993.
Fischbach BV, Trout KL, Lewis J, et al.: WAGR syndrome: a clinical review of 54 cases. Pediatrics 116 (4): 984-8, 2005.
Breslow NE, Norris R, Norkool PA, et al.: Characteristics and outcomes of children with the Wilms tumor-Aniridia syndrome: a report from the National Wilms Tumor Study Group. J Clin Oncol 21 (24): 4579-85, 2003.
Barbosa AS, Hadjiathanasiou CG, Theodoridis C, et al.: The same mutation affecting the splicing of WT1 gene is present on Frasier syndrome patients with or without Wilms' tumor. Hum Mutat 13 (2): 146-53, 1999.
Koziell AB, Grundy R, Barratt TM, et al.: Evidence for the genetic heterogeneity of nephropathic phenotypes associated with Denys-Drash and Frasier syndromes. Am J Hum Genet 64 (6): 1778-81, 1999.
Royer-Pokora B, Beier M, Henzler M, et al.: Twenty-four new cases of WT1 germline mutations and review of the literature: genotype/phenotype correlations for Wilms tumor development. Am J Med Genet A 127 (3): 249-57, 2004.
Pelletier J, Bruening W, Kashtan CE, et al.: Germline mutations in the Wilms' tumor suppressor gene are associated with abnormal urogenital development in Denys-Drash syndrome. Cell 67 (2): 437-47, 1991.
Green DM, Breslow NE, Beckwith JB, et al.: Screening of children with hemihypertrophy, aniridia, and Beckwith-Wiedemann syndrome in patients with Wilms tumor: a report from the National Wilms Tumor Study. Med Pediatr Oncol 21 (3): 188-92, 1993.
DeBaun MR, Siegel MJ, Choyke PL: Nephromegaly in infancy and early childhood: a risk factor for Wilms tumor in Beckwith-Wiedemann syndrome. J Pediatr 132 (3 Pt 1): 401-4, 1998.
DeBaun MR, Tucker MA: Risk of cancer during the first four years of life in children from The Beckwith-Wiedemann Syndrome Registry. J Pediatr 132 (3 Pt 1): 398-400, 1998.
Porteus MH, Narkool P, Neuberg D, et al.: Characteristics and outcome of children with Beckwith-Wiedemann syndrome and Wilms' tumor: a report from the National Wilms Tumor Study Group. J Clin Oncol 18 (10): 2026-31, 2000.
Greenberg F, Stein F, Gresik MV, et al.: The Perlman familial nephroblastomatosis syndrome. Am J Med Genet 24 (1): 101-10, 1986.
Neri G, Martini-Neri ME, Katz BE, et al.: The Perlman syndrome: familial renal dysplasia with Wilms tumor, fetal gigantism and multiple congenital anomalies. 1984. Am J Med Genet A 161A (11): 2691-6, 2013.
Astuti D, Morris MR, Cooper WN, et al.: Germline mutations in DIS3L2 cause the Perlman syndrome of overgrowth and Wilms tumor susceptibility. Nat Genet 44 (3): 277-84, 2012.
Golabi M, Leung A, Lopez C: Simpson-Golabi-Behmel Syndrome Type 1. In: Pagon RA, Adam MP, Bird TD, et al., eds.: GeneReviews. Seattle, WA: University of Washington, 2013, pp. Available online. Last accesed May 29, 2014.
Fagali C, Kok F, Nicola P, et al.: MLPA analysis in 30 Sotos syndrome patients revealed one total NSD1 deletion and two partial deletions not previously reported. Eur J Med Genet 52 (5): 333-6, 2009 Sep-Oct.
Isidor B, Bourdeaut F, Lafon D, et al.: Wilms' tumor in patients with 9q22.3 microdeletion syndrome suggests a role for PTCH1 in nephroblastomas. Eur J Hum Genet 21 (7): 784-7, 2013.
Cairney AE, Andrews M, Greenberg M, et al.: Wilms tumor in three patients with Bloom syndrome. J Pediatr 111 (3): 414-6, 1987.
Hartley AL, Birch JM, Tricker K, et al.: Wilms' tumor in the Li-Fraumeni cancer family syndrome. Cancer Genet Cytogenet 67 (2): 133-5, 1993.
Bourdeaut F, Guiochon-Mantel A, Fabre M, et al.: Alagille syndrome and nephroblastoma: Unusual coincidence of two rare disorders. Pediatr Blood Cancer 50 (4): 908-11, 2008.
Bonaïti-Pellié C, Chompret A, Tournade MF, et al.: Genetics and epidemiology of Wilms' tumor: the French Wilms' tumor study. Med Pediatr Oncol 20 (4): 284-91, 1992.
Winther JF, Sankila R, Boice JD, et al.: Cancer in siblings of children with cancer in the Nordic countries: a population-based cohort study. Lancet 358 (9283): 711-7, 2001.
Breslow NE, Olson J, Moksness J, et al.: Familial Wilms' tumor: a descriptive study. Med Pediatr Oncol 27 (5): 398-403, 1996.
Li FP, Williams WR, Gimbrere K, et al.: Heritable fraction of unilateral Wilms tumor. Pediatrics 81 (1): 147-9, 1988.
Ruteshouser EC, Huff V: Familial Wilms tumor. Am J Med Genet C Semin Med Genet 129 (1): 29-34, 2004.
Paulino AC, Thakkar B, Henderson WG: Metachronous bilateral Wilms' tumor: the importance of time interval to the development of a second tumor. Cancer 82 (2): 415-20, 1998.
Coppes MJ, Arnold M, Beckwith JB, et al.: Factors affecting the risk of contralateral Wilms tumor development: a report from the National Wilms Tumor Study Group. Cancer 85 (7): 1616-25, 1999.
Grundy P, Koufos A, Morgan K, et al.: Familial predisposition to Wilms' tumour does not map to the short arm of chromosome 11. Nature 336 (6197): 374-6, 1988.
Little SE, Hanks SP, King-Underwood L, et al.: Frequency and heritability of WT1 mutations in nonsyndromic Wilms' tumor patients: a UK Children's Cancer Study Group Study. J Clin Oncol 22 (20): 4140-6, 2004.
Grønskov K, Olsen JH, Sand A, et al.: Population-based risk estimates of Wilms tumor in sporadic aniridia. A comprehensive mutation screening procedure of PAX6 identifies 80% of mutations in aniridia. Hum Genet 109 (1): 11-8, 2001.
Clericuzio C, Hingorani M, Crolla JA, et al.: Clinical utility gene card for: WAGR syndrome. Eur J Hum Genet 19 (4): , 2011.
Hoyme HE, Seaver LH, Jones KL, et al.: Isolated hemihyperplasia (hemihypertrophy): report of a prospective multicenter study of the incidence of neoplasia and review. Am J Med Genet 79 (4): 274-8, 1998.
Shanske AL: Trisomy 18 in a second 20-year-old woman. Am J Med Genet A 140 (9): 966-7, 2006.
Reid S, Renwick A, Seal S, et al.: Biallelic BRCA2 mutations are associated with multiple malignancies in childhood including familial Wilms tumour. J Med Genet 42 (2): 147-51, 2005.
Hirsch B, Shimamura A, Moreau L, et al.: Association of biallelic BRCA2/FANCD1 mutations with spontaneous chromosomal instability and solid tumors of childhood. Blood 103 (7): 2554-9, 2004.
Reid S, Schindler D, Hanenberg H, et al.: Biallelic mutations in PALB2 cause Fanconi anemia subtype FA-N and predispose to childhood cancer. Nat Genet 39 (2): 162-4, 2007.
Gadd S, Huff V, Huang CC, et al.: Clinically relevant subsets identified by gene expression patterns support a revised ontogenic model of Wilms tumor: a Children's Oncology Group Study. Neoplasia 14 (8): 742-56, 2012.
van Heyningen V, Hoovers JM, de Kraker J, et al.: Raised risk of Wilms tumour in patients with aniridia and submicroscopic WT1 deletion. J Med Genet 44 (12): 787-90, 2007.
Scott RH, Walker L, Olsen ØE, et al.: Surveillance for Wilms tumour in at-risk children: pragmatic recommendations for best practice. Arch Dis Child 91 (12): 995-9, 2006.
Lange J, Peterson SM, Takashima JR, et al.: Risk factors for end stage renal disease in non-WT1-syndromic Wilms tumor. J Urol 186 (2): 378-86, 2011.
Breslow NE, Takashima JR, Ritchey ML, et al.: Renal failure in the Denys-Drash and Wilms' tumor-aniridia syndromes. Cancer Res 60 (15): 4030-2, 2000.
Scott RH, Douglas J, Baskcomb L, et al.: Constitutional 11p15 abnormalities, including heritable imprinting center mutations, cause nonsyndromic Wilms tumor. Nat Genet 40 (11): 1329-34, 2008.
Perlman EJ, Grundy PE, Anderson JR, et al.: WT1 mutation and 11P15 loss of heterozygosity predict relapse in very low-risk wilms tumors treated with surgery alone: a children's oncology group study. J Clin Oncol 29 (6): 698-703, 2011.
Maiti S, Alam R, Amos CI, et al.: Frequent association of beta-catenin and WT1 mutations in Wilms tumors. Cancer Res 60 (22): 6288-92, 2000.
Koesters R, Ridder R, Kopp-Schneider A, et al.: Mutational activation of the beta-catenin proto-oncogene is a common event in the development of Wilms' tumors. Cancer Res 59 (16): 3880-2, 1999.
Ruteshouser EC, Robinson SM, Huff V: Wilms tumor genetics: mutations in WT1, WTX, and CTNNB1 account for only about one-third of tumors. Genes Chromosomes Cancer 47 (6): 461-70, 2008.
Major MB, Camp ND, Berndt JD, et al.: Wilms tumor suppressor WTX negatively regulates WNT/beta-catenin signaling. Science 316 (5827): 1043-6, 2007.
Segers H, Kersseboom R, Alders M, et al.: Frequency of WT1 and 11p15 constitutional aberrations and phenotypic correlation in childhood Wilms tumour patients. Eur J Cancer 48 (17): 3249-56, 2012.
Algar EM, St Heaps L, Darmanian A, et al.: Paternally inherited submicroscopic duplication at 11p15.5 implicates insulin-like growth factor II in overgrowth and Wilms' tumorigenesis. Cancer Res 67 (5): 2360-5, 2007.
Satoh Y, Nakadate H, Nakagawachi T, et al.: Genetic and epigenetic alterations on the short arm of chromosome 11 are involved in a majority of sporadic Wilms' tumours. Br J Cancer 95 (4): 541-7, 2006.
Bjornsson HT, Brown LJ, Fallin MD, et al.: Epigenetic specificity of loss of imprinting of the IGF2 gene in Wilms tumors. J Natl Cancer Inst 99 (16): 1270-3, 2007.
Fukuzawa R, Breslow NE, Morison IM, et al.: Epigenetic differences between Wilms' tumours in white and east-Asian children. Lancet 363 (9407): 446-51, 2004.
Bliek J, Gicquel C, Maas S, et al.: Epigenotyping as a tool for the prediction of tumor risk and tumor type in patients with Beckwith-Wiedemann syndrome (BWS). J Pediatr 145 (6): 796-9, 2004.
Lennerz JK, Timmerman RJ, Grange DK, et al.: Addition of H19 'loss of methylation testing' for Beckwith-Wiedemann syndrome (BWS) increases the diagnostic yield. J Mol Diagn 12 (5): 576-88, 2010.
Rump P, Zeegers MP, van Essen AJ: Tumor risk in Beckwith-Wiedemann syndrome: A review and meta-analysis. Am J Med Genet A 136 (1): 95-104, 2005.
Rivera MN, Kim WJ, Wells J, et al.: An X chromosome gene, WTX, is commonly inactivated in Wilms tumor. Science 315 (5812): 642-5, 2007.
Wegert J, Wittmann S, Leuschner I, et al.: WTX inactivation is a frequent, but late event in Wilms tumors without apparent clinical impact. Genes Chromosomes Cancer 48 (12): 1102-11, 2009.
Gratias EJ, Jennings LJ, Anderson JR, et al.: Gain of 1q is associated with inferior event-free and overall survival in patients with favorable histology Wilms tumor: a report from the Children's Oncology Group. Cancer 119 (21): 3887-94, 2013.
Segers H, van den Heuvel-Eibrink MM, Williams RD, et al.: Gain of 1q is a marker of poor prognosis in Wilms' tumors. Genes Chromosomes Cancer 52 (11): 1065-74, 2013.
Grundy PE, Breslow NE, Li S, et al.: Loss of heterozygosity for chromosomes 1p and 16q is an adverse prognostic factor in favorable-histology Wilms tumor: a report from the National Wilms Tumor Study Group. J Clin Oncol 23 (29): 7312-21, 2005.
Messahel B, Williams R, Ridolfi A, et al.: Allele loss at 16q defines poorer prognosis Wilms tumour irrespective of treatment approach in the UKW1-3 clinical trials: a Children's Cancer and Leukaemia Group (CCLG) Study. Eur J Cancer 45 (5): 819-26, 2009.
Spreafico F, Gamba B, Mariani L, et al.: Loss of heterozygosity analysis at different chromosome regions in Wilms tumor confirms 1p allelic loss as a marker of worse prognosis: a study from the Italian Association of Pediatric Hematology and Oncology. J Urol 189 (1): 260-6, 2013.
Natrajan R, Little SE, Reis-Filho JS, et al.: Amplification and overexpression of CACNA1E correlates with relapse in favorable histology Wilms' tumors. Clin Cancer Res 12 (24): 7284-93, 2006.
Blish KR, Clausen KA, Hawkins GA, et al.: Loss of heterozygosity and SOSTDC1 in adult and pediatric renal tumors. J Exp Clin Cancer Res 29: 147, 2010.
Singh KP, Roy D: SKCG-1: a new candidate growth regulatory gene at chromosome 11q23.2 in human sporadic Wilms tumours. Br J Cancer 94 (10): 1524-32, 2006.
Bardeesy N, Falkoff D, Petruzzi MJ, et al.: Anaplastic Wilms' tumour, a subtype displaying poor prognosis, harbours p53 gene mutations. Nat Genet 7 (1): 91-7, 1994.
el Bahtimi R, Hazen-Martin DJ, Re GG, et al.: Immunophenotype, mRNA expression, and gene structure of p53 in Wilms' tumors. Mod Pathol 9 (3): 238-44, 1996.
Bardeesy N, Beckwith JB, Pelletier J: Clonal expansion and attenuated apoptosis in Wilms' tumors are associated with p53 gene mutations. Cancer Res 55 (2): 215-9, 1995.
Williams RD, Al-Saadi R, Chagtai T, et al.: Subtype-specific FBXW7 mutation and MYCN copy number gain in Wilms' tumor. Clin Cancer Res 16 (7): 2036-45, 2010.
Wu MK, Sabbaghian N, Xu B, et al.: Biallelic DICER1 mutations occur in Wilms tumours. J Pathol 230 (2): 154-64, 2013.
Huff V: Wilms tumor genetics. Am J Med Genet 79 (4): 260-7, 1998.
Hu M, Fletcher J, McCahon E, et al.: Bilateral Wilms tumor and early presentation in pediatric patients is associated with the truncation of the Wilms tumor 1 protein. J Pediatr 163 (1): 224-9, 2013.
Tan TY, Amor DJ: Tumour surveillance in Beckwith-Wiedemann syndrome and hemihyperplasia: a critical review of the evidence and suggested guidelines for local practice. J Paediatr Child Health 42 (9): 486-90, 2006.
Teplick A, Kowalski M, Biegel JA, et al.: Educational paper: screening in cancer predisposition syndromes: guidelines for the general pediatrician. Eur J Pediatr 170 (3): 285-94, 2011.
Hingorani M, Hanson I, van Heyningen V: Aniridia. Eur J Hum Genet 20 (10): 1011-7, 2012.
Done JS, Huff V: Wilms Tumor Overview. In: Pagon RA, Adam MP, Bird TD, et al., eds.: GeneReviews. Seattle, WA: University of Washington, 2013, pp. Available online. Last accessed May 29, 2014.
Greene AK, Kieran M, Burrows PE, et al.: Wilms tumor screening is unnecessary in Klippel-Trenaunay syndrome. Pediatrics 113 (4): e326-9, 2004.
Green DM: Wilms' tumor. In: Greem DM: Diagnosis and Management of Malignant Solid Tumors in Infants and Children. Boston, Ma: Martinus Nijhoff Publishing, 1985, pp 129-86.
Maas MH, Cransberg K, van Grotel M, et al.: Renin-induced hypertension in Wilms tumor patients. Pediatr Blood Cancer 48 (5): 500-3, 2007.
Green DM: Controversies in the management of Wilms tumour - immediate nephrectomy or delayed nephrectomy? Eur J Cancer 43 (17): 2453-6, 2007.
Zoeller G, Pekrun A, Lakomek M, et al.: Wilms tumor: the problem of diagnostic accuracy in children undergoing preoperative chemotherapy without histological tumor verification. J Urol 151 (1): 169-71, 1994.
Begent J, Sebire NJ, Levitt G, et al.: Pilot study of F(18)-Fluorodeoxyglucose Positron Emission Tomography/computerised tomography in Wilms' tumour: correlation with conventional imaging, pathology and immunohistochemistry. Eur J Cancer 47 (3): 389-96, 2011.
Callaghan MU, Wong TE, Federici AB: Treatment of acquired von Willebrand syndrome in childhood. Blood 122 (12): 2019-22, 2013.
Shamberger RC, Guthrie KA, Ritchey ML, et al.: Surgery-related factors and local recurrence of Wilms tumor in National Wilms Tumor Study 4. Ann Surg 229 (2): 292-7, 1999.
Hamilton TE, Green DM, Perlman EJ, et al.: Bilateral Wilms' tumor with anaplasia: lessons from the National Wilms' Tumor Study. J Pediatr Surg 41 (10): 1641-4, 2006.
McDonald K, Duffy P, Chowdhury T, et al.: Added value of abdominal cross-sectional imaging (CT or MRI) in staging of Wilms' tumours. Clin Radiol 68 (1): 16-20, 2013.
Khanna G, Rosen N, Anderson JR, et al.: Evaluation of diagnostic performance of CT for detection of tumor thrombus in children with Wilms tumor: a report from the Children's Oncology Group. Pediatr Blood Cancer 58 (4): 551-5, 2012.
Khanna G, Naranjo A, Hoffer F, et al.: Detection of preoperative wilms tumor rupture with CT: a report from the Children's Oncology Group. Radiology 266 (2): 610-7, 2013.
Green DM, Breslow NE, Beckwith JB, et al.: Effect of duration of treatment on treatment outcome and cost of treatment for Wilms' tumor: a report from the National Wilms' Tumor Study Group. J Clin Oncol 16 (12): 3744-51, 1998.
Kalapurakal JA, Dome JS, Perlman EJ, et al.: Management of Wilms' tumour: current practice and future goals. Lancet Oncol 5 (1): 37-46, 2004.
Ehrlich PF: Wilms tumor: progress and considerations for the surgeon. Surg Oncol 16 (3): 157-71, 2007.
Dome JS, Cotton CA, Perlman EJ, et al.: Treatment of anaplastic histology Wilms' tumor: results from the fifth National Wilms' Tumor Study. J Clin Oncol 24 (15): 2352-8, 2006.
Shamberger RC, Anderson JR, Breslow NE, et al.: Long-term outcomes for infants with very low risk Wilms tumor treated with surgery alone in National Wilms Tumor Study-5. Ann Surg 251 (3): 555-8, 2010.
Routh JC, Grundy PE, Anderson JR, et al.: B7-h1 as a biomarker for therapy failure in patients with favorable histology Wilms tumor. J Urol 189 (4): 1487-92, 2013.
Ali AN, Diaz R, Shu HK, et al.: A Surveillance, Epidemiology and End Results (SEER) program comparison of adult and pediatric Wilms' tumor. Cancer 118 (9): 2541-51, 2012.
Kalapurakal JA, Nan B, Norkool P, et al.: Treatment outcomes in adults with favorable histologic type Wilms tumor-an update from the National Wilms Tumor Study Group. Int J Radiat Oncol Biol Phys 60 (5): 1379-84, 2004.
Reinhard H, Aliani S, Ruebe C, et al.: Wilms' tumor in adults: results of the Society of Pediatric Oncology (SIOP) 93-01/Society for Pediatric Oncology and Hematology (GPOH) Study. J Clin Oncol 22 (22): 4500-6, 2004.
Popov SD, Sebire NJ, Pritchard-Jones K, et al.: Renal tumors in children aged 10-16 Years: a report from the United Kingdom Children's Cancer and Leukaemia Group. Pediatr Dev Pathol 14 (3): 189-93, 2011 May-Jun.
Childhood cancer by the ICCC. In: Howlader N, Noone AM, Krapcho M, et al., eds.: SEER Cancer Statistics Review, 1975-2010. Bethesda, Md: National Cancer Institute, based on November 2012 SEER data submission, posted to the SEER web site, April 2013, Section 29. Also available online. Last accessed June 26, 2014.
Perlman EJ: Pediatric renal tumors: practical updates for the pathologist. Pediatr Dev Pathol 8 (3): 320-38, 2005 May-Jun.
Indolfi P, Jenkner A, Terenziani M, et al.: Synchronous bilateral Wilms tumor: a report from the Associazione Italiana Ematologia Oncologia Pediatrica (AIEOP). Cancer 119 (8): 1586-92, 2013.
Hamilton TE, Ritchey ML, Haase GM, et al.: The management of synchronous bilateral Wilms tumor: a report from the National Wilms Tumor Study Group. Ann Surg 253 (5): 1004-10, 2011.
Williams RD, Al-Saadi R, Natrajan R, et al.: Molecular profiling reveals frequent gain of MYCN and anaplasia-specific loss of 4q and 14q in Wilms tumor. Genes Chromosomes Cancer 50 (12): 982-95, 2011.
Vujanić GM, Harms D, Sandstedt B, et al.: New definitions of focal and diffuse anaplasia in Wilms tumor: the International Society of Paediatric Oncology (SIOP) experience. Med Pediatr Oncol 32 (5): 317-23, 1999.
Faria P, Beckwith JB, Mishra K, et al.: Focal versus diffuse anaplasia in Wilms tumor--new definitions with prognostic significance: a report from the National Wilms Tumor Study Group. Am J Surg Pathol 20 (8): 909-20, 1996.
Beckwith JB: New developments in the pathology of Wilms tumor. Cancer Invest 15 (2): 153-62, 1997.
Beckwith JB: Precursor lesions of Wilms tumor: clinical and biological implications. Med Pediatr Oncol 21 (3): 158-68, 1993.
Cooke A, Deshpande AV, La Hei ER, et al.: Ectopic nephrogenic rests in children: the clinicosurgical implications. J Pediatr Surg 44 (12): e13-6, 2009.
Wilms' tumor: status report, 1990. By the National Wilms' Tumor Study Committee. J Clin Oncol 9 (5): 877-87, 1991.
Green DM, Breslow NE, D'Angio GJ, et al.: Outcome of patients with Stage II/favorable histology Wilms tumor with and without local tumor spill: a report from the National Wilms Tumor Study Group. Pediatr Blood Cancer 61 (1): 134-9, 2014.
Ehrlich PF, Anderson JR, Ritchey ML, et al.: Clinicopathologic findings predictive of relapse in children with stage III favorable-histology Wilms tumor. J Clin Oncol 31 (9): 1196-201, 2013.
Breslow NE, Collins AJ, Ritchey ML, et al.: End stage renal disease in patients with Wilms tumor: results from the National Wilms Tumor Study Group and the United States Renal Data System. J Urol 174 (5): 1972-5, 2005.
D'Angio GJ, Breslow N, Beckwith JB, et al.: Treatment of Wilms' tumor. Results of the Third National Wilms' Tumor Study. Cancer 64 (2): 349-60, 1989.
Jereb B, Burgers JM, Tournade MF, et al.: Radiotherapy in the SIOP (International Society of Pediatric Oncology) nephroblastoma studies: a review. Med Pediatr Oncol 22 (4): 221-7, 1994.
Green DM: The treatment of stages I-IV favorable histology Wilms' tumor. J Clin Oncol 22 (8): 1366-72, 2004.
Green DM, Breslow NE, Beckwith JB, et al.: Comparison between single-dose and divided-dose administration of dactinomycin and doxorubicin for patients with Wilms' tumor: a report from the National Wilms' Tumor Study Group. J Clin Oncol 16 (1): 237-45, 1998.
D'Angio GJ, Evans AE, Breslow N, et al.: The treatment of Wilms' tumor: Results of the national Wilms' tumor study. Cancer 38 (2): 633-46, 1976.
D'Angio GJ, Evans A, Breslow N, et al.: The treatment of Wilms' tumor: results of the Second National Wilms' Tumor Study. Cancer 47 (9): 2302-11, 1981.
Kieran K, Anderson JR, Dome JS, et al.: Lymph node involvement in Wilms tumor: results from National Wilms Tumor Studies 4 and 5. J Pediatr Surg 47 (4): 700-6, 2012.
Ritchey M, Daley S, Shamberger RC, et al.: Ureteral extension in Wilms' tumor: a report from the National Wilms' Tumor Study Group (NWTSG). J Pediatr Surg 43 (9): 1625-9, 2008.
Gow KW, Barnhart DC, Hamilton TE, et al.: Primary nephrectomy and intraoperative tumor spill: report from the Children's Oncology Group (COG) renal tumors committee. J Pediatr Surg 48 (1): 34-8, 2013.
McNeil DE, Langer JC, Choyke P, et al.: Feasibility of partial nephrectomy for Wilms' tumor in children with Beckwith-Wiedemann syndrome who have been screened with abdominal ultrasonography. J Pediatr Surg 37 (1): 57-60, 2002.
Auber F, Jeanpierre C, Denamur E, et al.: Management of Wilms tumors in Drash and Frasier syndromes. Pediatr Blood Cancer 52 (1): 55-9, 2009.
Neville H, Ritchey ML, Shamberger RC, et al.: The occurrence of Wilms tumor in horseshoe kidneys: a report from the National Wilms Tumor Study Group (NWTSG). J Pediatr Surg 37 (8): 1134-7, 2002.
Ferrer FA, Rosen N, Herbst K, et al.: Image based feasibility of renal sparing surgery for very low risk unilateral Wilms tumors: a report from the Children's Oncology Group. J Urol 190 (5): 1846-51, 2013.
Ritchey ML: Renal sparing surgery for Wilms tumor. J Urol 174 (4 Pt 1): 1172-3, 2005.
Cozzi DA, Zani A: Nephron-sparing surgery in children with primary renal tumor: indications and results. Semin Pediatr Surg 15 (1): 3-9, 2006.
Zhuge Y, Cheung MC, Yang R, et al.: Improved survival with lymph node sampling in Wilms tumor. J Surg Res 167 (2): e199-203, 2011.
Ritchey ML, Kelalis PP, Breslow N, et al.: Surgical complications after nephrectomy for Wilms' tumor. Surg Gynecol Obstet 175 (6): 507-14, 1992.
Ehrlich PF, Ferrer FA, Ritchey ML, et al.: Hepatic metastasis at diagnosis in patients with Wilms tumor is not an independent adverse prognostic factor for stage IV Wilms tumor: a report from the Children's Oncology Group/National Wilms Tumor Study Group. Ann Surg 250 (4): 642-8, 2009.
Ritchey ML: Primary nephrectomy for Wilms' tumor: approach of the National Wilms' Tumor Study Group. Urology 47 (6): 787-91, 1996.
Lall A, Pritchard-Jones K, Walker J, et al.: Wilms' tumor with intracaval thrombus in the UK Children's Cancer Study Group UKW3 trial. J Pediatr Surg 41 (2): 382-7, 2006.
Ritchey ML, Pringle KC, Breslow NE, et al.: Management and outcome of inoperable Wilms tumor. A report of National Wilms Tumor Study-3. Ann Surg 220 (5): 683-90, 1994.
Ritchey ML, Shamberger RC, Haase G, et al.: Surgical complications after primary nephrectomy for Wilms' tumor: report from the National Wilms' Tumor Study Group. J Am Coll Surg 192 (1): 63-8; quiz 146, 2001.
Tournade MF, Com-Nougué C, Voûte PA, et al.: Results of the Sixth International Society of Pediatric Oncology Wilms' Tumor Trial and Study: a risk-adapted therapeutic approach in Wilms' tumor. J Clin Oncol 11 (6): 1014-23, 1993.
Oberholzer HF, Falkson G, De Jager LC: Successful management of inferior vena cava and right atrial nephroblastoma tumor thrombus with preoperative chemotherapy. Med Pediatr Oncol 20 (1): 61-3, 1992.
Saarinen UM, Wikström S, Koskimies O, et al.: Percutaneous needle biopsy preceding preoperative chemotherapy in the management of massive renal tumors in children. J Clin Oncol 9 (3): 406-15, 1991.
Dykes EH, Marwaha RK, Dicks-Mireaux C, et al.: Risks and benefits of percutaneous biopsy and primary chemotherapy in advanced Wilms' tumour. J Pediatr Surg 26 (5): 610-2, 1991.
Thompson WR, Newman K, Seibel N, et al.: A strategy for resection of Wilms' tumor with vena cava or atrial extension. J Pediatr Surg 27 (7): 912-5, 1992.
Shamberger RC, Ritchey ML, Haase GM, et al.: Intravascular extension of Wilms tumor. Ann Surg 234 (1): 116-21, 2001.
Szavay P, Luithle T, Semler O, et al.: Surgery of cavoatrial tumor thrombus in nephroblastoma: a report of the SIOP/GPOH study. Pediatr Blood Cancer 43 (1): 40-5, 2004.
Rutigliano DN, Kayton ML, Steinherz P, et al.: The use of preoperative chemotherapy in Wilms' tumor with contained retroperitoneal rupture. J Pediatr Surg 42 (9): 1595-9, 2007.
Corn BW, Goldwein JW, Evans I, et al.: Outcomes in low-risk babies treated with half-dose chemotherapy according to the Third National Wilms' Tumor Study. J Clin Oncol 10 (8): 1305-9, 1992.
Morgan E, Baum E, Breslow N, et al.: Chemotherapy-related toxicity in infants treated according to the Second National Wilms' Tumor Study. J Clin Oncol 6 (1): 51-5, 1988.
Green DM, Norkool P, Breslow NE, et al.: Severe hepatic toxicity after treatment with vincristine and dactinomycin using single-dose or divided-dose schedules: a report from the National Wilms' Tumor Study. J Clin Oncol 8 (9): 1525-30, 1990.
Raine J, Bowman A, Wallendszus K, et al.: Hepatopathy-thrombocytopenia syndrome--a complication of dactinomycin therapy for Wilms' tumor: a report from the United Kingdom Childrens Cancer Study Group. J Clin Oncol 9 (2): 268-73, 1991.
Feusner JH, Ritchey ML, Norkool PA, et al.: Renal failure does not preclude cure in children receiving chemotherapy for Wilms tumor: a report from the National Wilms Tumor Study Group. Pediatr Blood Cancer 50 (2): 242-5, 2008.
Veal GJ, English MW, Grundy RG, et al.: Pharmacokinetically guided dosing of carboplatin in paediatric cancer patients with bilateral nephrectomy. Cancer Chemother Pharmacol 54 (4): 295-300, 2004.
Green DM, Breslow NE, Beckwith JB, et al.: Treatment with nephrectomy only for small, stage I/favorable histology Wilms' tumor: a report from the National Wilms' Tumor Study Group. J Clin Oncol 19 (17): 3719-24, 2001.
Kalapurakal JA, Li SM, Breslow NE, et al.: Intraoperative spillage of favorable histology wilms tumor cells: influence of irradiation and chemotherapy regimens on abdominal recurrence. A report from the National Wilms Tumor Study Group. Int J Radiat Oncol Biol Phys 76 (1): 201-6, 2010.
Kalapurakal JA, Green DM, Haase G, et al.: Outcomes of children with favorable histology wilms tumor and peritoneal implants treated in National Wilms Tumor Studies-4 and -5. Int J Radiat Oncol Biol Phys 77 (2): 554-8, 2010.
Grundy PE, Green DM, Dirks AC, et al.: Clinical significance of pulmonary nodules detected by CT and Not CXR in patients treated for favorable histology Wilms tumor on national Wilms tumor studies-4 and -5: a report from the Children's Oncology Group. Pediatr Blood Cancer 59 (4): 631-5, 2012.
Verschuur A, Van Tinteren H, Graf N, et al.: Treatment of pulmonary metastases in children with stage IV nephroblastoma with risk-based use of pulmonary radiotherapy. J Clin Oncol 30 (28): 3533-9, 2012.
Ehrlich PF: Bilateral Wilms' tumor: the need to improve outcomes. Expert Rev Anticancer Ther 9 (7): 963-73, 2009.
Aronson DC, Slaar A, Heinen RC, et al.: Long-term outcome of bilateral Wilms tumors (BWT). Pediatr Blood Cancer 56 (7): 1110-3, 2011.
Sudour H, Audry G, Schleimacher G, et al.: Bilateral Wilms tumors (WT) treated with the SIOP 93 protocol in France: epidemiological survey and patient outcome. Pediatr Blood Cancer 59 (1): 57-61, 2012.
Davidoff AM, Giel DW, Jones DP, et al.: The feasibility and outcome of nephron-sparing surgery for children with bilateral Wilms tumor. The St Jude Children's Research Hospital experience: 1999-2006. Cancer 112 (9): 2060-70, 2008.
Ritchey ML, Green DM, Thomas PR, et al.: Renal failure in Wilms' tumor patients: a report from the National Wilms' Tumor Study Group. Med Pediatr Oncol 26 (2): 75-80, 1996.
Fuchs J, Wünsch L, Flemming P, et al.: Nephron-sparing surgery in synchronous bilateral Wilms' tumors. J Pediatr Surg 34 (10): 1505-9, 1999.
Horwitz JR, Ritchey ML, Moksness J, et al.: Renal salvage procedures in patients with synchronous bilateral Wilms' tumors: a report from the National Wilms' Tumor Study Group. J Pediatr Surg 31 (8): 1020-5, 1996.
Ritchey ML: The role of preoperative chemotherapy for Wilms' tumor: the NWTSG perspective. National Wilms' Tumor Study Group. Semin Urol Oncol 17 (1): 21-7, 1999.
Zuppan CW, Beckwith JB, Weeks DA, et al.: The effect of preoperative therapy on the histologic features of Wilms' tumor. An analysis of cases from the Third National Wilms' Tumor Study. Cancer 68 (2): 385-94, 1991.
Kist-van Holthe JE, Ho PL, Stablein D, et al.: Outcome of renal transplantation for Wilms' tumor and Denys-Drash syndrome: a report of the North American Pediatric Renal Transplant Cooperative Study. Pediatr Transplant 9 (3): 305-10, 2005.
Montgomery BT, Kelalis PP, Blute ML, et al.: Extended followup of bilateral Wilms tumor: results of the National Wilms Tumor Study. J Urol 146 (2 ( Pt 2)): 514-8, 1991.
Shamberger RC, Haase GM, Argani P, et al.: Bilateral Wilms' tumors with progressive or nonresponsive disease. J Pediatr Surg 41 (4): 652-7; discussion 652-7, 2006.
Breslow NE, Lange JM, Friedman DL, et al.: Secondary malignant neoplasms after Wilms tumor: an international collaborative study. Int J Cancer 127 (3): 657-66, 2010.
Termuhlen AM, Tersak JM, Liu Q, et al.: Twenty-five year follow-up of childhood Wilms tumor: a report from the Childhood Cancer Survivor Study. Pediatr Blood Cancer 57 (7): 1210-6, 2011.
Green DM, Grigoriev YA, Nan B, et al.: Congestive heart failure after treatment for Wilms' tumor: a report from the National Wilms' Tumor Study group. J Clin Oncol 19 (7): 1926-34, 2001.
Green DM, Lange JM, Peabody EM, et al.: Pregnancy outcome after treatment for Wilms tumor: a report from the national Wilms tumor long-term follow-up study. J Clin Oncol 28 (17): 2824-30, 2010.
Malignant epithelial tumors arising in the kidneys of children account for more than 5% of new pediatric renal tumors; therefore, they are more common than clear cell sarcoma of the kidney or rhabdoid tumors of the kidney. Renal cell carcinoma (RCC), the most common primary malignancy of the kidney in adults, is rare in children younger than 15 years. In the older age group of adolescents (aged 15–19 years), approximately two-thirds of renal malignancies are RCC. The annual incidence rate is approximately 4 cases per 1 million children, compared with an incidence of Wilms tumor of the kidney that is at least 29-fold higher.
Conditions associated with RCC include the following:
Screening for the VHL gene is available. To detect clear cell renal carcinoma in these individuals when the lesions are smaller than 3 cm and renal-sparing surgery can be performed, annual screening with abdominal ultrasound or magnetic resonance imaging (MRI) is recommended, beginning at age 8 to 11 years.
(Refer to the Von Hippel-Lindau Syndrome section of the PDQ summary on Genetics of Kidney Cancer (Renal Cell Cancer) for more information.)
Succinate dehydrogenase (SDHB, SDHC, and SDHD) is a Krebs cycle enzyme gene that has been associated with the development of familial RCC occurring with pheochromocytoma/paraganglioma. Germline mutations in a subunit of the gene have been reported in individuals with renal cancer and no history of pheochromocytoma.
Indications for germline genetic testing of children and adolescents with RCC to check for a related syndrome are described in Table 7.
Indication for Testing
Multifocal RCC or VHL lesions
von Hippel-Lindau syndrome
Family history of clear cell RCC or multifocal RCC with absent VHL mutation
Chromosome 3 gene translocations
Hereditary non-VHL clear cell RCC syndrome
Multifocal papillary RCC or family history of papillary RCC
Hereditary papillary RCC syndrome
Multifocal RCC or cutaneous fibrofolliculoma or pulmonary cysts or spontaneous pneumothorax
Chromophobe or oncocytic or clear cell
Germline sequence BHD gene
Personal or family history of early-onset uterine leiomyomata or cutaneous leiomyomata
Type 2 papillary or collecting duct carcinoma
Hereditary leiomyomata/RCC syndrome
Multifocal RCC or early-onset RCC or presence of paraganglioma/pheochromocytoma or family history of paraganglioma/pheochromocytoma
Clear cell or chromophobe
SDHB gene, SDHC gene, SDHD gene
Hereditary paraganglioma/pheochromocytoma syndrome
VHL = von Hippel-Lindau.
aAdapted from Linehan et al.
Translocation-positive carcinomas of the kidney are recognized as a distinct form of RCC and may be the most common form of RCC in children. They are characterized by translocations involving the transcription factor E3 gene (TFE3) located on Xp11.2. The TFE3 gene may partner with one of the following genes:
Another less-common translocation subtype, t(6;11)(p21;q12), involving a fusion Alpha/TFEB, induces overexpression of transcription factor EB (TFEB). The translocations involving TFE3 and TFEB induce overexpression of these proteins, which can be identified by immunohistochemistry.
Previous exposure to chemotherapy is the only known risk factor for the development of Xp11 translocation RCCs. The postchemotherapy interval ranged from 4 to 13 years. All reported patients received either a DNA topoisomerase II inhibitor and/or an alkylating agent.
Controversy exists as to the biological behavior of the translocation RCC in children and young adults. Whereas some series have suggested a good prognosis when RCC is treated with surgery alone despite presenting at a higher stage (III/IV) than TFE-RCC, a meta-analysis reported that these patients have poorer outcomes. The outcomes for these patients are being studied in the ongoing COG-AREN03B2 (NCT00898365) Biology and Classification Study. VEGFR-targeted therapies and mTOR inhibitors seem to be active in Xp11 translocation metastatic RCC. Recurrences have been reported 20 to 30 years after the initial resection of the translocation-associated RCC.
Pediatric RCC differs histologically from the adult counterparts. Although the two main morphological subgroups of papillary and clear cell can be identified, about 25% of RCCs show heterogeneous features that do not fit into either of these categories. Childhood RCCs are more frequently of the papillary subtype (20%–50% of pediatric RCCs) and can sometimes occur in the setting of Wilms tumor, metanephric adenoma, and metanephric adenofibroma.
RCC in children and young adults has a different genetic and morphologic spectrum than that seen in older adults.
The primary prognostic factor for RCC is stage of disease. In a series of 41 children with RCC, the median age was 10 years, with 46% presenting with localized stage I and stage II disease, 29% with stage III disease, and 22% with stage IV disease, according to the Robson classification system. The sites of metastases were the lungs, liver, and lymph nodes. Event-free survival (EFS) and overall survival (OS) were each about 55% at 20 years posttreatment. Patients with stage I and stage II disease had an 89% OS rate, while those with stage III and stage IV disease had a 23% OS rate at 20 years posttreatment.
An important difference between the outcomes in children and adults with RCC is the prognostic significance of local lymph node involvement. Adults presenting with RCC and involved lymph nodes have a 5-year OS of approximately 20%, but the literature suggests that 72% of children with RCC and local lymph node involvement at diagnosis (without distant metastases) survive their disease. In another series of 49 patients from a population-based cancer registry, the findings were similar. In this series, 33% of the patients had papillary subtype, 22% had translocation type, 16% were unclassified, and 6% had clear-cell subtype. Survival at 5 years was 96% for patients with localized disease, 75% for patients with positive regional lymph nodes, and 33% for patients with distant metastatic RCC.
RCC may present with the following:
Refer to the Wilms tumor Clinical Features and Diagnostic and Staging Evaluation sections of this summary for more information about the clinical features and diagnostic evaluation of childhood kidney tumors. (Refer to the Stage Information for Renal Cell Cancer section of the Renal Cell Cancer Treatment summary for more information about the staging evaluation.)
Survival of patients with RCC is affected by stage of disease at presentation and the completeness of resection at radical nephrectomy. OS rates for all patients with RCC range from 64% to 87%. The 5-year survival rates for pediatric RCC is 90% or higher for stage I, higher than 80% for stage II, 70% for stage III, and lower than 15% for stage IV. Retrospective analyses and the small number of patients involved place limitations on the level of evidence in the area of treatment.
Standard treatment options for RCC include the following:
The primary treatment for RCC includes total surgical removal of the kidney and associated lymph nodes.
Renal-sparing surgery may be considered for carefully selected patients with low-volume localized disease. In two small series, patients who had partial nephrectomies seemed to have outcomes equivalent to those who had radical nephrectomies.
As with adult RCC, there is no standard treatment for unresectable metastatic disease in children. The response to radiation is poor, and chemotherapy is not effective. Immunotherapy with such agents as interferon-alpha and interleukin-2 may have some effect on cancer control. Rare spontaneous regression of pulmonary metastasis may occur with resection of the primary tumor.
Several targeted therapies (e.g., sorafenib, sunitinib, bevacizumab, temsirolimus, pazopanib, and everolimus) have been approved for use in adults with RCC; however, these agents have not been tested in pediatric patients with RCC. Case reports of pediatric and adolescent patients with a TFE3 RCC suggest responsiveness to multiple tyrosine kinase inhibitors. (Refer to the PDQ summary on adult Renal Cell Cancer Treatment for more information on the use of targeted therapies.)
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with childhood renal cell carcinoma. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
Bernstein L, Linet M, Smith MA, et al.: Renal Tumors. In: Ries LA, Smith MA, Gurney JG, et al., eds.: Cancer incidence and survival among children and adolescents: United States SEER Program 1975-1995. Bethesda, Md: National Cancer Institute, SEER Program, 1999. NIH Pub.No. 99-4649., pp 79-90. Also available online. Last accessed May 29, 2014.
Bruder E, Passera O, Harms D, et al.: Morphologic and molecular characterization of renal cell carcinoma in children and young adults. Am J Surg Pathol 28 (9): 1117-32, 2004.
Schimke RN, Collins DL, Stolle CA: Von Hippel-Lindau Syndrome. In: Pagon RA, Adam MP, Bird TD, et al., eds.: GeneReviews. Seattle, WA: University of Washington, 2013, pp. Available online. Last accessed May 29, 2014.
Park HK, Zhang S, Wong MK, et al.: Clinical presentation of epithelioid angiomyolipoma. Int J Urol 14 (1): 21-5, 2007.
Pea M, Bonetti F, Martignoni G, et al.: Apparent renal cell carcinomas in tuberous sclerosis are heterogeneous: the identification of malignant epithelioid angiomyolipoma. Am J Surg Pathol 22 (2): 180-7, 1998.
Wang N, Perkins KL: Involvement of band 3p14 in t(3;8) hereditary renal carcinoma. Cancer Genet Cytogenet 11 (4): 479-81, 1984.
Ricketts C, Woodward ER, Killick P, et al.: Germline SDHB mutations and familial renal cell carcinoma. J Natl Cancer Inst 100 (17): 1260-2, 2008.
Linehan WM, Bratslavsky G, Pinto PA, et al.: Molecular diagnosis and therapy of kidney cancer. Annu Rev Med 61: 329-43, 2010.
Swartz MA, Karth J, Schneider DT, et al.: Renal medullary carcinoma: clinical, pathologic, immunohistochemical, and genetic analysis with pathogenetic implications. Urology 60 (6): 1083-9, 2002.
Hakimi AA, Koi PT, Milhoua PM, et al.: Renal medullary carcinoma: the Bronx experience. Urology 70 (5): 878-82, 2007.
Strouse JJ, Spevak M, Mack AK, et al.: Significant responses to platinum-based chemotherapy in renal medullary carcinoma. Pediatr Blood Cancer 44 (4): 407-11, 2005.
Rathmell WK, Monk JP: High-dose-intensity MVAC for Advanced Renal Medullary Carcinoma: Report of Three Cases and Literature Review. Urology 72 (3): 659-63, 2008.
Alrashdi I, Levine S, Paterson J, et al.: Hereditary leiomyomatosis and renal cell carcinoma: very early diagnosis of renal cancer in a paediatric patient. Fam Cancer 9 (2): 239-43, 2010.
Bayley JP, Launonen V, Tomlinson IP: The FH mutation database: an online database of fumarate hydratase mutations involved in the MCUL (HLRCC) tumor syndrome and congenital fumarase deficiency. BMC Med Genet 9: 20, 2008.
Medeiros LJ, Palmedo G, Krigman HR, et al.: Oncocytoid renal cell carcinoma after neuroblastoma: a report of four cases of a distinct clinicopathologic entity. Am J Surg Pathol 23 (7): 772-80, 1999.
Dhall D, Al-Ahmadie HA, Dhall G, et al.: Pediatric renal cell carcinoma with oncocytoid features occurring in a child after chemotherapy for cardiac leiomyosarcoma. Urology 70 (1): 178.e13-5, 2007.
Schafernak KT, Yang XJ, Hsueh W, et al.: Pediatric renal cell carcinoma as second malignancy: reports of two cases and a review of the literature. Can J Urol 14 (6): 3739-44, 2007.
Rais-Bahrami S, Drabick JJ, De Marzo AM, et al.: Xp11 translocation renal cell carcinoma: delayed but massive and lethal metastases of a chemotherapy-associated secondary malignancy. Urology 70 (1): 178.e3-6, 2007.
Brassesco MS, Valera ET, Bonilha TA, et al.: Secondary PSF/TFE3-associated renal cell carcinoma in a child treated for genitourinary rhabdomyosarcoma. Cancer Genet 204 (2): 108-10, 2011.
Wilson CL, Ness KK, Neglia JP, et al.: Renal carcinoma after childhood cancer: a report from the childhood cancer survivor study. J Natl Cancer Inst 105 (7): 504-8, 2013.
Linehan WM, Pinto PA, Bratslavsky G, et al.: Hereditary kidney cancer: unique opportunity for disease-based therapy. Cancer 115 (10 Suppl): 2252-61, 2009.
Argani P, Hicks J, De Marzo AM, et al.: Xp11 translocation renal cell carcinoma (RCC): extended immunohistochemical profile emphasizing novel RCC markers. Am J Surg Pathol 34 (9): 1295-303, 2010.
Argani P, Laé M, Ballard ET, et al.: Translocation carcinomas of the kidney after chemotherapy in childhood. J Clin Oncol 24 (10): 1529-34, 2006.
Ramphal R, Pappo A, Zielenska M, et al.: Pediatric renal cell carcinoma: clinical, pathologic, and molecular abnormalities associated with the members of the mit transcription factor family. Am J Clin Pathol 126 (3): 349-64, 2006.
Geller JI, Argani P, Adeniran A, et al.: Translocation renal cell carcinoma: lack of negative impact due to lymph node spread. Cancer 112 (7): 1607-16, 2008.
Camparo P, Vasiliu V, Molinie V, et al.: Renal translocation carcinomas: clinicopathologic, immunohistochemical, and gene expression profiling analysis of 31 cases with a review of the literature. Am J Surg Pathol 32 (5): 656-70, 2008.
Qiu Rao, Bing Guan, Zhou XJ: Xp11.2 Translocation renal cell carcinomas have a poorer prognosis than non-Xp11.2 translocation carcinomas in children and young adults: a meta-analysis. Int J Surg Pathol 18 (6): 458-64, 2010.
Malouf GG, Camparo P, Oudard S, et al.: Targeted agents in metastatic Xp11 translocation/TFE3 gene fusion renal cell carcinoma (RCC): a report from the Juvenile RCC Network. Ann Oncol 21 (9): 1834-8, 2010.
Estrada CR, Suthar AM, Eaton SH, et al.: Renal cell carcinoma: Children's Hospital Boston experience. Urology 66 (6): 1296-300, 2005.
Carcao MD, Taylor GP, Greenberg ML, et al.: Renal-cell carcinoma in children: a different disorder from its adult counterpart? Med Pediatr Oncol 31 (3): 153-8, 1998.
Indolfi P, Terenziani M, Casale F, et al.: Renal cell carcinoma in children: a clinicopathologic study. J Clin Oncol 21 (3): 530-5, 2003.
Geller JI, Dome JS: Local lymph node involvement does not predict poor outcome in pediatric renal cell carcinoma. Cancer 101 (7): 1575-83, 2004.
Selle B, Furtwängler R, Graf N, et al.: Population-based study of renal cell carcinoma in children in Germany, 1980-2005: more frequently localized tumors and underlying disorders compared with adult counterparts. Cancer 107 (12): 2906-14, 2006.
Cook A, Lorenzo AJ, Salle JL, et al.: Pediatric renal cell carcinoma: single institution 25-year case series and initial experience with partial nephrectomy. J Urol 175 (4): 1456-60; discussion 1460, 2006.
Fyfe G, Fisher RI, Rosenberg SA, et al.: Results of treatment of 255 patients with metastatic renal cell carcinoma who received high-dose recombinant interleukin-2 therapy. J Clin Oncol 13 (3): 688-96, 1995.
De Pasquale MD, Pessolano R, Boldrini R, et al.: Continuing response to subsequent treatment lines with tyrosine kinase inhibitors in an adolescent with metastatic renal cell carcinoma. J Pediatr Hematol Oncol 33 (5): e176-9, 2011.
Chowdhury T, Prichard-Jones K, Sebire NJ, et al.: Persistent complete response after single-agent sunitinib treatment in a case of TFE translocation positive relapsed metastatic pediatric renal cell carcinoma. J Pediatr Hematol Oncol 35 (1): e1-3, 2013.
Rhabdoid tumors are extremely aggressive malignancies that generally occur in infants and young children. The most common locations are the kidney (termed malignant rhabdoid tumors or MRT) and central nervous system (CNS) (atypical teratoid/rhabdoid tumor), although rhabdoid tumors can also arise in most soft tissue sites. (Refer to the PDQ summary on Childhood Central Nervous System Atypical Teratoid/Rhabdoid Tumor Treatment for information on the treatment of central nervous system disease.) Relapses occur early (median time from diagnosis is 8 months).
A distinct clinical presentation that suggests a diagnosis of rhabdoid tumor of the kidney includes the following:
(Refer to the Wilms tumor Clinical Features and Diagnostic and Staging Evaluation sections of this summary for more information about the clinical features and diagnostic evaluation of childhood kidney tumors.)
Approximately two-thirds of patients will present with advanced-stage disease. Bilateral cases have been reported. Rhabdoid tumors of the kidney tend to metastasize to the lungs and the brain. As many as 10% to 15% of patients with rhabdoid tumors of the kidney also have CNS lesions. The staging system used for rhabdoid tumor of the kidney is the same system used for Wilms tumor. (Refer to the Stage Information for Wilms Tumor section of this summary for more information.)
Histologically, the most distinctive features of rhabdoid tumors of the kidney are rather large cells with large vesicular nuclei, a prominent single nucleolus, and in some cells, the presence of globular eosinophilic cytoplasmic inclusions.
Rhabdoid tumors in all anatomical locations have a common genetic abnormality—loss of function of the SMARCB1/INI1/SNF5/BAF47 gene located at chromosome 22q11.2. SMARCB1 encodes a component of the SWI/SNF (SWItch/Sucrose NonFermentable) chromatin remodeling complex that has an important role in controlling gene transcription. Based on gene expression analysis in rhabdoid tumors, it is hypothesized that rhabdoid tumors arise in early progenitor cells during a critical developmental window in which loss of SMARCB1 directly results in repression of neural development, loss of cyclin-dependent kinase inhibition, and trithorax/polycomb dysregulation. Identical mutations may give rise to a brain or kidney tumor.
Germline mutations of SMARCB1 have been documented for patients with one or more primary tumors of the brain and/or kidney, consistent with a genetic predisposition to the development of rhabdoid tumors. Approximately 35% of patients with rhabdoid tumors have germline SMARCB1 alterations. In most cases, the mutations are de novo and not inherited from a parent. The median age of children with rhabdoid tumors and a germline mutation or deletion is younger (5 months) than that of children with apparently sporadic disease (18 months). Germline mosaicism has been suggested for several families with multiple affected siblings. It appears that those patients with germline mutations may have the worst prognosis.
Early-onset, multifocal disease and familial cases strongly support the possibility of a rhabdoid predisposition syndrome. This has been confirmed by the presence of germline mutations of SMARCB1 in rare familial cases and in a subset of patients with apparently sporadic rhabdoid tumors. These cases have been labeled as rhabdoid tumor predisposition syndrome, type 1. Thirty-five patients (N = 100) with rhabdoid tumors of the brain, kidney, or soft tissues were found to have a germline SMARCB1 abnormality. These abnormalities included point and frameshift mutations, intragenic deletions and duplications, and larger deletions. Nine cases demonstrated parent-to-child transmission of a mutated copy of SMARCB1. In eight of the nine cases, one or more family members were also diagnosed with rhabdoid tumor or schwannoma; and two of the eight families presented with multiple affected children, consistent with gonadal mosaicism.
Two cases of inactivating mutations in the SMARCA4 gene have been found in three children from two unrelated families, establishing the phenotypically similar syndrome now known as rhabdoid tumor predisposition syndrome, type 2. In these cases, SMARCA4 behaves as a classical tumor suppressor, with one deleterious mutation inherited in the germline and the other acquired in the tumor. Another report describes an autosomal dominant pattern of inheritance discovered through an exome sequencing project.
Germline analysis is suggested for individuals of all ages with rhabdoid tumors. Genetic counseling is also part of the treatment plan, given the low-but-actual risk of familial recurrence. In cases of mutations, parental screening should be considered, although such screening carries a low probability of positivity. Prenatal diagnosis can be performed in situations where a specific SMARCB1 mutation or deletion has been documented in the family.
Recommendations for surveillance in patients with germline SMARCB1 mutations have been developed on the basis of epidemiology and clinical course of rhabdoid tumors. These recommendations were developed by a group of pediatric cancer genetic experts (including oncologists, radiologists, and geneticists). They have not been formally studied to confirm the benefit of monitoring patients with germline SMARCB1 mutations. The aggressive natural history of the disease, apparently high penetrance, and well-defined age of onset for CNS atypical teratoid/rhabdoid tumor suggest that surveillance could prove beneficial. Given the potential survival benefit of surgically resectable disease, it is postulated that early detection might improve overall survival (OS).
Because of the relative rarity of this tumor, all patients with rhabdoid tumor of the kidney should be considered for entry into a clinical trial. Treatment planning by a multidisciplinary team of cancer specialists (pediatric surgeon or pediatric urologist, pediatric radiation oncologist, and pediatric oncologist) with experience treating renal tumors is required to determine and implement optimum treatment.
Patients with rhabdoid tumors of the kidney continue to have a poor prognosis.
In a review of 142 patients from the National Wilms Tumor Studies (NWTS) NWTS-1 through NWTS-5, age and stage are important prognostic factors:
There is no standard treatment option for rhabdoid tumor of the kidney. The Société Internationale d’Oncologie Pédiatrique (SIOP) renal tumor group has noted that preoperative chemotherapy does not seem to translate into improved survival. Delays in surgery lead to worse survival, compared with patients treated according to direct surgery strategies.
The NWTS-5 (COG-Q9401/NCT00002611) trial closed the arm for rhabdoid tumor treatment with cyclophosphamide, etoposide, and carboplatin because poor outcome was observed. Combinations of etoposide and cisplatin;
etoposide and ifosfamide; and ifosfamide, carboplatin, and etoposide (ICE chemotherapy) have been used (COG-Q9401).
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with rhabdoid tumor of the kidney. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
van den Heuvel-Eibrink MM, van Tinteren H, Rehorst H, et al.: Malignant rhabdoid tumours of the kidney (MRTKs), registered on recent SIOP protocols from 1993 to 2005: a report of the SIOP renal tumour study group. Pediatr Blood Cancer 56 (5): 733-7, 2011.
Reinhard H, Reinert J, Beier R, et al.: Rhabdoid tumors in children: prognostic factors in 70 patients diagnosed in Germany. Oncol Rep 19 (3): 819-23, 2008.
Amar AM, Tomlinson G, Green DM, et al.: Clinical presentation of rhabdoid tumors of the kidney. J Pediatr Hematol Oncol 23 (2): 105-8, 2001.
Tomlinson GE, Breslow NE, Dome J, et al.: Rhabdoid tumor of the kidney in the National Wilms' Tumor Study: age at diagnosis as a prognostic factor. J Clin Oncol 23 (30): 7641-5, 2005.
Imbalzano AN, Jones SN: Snf5 tumor suppressor couples chromatin remodeling, checkpoint control, and chromosomal stability. Cancer Cell 7 (4): 294-5, 2005.
Eaton KW, Tooke LS, Wainwright LM, et al.: Spectrum of SMARCB1/INI1 mutations in familial and sporadic rhabdoid tumors. Pediatr Blood Cancer 56 (1): 7-15, 2011.
Gadd S, Sredni ST, Huang CC, et al.: Rhabdoid tumor: gene expression clues to pathogenesis and potential therapeutic targets. Lab Invest 90 (5): 724-38, 2010.
Biegel JA, Zhou JY, Rorke LB, et al.: Germ-line and acquired mutations of INI1 in atypical teratoid and rhabdoid tumors. Cancer Res 59 (1): 74-9, 1999.
Biegel JA: Molecular genetics of atypical teratoid/rhabdoid tumor. Neurosurg Focus 20 (1): E11, 2006.
Janson K, Nedzi LA, David O, et al.: Predisposition to atypical teratoid/rhabdoid tumor due to an inherited INI1 mutation. Pediatr Blood Cancer 47 (3): 279-84, 2006.
Schneppenheim R, Frühwald MC, Gesk S, et al.: Germline nonsense mutation and somatic inactivation of SMARCA4/BRG1 in a family with rhabdoid tumor predisposition syndrome. Am J Hum Genet 86 (2): 279-84, 2010.
Hasselblatt M, Gesk S, Oyen F, et al.: Nonsense mutation and inactivation of SMARCA4 (BRG1) in an atypical teratoid/rhabdoid tumor showing retained SMARCB1 (INI1) expression. Am J Surg Pathol 35 (6): 933-5, 2011.
Witkowski L, Lalonde E, Zhang J, et al.: Familial rhabdoid tumour 'avant la lettre'--from pathology review to exome sequencing and back again. J Pathol 231 (1): 35-43, 2013.
Waldron PE, Rodgers BM, Kelly MD, et al.: Successful treatment of a patient with stage IV rhabdoid tumor of the kidney: case report and review. J Pediatr Hematol Oncol 21 (1): 53-7, 1999 Jan-Feb.
Wagner L, Hill DA, Fuller C, et al.: Treatment of metastatic rhabdoid tumor of the kidney. J Pediatr Hematol Oncol 24 (5): 385-8, 2002 Jun-Jul.
Clear cell sarcoma of the kidney is not a Wilms tumor variant, but it
is an important primary renal tumor associated with a higher rate
of relapse and death than favorable-histology (FH) Wilms tumor. The classic pattern of clear cell sarcoma of the kidney is defined by nests or cords of cells
separated by regularly spaced fibrovascular septa. In addition to
pulmonary metastases, clear cell sarcoma also spreads to bone, brain, and soft
tissue. (Refer to the Wilms tumor Clinical Features and Diagnostic and Staging Evaluation sections of this summary for more information about the clinical features and diagnostic evaluation of childhood kidney tumors.)
While little is known about the biology of clear cell sarcoma of the kidney, the t(10;17)(q22;p13) translocation has been reported. As a result of the translocation, the YWHAE-FAM22 fusion transcript is formed; this transcript was detected in 12% of cases of clear cell sarcoma of the kidney in one series. 17p13 is the site of the P53 gene; however, this gene does not show abnormal expression and most likely is not involved. Gene expression studies revealed the upregulation of neural markers, with ensuing activation of the sonic hedgehog and Akt pathways. When DNA methylation profiling was used, the epigenetic characteristics of clear cell sarcoma of the kidney, rhabdoid tumor of the kidney, and Ewing sarcoma of the kidney, in comparison with those of the non-neoplastic kidney, exhibited distinct DNA methylation profiles in a tumor type–specific manner. The DNA methylation pattern of the THBS1 CpG site is sufficient for distinction of clear cell sarcoma of the kidney from other pediatric renal tumors.
Younger age and stage IV disease have been identified as adverse prognostic factors for event-free survival (EFS).
Historically, relapses have occurred in long intervals after the completion of chemotherapy (up to 10 years); however, with current therapy, relapses after 3 years are uncommon. The brain is a frequent site of recurrent disease, suggesting that it is a sanctuary site for cells that are protected from the intensive chemotherapy that patients currently receive. An awareness of the clinical signs of recurrent disease in the brain is important during regular follow-up.
There are no standard recommendations for the frequency of brain imaging during follow-up.
Because of the relative rarity of this tumor, all patients with clear cell sarcoma of the kidney should be considered for entry into a clinical trial. Treatment planning by a multidisciplinary team of cancer specialists (pediatric surgeon or pediatric urologist, pediatric radiation oncologist, and pediatric oncologist) with experience treating renal tumors is required to determine and implement optimum treatment.
The approach for treating clear cell sarcoma of the kidney is different from the approach for treating
Wilms tumor because the overall survival (OS) of children with clear cell sarcoma of the kidney remains lower than that for patients with FH Wilms tumor. All patients undergo postoperative radiation to the tumor bed and receive doxorubicin as part of their chemotherapy regimen.
The standard treatment option for clear cell sarcoma of the kidney is the following:
Evidence (surgery, chemotherapy, and radiation therapy):
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with clear cell sarcoma of the kidney. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
Argani P, Perlman EJ, Breslow NE, et al.: Clear cell sarcoma of the kidney: a review of 351 cases from the National Wilms Tumor Study Group Pathology Center. Am J Surg Pathol 24 (1): 4-18, 2000.
O'Meara E, Stack D, Lee CH, et al.: Characterization of the chromosomal translocation t(10;17)(q22;p13) in clear cell sarcoma of kidney. J Pathol 227 (1): 72-80, 2012.
Cutcliffe C, Kersey D, Huang CC, et al.: Clear cell sarcoma of the kidney: up-regulation of neural markers with activation of the sonic hedgehog and Akt pathways. Clin Cancer Res 11 (22): 7986-94, 2005.
Ueno H, Okita H, Akimoto S, et al.: DNA methylation profile distinguishes clear cell sarcoma of the kidney from other pediatric renal tumors. PLoS One 8 (4): e62233, 2013.
Furtwängler R, Gooskens SL, van Tinteren H, et al.: Clear cell sarcomas of the kidney registered on International Society of Pediatric Oncology (SIOP) 93-01 and SIOP 2001 protocols: a report of the SIOP Renal Tumour Study Group. Eur J Cancer 49 (16): 3497-506, 2013.
Seibel NL, Li S, Breslow NE, et al.: Effect of duration of treatment on treatment outcome for patients with clear-cell sarcoma of the kidney: a report from the National Wilms' Tumor Study Group. J Clin Oncol 22 (3): 468-73, 2004.
Seibel NL, Sun J, Anderson JR, et al.: Outcome of clear cell sarcoma of the kidney (CCSK) treated on the National Wilms Tumor Study-5 (NWTS). [Abstract] J Clin Oncol 24 (Suppl 18): A-9000, 502s, 2006.
Radulescu VC, Gerrard M, Moertel C, et al.: Treatment of recurrent clear cell sarcoma of the kidney with brain metastasis. Pediatr Blood Cancer 50 (2): 246-9, 2008.
Kalapurakal JA, Perlman EJ, Seibel NL, et al.: Outcomes of patients with revised stage I clear cell sarcoma of kidney treated in National Wilms Tumor Studies 1-5. Int J Radiat Oncol Biol Phys 85 (2): 428-31, 2013.
Mesoblastic nephroma comprises about 5% of childhood kidney tumors, and more than 90% of cases appear within the first year of life. It is the most common kidney tumor found in infants younger than 3 months. The median age of diagnosis is 1 to 2 months. Twice as many males as females are diagnosed. The diagnosis should be questioned when applied to individuals older than 2 years.
When patients are diagnosed in the first 7 months of life, the 5-year event-free survival (EFS) rate is 94%, and the overall survival (OS) rate is 96%. In a report from the United Kingdom of 50 children with mesoblastic nephroma studied on clinical trials and 80 cases from the national registry in the same time period, there were no deaths.
Grossly, mesoblastic nephromas appear as solitary, unilateral masses indistinguishable from nephroblastoma. Microscopically, they consist of spindled mesenchymal cells. Mesoblastic nephroma can be divided into the following two major types:
The risk for recurrence in mesoblastic nephroma is closely associated with the presence of a cellular component and with stage.
(Refer to the Wilms tumor Clinical Features and Diagnostic and Staging Evaluation sections of this summary for more information about the clinical features and diagnostic evaluation of childhood kidney tumors.)
Standard treatment options for congenital mesoblastic nephroma include the following:
Adjuvant chemotherapy has been recommended for patients with stage III cellular subtype who are aged 3 months or older at diagnosis. However, the benefit of adjuvant therapy will remain unproven with such a low incidence of disease. Infants younger than 2 months with incompletely resected, stage III disease may not need chemotherapy.
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with congenital mesoblastic nephroma. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
England RJ, Haider N, Vujanic GM, et al.: Mesoblastic nephroma: a report of the United Kingdom Children's Cancer and Leukaemia Group (CCLG). Pediatr Blood Cancer 56 (5): 744-8, 2011.
van den Heuvel-Eibrink MM, Grundy P, Graf N, et al.: Characteristics and survival of 750 children diagnosed with a renal tumor in the first seven months of life: A collaborative study by the SIOP/GPOH/SFOP, NWTSG, and UKCCSG Wilms tumor study groups. Pediatr Blood Cancer 50 (6): 1130-4, 2008.
Furtwaengler R, Reinhard H, Leuschner I, et al.: Mesoblastic nephroma--a report from the Gesellschaft fur Pädiatrische Onkologie und Hämatologie (GPOH). Cancer 106 (10): 2275-83, 2006.
Vujanić GM, Sandstedt B, Harms D, et al.: Revised International Society of Paediatric Oncology (SIOP) working classification of renal tumors of childhood. Med Pediatr Oncol 38 (2): 79-82, 2002.
Ewing sarcoma (neuroepithelial tumor) of the kidney is extremely rare and demonstrates a unique proclivity for young adults. It is a highly aggressive neoplasm, more often presenting with large tumors and penetration of the renal capsule, extension into the renal vein, and in 40% of cases, evidence of metastases.
Primary Ewing sarcoma of the kidney consists of primitive
neuroectodermal tumors characterized by CD99 (MIC-2) positivity and
the detection of EWS/FLI-1 fusion transcripts. In Ewing sarcoma of the kidney, focal, atypical histologic features
have been seen, including clear cell sarcoma, rhabdoid tumor, malignant
peripheral nerve sheath tumors, and paraganglioma. (Refer to the PDQ summary on Ewing Sarcoma Treatment for more information.)
There is no standard treatment option for Ewing sarcoma of the kidney. However, multimodal treatment (chemotherapy and radiation therapy) and aggressive surgical approach seem to be associated with a better outcome than previously reported. Consideration should also be given to substituting cyclophosphamide for ifosfamide in patients after they have undergone a nephrectomy. 
according to Ewing sarcoma/primitive neuroectodermal tumor protocols should be considered.
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with peripheral primitive neuroectodermal tumor of the kidney. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
Parham DM, Roloson GJ, Feely M, et al.: Primary malignant neuroepithelial tumors of the kidney: a clinicopathologic analysis of 146 adult and pediatric cases from the National Wilms' Tumor Study Group Pathology Center. Am J Surg Pathol 25 (2): 133-46, 2001.
Tagarelli A, Spreafico F, Ferrari A, et al.: Primary renal soft tissue sarcoma in children. Urology 80 (3): 698-702, 2012.
Rowe RG, Thomas DG, Schuetze SM, et al.: Ewing sarcoma of the kidney: case series and literature review of an often overlooked entity in the diagnosis of primary renal tumors. Urology 81 (2): 347-53, 2013.
Ellison DA, Parham DM, Bridge J, et al.: Immunohistochemistry of primary malignant neuroepithelial tumors of the kidney: a potential source of confusion? A study of 30 cases from the National Wilms Tumor Study Pathology Center. Hum Pathol 38 (2): 205-11, 2007.
Desmoplastic small round cell tumor of the kidney is a rare, small, round blue tumor of the kidney. It is diagnosed by its characteristic EWS-WT1 translocation. (Refer to the Desmoplastic small round cell tumor section in the PDQ summary on Childhood Soft Tissue Sarcoma Treatment for more information about desmoplastic small round cell tumor of the kidney.)
Wang LL, Perlman EJ, Vujanic GM, et al.: Desmoplastic small round cell tumor of the kidney in childhood. Am J Surg Pathol 31 (4): 576-84, 2007.
Cystic partially differentiated nephroblastoma is a rare cystic variant of Wilms tumor (1%), with unique pathologic and clinical characteristics. It is composed entirely of cysts, and their thin septa are the only solid portion of the tumor. The septa contain blastemal cells in any amount with or without embryonal stromal or epithelial cell type. Several pathologic features distinguish this neoplasm from standard Wilms tumor.
Recurrence has been reported following tumor spillage at surgery.[Level of evidence: 3iiiA]
Standard treatment options for cystic partially differentiated nephroblastoma include the following:
Baker JM, Viero S, Kim PC, et al.: Stage III cystic partially differentiated nephroblastoma recurring after nephrectomy and chemotherapy. Pediatr Blood Cancer 50 (1): 129-31, 2008.
Blakely ML, Shamberger RC, Norkool P, et al.: Outcome of children with cystic partially differentiated nephroblastoma treated with or without chemotherapy. J Pediatr Surg 38 (6): 897-900, 2003.
Multilocular cystic nephromas are benign lesions consisting of cysts lined by renal epithelium. These lesions can occur bilaterally, and a familial pattern has been reported.
Multilocular cystic nephroma has been associated with pleuropulmonary blastomas, so radiographic imaging studies of the chest are monitored in patients with multilocular cystic nephroma. (Refer to the Clinical Features and Diagnostic and Staging Evaluation sections of this summary for more information about the clinical features and diagnostic evaluation of childhood kidney tumors.)
The standard treatment for multilocular cystic nephroma is surgery.
Ashley RA, Reinberg YE: Familial multilocular cystic nephroma: a variant of a unique renal neoplasm. Urology 70 (1): 179.e9-10, 2007.
Primary renal synovial sarcoma is a subset of embryonal sarcoma of the kidney and is characterized by the t(x;18)(p11;q11) SYT-SSX translocation. It is similar in histology to the monophasic spindle cell synovial sarcoma and is considered an aggressive tumor with adverse patient outcomes in more than 50% of cases (n = 16). Primary renal synovial sarcoma contains cystic structures derived from dilated, trapped renal tubules. Primary renal synovial sarcoma occurs more often in young adults.
The standard treatment for primary renal synovial sarcoma is chemotherapy. Chemotherapy regimens that are different from those traditionally used for Wilms tumor are used.
Schoolmeester JK, Cheville JC, Folpe AL: Synovial sarcoma of the kidney: a clinicopathologic, immunohistochemical, and molecular genetic study of 16 cases. Am J Surg Pathol 38 (1): 60-5, 2014.
Argani P, Faria PA, Epstein JI, et al.: Primary renal synovial sarcoma: molecular and morphologic delineation of an entity previously included among embryonal sarcomas of the kidney. Am J Surg Pathol 24 (8): 1087-96, 2000.
Anaplastic sarcoma of the kidney is a rare renal tumor that has been identified mainly in patients younger than 15 years.
Patients present with a renal mass, with the most common sites of metastases being the lung, liver, and bones. (Refer to the Wilms tumor Clinical Features and Diagnostic and Staging Evaluation sections of this summary for more information about the clinical features and diagnostic evaluation of childhood kidney tumors.)
Cytogenetic abnormalities such as rearrangement between 10q21 and 18p11.2 have been reported. These tumors show pathologic features similar to pleuropulmonary blastoma of childhood (refer to the Pleuropulmonary Blastoma section in the PDQ summary on Unusual Cancers of Childhood for more information) and undifferentiated embryonal sarcoma of the liver (refer to the Treatment of Undifferentiated Embryonal Sarcoma of the Liver section in the PDQ summary on Childhood Liver Cancer for more information).
There is no standard treatment for anaplastic sarcoma of the kidney. In the past, these tumors have been identified as anaplastic Wilms tumor and treated accordingly.
Gomi K, Hamanoue S, Tanaka M, et al.: Anaplastic sarcoma of the kidney with chromosomal abnormality: first report on cytogenetic findings. Hum Pathol 41 (10): 1495-9, 2010.
Vujanić GM, Kelsey A, Perlman EJ, et al.: Anaplastic sarcoma of the kidney: a clinicopathologic study of 20 cases of a new entity with polyphenotypic features. Am J Surg Pathol 31 (10): 1459-68, 2007.
Some multifocal nephrogenic rests may become hyperplastic, which may produce a thick rind of blastemal or tubular cells that enlarge the kidney. Nephroblastomatosis may be diagnosed radiographically by magnetic resonance imaging, in which the homogeneity of the hypointense rind-like lesion on contrast-enhanced imaging differentiates it from Wilms tumor. Biopsy often cannot discriminate Wilms tumor from these hyperplastic nephrogenic rests. Differentiation may occur after chemotherapy is administered.
Standard treatment options for nephroblastomatosis include the following:
Current treatment includes vincristine and dactinomycin until nearly complete resolution, as determined by imaging.
Even with treatment (vincristine and dactinomycin), about one-half of children diagnosed with nephroblastomatosis will develop Wilms tumor within 36 months. In a series of 52 patients, 3 patients died of recurrent Wilms tumor. In treated children, as many as one-third of Wilms tumors are anaplastic, probably as a result of selection of chemotherapy-resistant tumors, so early detection is critical. Patients are monitored by imaging at a maximum interval of 3 months, for a minimum of 7 years. Given the high incidence of bilaterality and the subsequent Wilms tumors, renal-sparing surgery is indicated.
These patients are eligible for treatment on the COG-AREN0534 trial with vincristine and dactinomycin.
Perlman EJ, Faria P, Soares A, et al.: Hyperplastic perilobar nephroblastomatosis: long-term survival of 52 patients. Pediatr Blood Cancer 46 (2): 203-21, 2006.
Patients with recurrent rhabdoid tumor of the kidney, clear cell sarcoma of the kidney,
neuroepithelial tumor of the kidney, and renal cell carcinoma should be considered for treatment on
available phase I and phase II clinical trials.
Standard-risk relapsed Wilms tumor
Surgery, radiation therapy, and chemotherapy
High-risk and very high-risk relapsed Wilms tumor
Chemotherapy, surgery, and/or radiation therapy
Hematopoietic stem cell transplantation
Recurrent clear cell sarcoma of the kidney
Chemotherapy, surgery, and/or radiation therapy
Approximately 15% of patients with favorable-histology (FH) Wilms tumor and 50% of patients with anaplastic Wilms tumor experience recurrence. Historically, the salvage rate for patients with recurrent FH Wilms tumor was 25% to 40%. As a result of modern treatment combinations, the outcome after recurrence has improved up to 60%.
A number of potential prognostic features influencing outcome postrecurrence have been analyzed, but it is difficult to separate whether these factors are independent of each other. Also, the following prognostic factors appear to be changing over time as therapy for primary and recurrent Wilms tumor evolves:
The National Wilms Tumor Study-5 (NWTS-5 [NCT00002611]) showed that time to recurrence and site of recurrence are no longer prognostically significant. However, in a Société Internationale d’Oncologie Pédiatrique (SIOP) study, patients who experienced a pulmonary relapse within 12 months of diagnosis had a poorer prognosis (5-year overall survival [OS], 47%) than did patients who experienced a pulmonary relapse 12 months or more after diagnosis (5-year OS, 75%).
On the basis of these results, the following three risk categories have been identified:
In children who had small stage I Wilms tumor and were treated with surgery alone, the EFS was 84%. All but one child who relapsed was salvaged with treatment tailored to the site of recurrence.
Successful retreatment can be accomplished for Wilms tumor patients whose initial therapy consisted of immediate nephrectomy followed by chemotherapy with vincristine and dactinomycin and who relapse.
Treatment options for standard-risk relapsed Wilms tumor include the following:
Evidence (surgery, radiation therapy, and chemotherapy):
Treatment options for high-risk and very high-risk relapsed Wilms tumor include the following:
Evidence (chemotherapy, surgery, and/or radiation therapy):
Patients with stage II, stage III, and stage IV anaplastic-histology tumors at diagnosis have a very poor prognosis upon recurrence. The
combination of ifosfamide, etoposide, and carboplatin has demonstrated activity
in this group of patients, but significant hematologic toxic effects have been
High-dose chemotherapy followed by autologous HSCT has been utilized for recurrent high-risk patients.
The outcome of autologous stem cell rescue in selected patients is favorable; however, patients with gross residual disease going into transplant do not do as well. No randomized trials of chemotherapy versus transplant have been reported, and case series suffer from selection bias.
Patients in whom such salvage
attempts fail should be offered treatment on available phase I or phase II
Clear cell sarcoma of the kidney has been characterized by late relapses. However, in NWTS-5, most relapses occurred within 3 years, and the most common site of recurrence was the brain.
The optimal treatment of relapsed clear cell sarcoma of the kidney has not been established. Treatment of patients with recurrent clear cell sarcoma of the kidney depends on initial therapy and site of recurrence.
Treatment options for recurrent clear cell sarcoma of the kidney include the following:
Cyclophosphamide and carboplatin should be considered if not used initially. Patients with recurrent clear cell sarcoma of the kidney involving the brain have responded to treatment with ifosfamide, carboplatin, and etoposide (ICE) coupled with local control consisting of either surgical resection and/or radiation.[Level of evidence: 2A]
The use of high-dose chemotherapy followed by stem cell transplant is undefined in patients with recurrent clear cell sarcoma of the kidney.
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with recurrent Wilms tumor and other childhood kidney tumors. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
Malogolowkin M, Cotton CA, Green DM, et al.: Treatment of Wilms tumor relapsing after initial treatment with vincristine, actinomycin D, and doxorubicin. A report from the National Wilms Tumor Study Group. Pediatr Blood Cancer 50 (2): 236-41, 2008.
Reinhard H, Schmidt A, Furtwängler R, et al.: Outcome of relapses of nephroblastoma in patients registered in the SIOP/GPOH trials and studies. Oncol Rep 20 (2): 463-7, 2008.
Grundy P, Breslow N, Green DM, et al.: Prognostic factors for children with recurrent Wilms' tumor: results from the Second and Third National Wilms' Tumor Study. J Clin Oncol 7 (5): 638-47, 1989.
Green DM, Cotton CA, Malogolowkin M, et al.: Treatment of Wilms tumor relapsing after initial treatment with vincristine and actinomycin D: a report from the National Wilms Tumor Study Group. Pediatr Blood Cancer 48 (5): 493-9, 2007.
Warmann SW, Furtwängler R, Blumenstock G, et al.: Tumor biology influences the prognosis of nephroblastoma patients with primary pulmonary metastases: results from SIOP 93-01/GPOH and SIOP 2001/GPOH. Ann Surg 254 (1): 155-62, 2011.
Abu-Ghosh AM, Krailo MD, Goldman SC, et al.: Ifosfamide, carboplatin and etoposide in children with poor-risk relapsed Wilms' tumor: a Children's Cancer Group report. Ann Oncol 13 (3): 460-9, 2002.
Garaventa A, Hartmann O, Bernard JL, et al.: Autologous bone marrow transplantation for pediatric Wilms' tumor: the experience of the European Bone Marrow Transplantation Solid Tumor Registry. Med Pediatr Oncol 22 (1): 11-4, 1994.
Pein F, Michon J, Valteau-Couanet D, et al.: High-dose melphalan, etoposide, and carboplatin followed by autologous stem-cell rescue in pediatric high-risk recurrent Wilms' tumor: a French Society of Pediatric Oncology study. J Clin Oncol 16 (10): 3295-301, 1998.
Campbell AD, Cohn SL, Reynolds M, et al.: Treatment of relapsed Wilms' tumor with high-dose therapy and autologous hematopoietic stem-cell rescue: the experience at Children's Memorial Hospital. J Clin Oncol 22 (14): 2885-90, 2004.
Tannous R, Giller R, Holmes E, et al.: Intensive therapy for high risk (HR) relapsed Wilms' tumor (WT): a CCG-4921/POG-9445 study report. [Abstract] Proceedings of the American Society of Clinical Oncology 19: A2315, 2000.
Spreafico F, Bisogno G, Collini P, et al.: Treatment of high-risk relapsed Wilms tumor with dose-intensive chemotherapy, marrow-ablative chemotherapy, and autologous hematopoietic stem cell support: experience by the Italian Association of Pediatric Hematology and Oncology. Pediatr Blood Cancer 51 (1): 23-8, 2008.
Gooskens SL, Furtwängler R, Vujanic GM, et al.: Clear cell sarcoma of the kidney: a review. Eur J Cancer 48 (14): 2219-26, 2012.
This information is provided by the National Cancer Institute.
This information was last updated on August 15, 2014.
Many children with cancer receive treatment in the outpatient setting, which allows them to stay in school and continue to develop intellectually and socially. However, returning to school can be an emotional experience; our Back to School Program is designed to ease your child's transition back to the classroom.
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The Expressive Arts Therapy program, sponsored by the Leonard P. Zakim Center for Integrative Therapies, provides adult patients, family members, and caregivers with a variety of options to support well-being during cancer treatment. From live music meditation to painting technique workshops, the program offers a range of creative outlets to suit every interest.
Dana-Farber and Children's Hospital, including parking facilities, are fully accessible to people with disabilities. There are wheelchairs at the main entrance, and security staff can provide personal assistance. We also have many educational materials available in large print and audiotape formats.
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Find practical tips and suggestions for individuals caring for a family member or friend with cancer, including creating a caregiving plan, finding community resources, and looking after your own well-being.
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Integrative therapies, also known as complementary therapies, range from acupuncture and massage to nutritional guidance and music therapy. Patients treated at the Zakim Center credit its services with easing nausea, improving circulation, and reducing pain, stress, and anxiety associated with cancer treatment.
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