Kidney Tumors

Wilms' tumor

Wilms' tumor or nephroblastoma is a tumor of the kidneys that typically occurs in children, rarely in adults. Its common name is an eponym, referring to Dr. Max Wilms, the German surgeon (1867-1918) who first described this kind of tumor.

Approximately 500 cases are diagnosed in the U.S. annually. The majority (75%) occur in otherwise normal children; a minority (25%) is associated with other developmental abnormalities. It is highly responsive to treatment, with about 90% of patients surviving at least five years.

Pathology

Pathologically, a triphasic nephroblastoma comprises three elements:

• blastema
  
• mesenchyme
• epithelium

Wilms' tumor is a malignant tumor containing metanephric blastema, stromal and epithelial derivatives. Characteristic is the presence of abortive tubules and glomeruli surrounded by a spindled cell stroma. The stroma may include striated muscle, cartilage, bone, fat tissue, fibrous tissue. The tumor is compressing the normal kidney parenchyma.

The mesenchymal component may include cells showing rhabdomyoid differentiation. The rhabdomyoid component may itself show features of malignancy (rhabdomyosarcomatous Wilms).

Wilms tumor may be separated into 2 prognostic groups based on pathologic characteristics:

• Favorable - Contains well developed components mentioned above
• Anaplastic - Contains diffuse anaplasia (poorly developed cells)

Molecular biology

Mutations of the WT1 gene on chromosome 11 are observed in approximately 20% of Wilms tumors. At least half of the Wilms tumors with mutations in WT1 also carry mutations in CTNNB1, the gene encoding the proto-oncogene beta-catenin.

A gene on the X chromosome, WTX, is inactivated in up to 30% of Wilms tumor cases.

Many cases do not have mutations in any of these genes.

Staging and treatment

Staging is determined by combination of imaging studies, and pathologic findings if the tumor is operable. Treatment strategy is determined by the stage:

Stage I (43% of patients)

For stage I Wilms' tumor, 1 or more of the following criteria must be met:

• Tumor is limited to the kidney and is completely excised.
• The surface of the renal capsule is intact.
• The tumor is not ruptured or biopsied (open or needle) prior to removal.
• No involvement of renal sinus vessels.
• No residual tumor apparent beyond the margins of excision.

Treatment: Nephrectomy + 18 weeks of chemotherapy

Outcome: 98% 4-year survival; 85% 4-year survival if anaplastic

Stage II (23% of patients)

For Stage II Wilms' tumor, 1 or more of the following criteria must be met:

• Tumor extends beyond the kidney but is completely excised.
• No residual tumor apparent at or beyond the margins of excision.
• Any of the following conditions may also exist:
  • Tumor involvement of the blood vessels of the renal sinus and/or outside the renal parenchyma.
  • The tumor has been biopsied prior to removal or there is local spillage of tumor during surgery, confined to the flank.

Treatment: Nephrectomy + abdominal radiation + 24 weeks of chemotherapy

Outcome: 96% 4-year survival; 70% 4-year survival if anaplastic

Stage III (23% of patients)

For Stage III Wilms' tumor, 1 or more of the following criteria must be met:

• Unresectable primary tumor.
• Lymph node metastasis.
• Positive surgical margins.
• Tumor spillage involving peritoneal surfaces either before or during surgery, or transected tumor thrombus.

Treatment: Abdominal radiation + 24 weeks of chemotherapy + nephrectomy after tumor shrinkage

Outcome: 95% 4-year survival; 56% 4-year survival if anaplastic

Stage IV (10% of patients)

Stage IV Wilms' tumor is defined as the presence of hematogenous metastases (lung, liver, bone, or brain), or lymph node metastases outside the abdomenopelvic region.

Treatment: Nephrectomy + abdominal radiation + 24 weeks of chemotherapy + radiation of metastatic site as appropriate

Outcome: 90% 4-year survival; 17% 4-year survival if anaplastic

Stage V (5% of patients)

Stage V Wilms’ tumor is defined as bilateral renal involvement at the time of initial diagnosis. Note: For patients with bilateral involvement, an attempt should be made to stage each side according to the above criteria (stage I to III) on the basis of extent of disease prior to biopsy. The 4-year survival was 94% for those patients whose most advanced lesion was stage I or stage II; 76% for those whose most advanced lesion was stage III.

Treatment: Individualized therapy based on tumor burden

Stage I-IV Anaplasia

Children with stage I anaplastic tumors have an excellent prognosis (80-90% five-year survival). They can be managed with the same regimen given to stage I favorable histology patients.

Children with stage II through stage IV diffuse anaplasia, however, represent a higher-risk group. These tumors are more resistant to the chemotherapy traditionally used in children with Wilms’ tumor (favorable histology), and require more aggressive regimens.

Treatment

Once a kidney tumor is found, surgery can find out whether or not the tumor is cancer. 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. If the tumor is only in the kidney, it can be removed along with the whole kidney (a process called 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.

Renal cell carcinoma

Renal cell carcinoma (RCC) is the most common form of kidney cancer arising from the renal tubule. It is the most common type of kidney cancer in adults. Initial treatment is most commonly a radical or partial nephrectomy. Where the tumour is confined to the renal parenchyma, the 5-year survival rate is 60-70%, but this is lowered considerably where metastases have spread. It is resistant to radiation therapy and chemotherapy, although some cases respond to immunotherapy. Targeted cancer therapies such as sunitinib have improved the outlook for RCC, although they have not yet demonstrated improved survival.

Signs and symptoms

The classic triad is hematuria (blood in the urine), flank pain and an abdominal mass. This is now known as the 'too late triad' because by the time patients present with symptoms, their disease is often advanced beyond a curative stage. In addition, whilst this triad is highly suggestive of RCC, it only occurs in around 15% of the sufferers. Today, the majority of renal tumors are asymptomatic and are detected incidentally on imaging, usually for an unrelated cause.

Signs may include:

• Abnormal urine color (dark, rusty, or brown) due to blood in the urine (found in 60% of cases)
• Loin pain (found in 40% of cases)
• Abdominal mass (25% of cases)
• Malaise, weight loss or anorexia (30% of cases)
• Polycthemia (5% of cases)
• Anaemia resulting from depression of erythropoietin (5% of cases)
• The presenting symptom may be due to metastatic disease, such as a pathologic fracture of the hip due to a metastasis to the bone
• Enlargement of one testicle known as varicocele (usually the left, due to blockage of the left gonadal vein by tumor invasion of the left renal vein -- the right gonadal vein drains directly into the inferior vena cava)
• Vision abnormalities
• Pallor or plethora
• Hirsutism - Excessive hair growth (females)
• Constipation
• Hypertension (high blood pressure) resulting from secretion of renin by the tumour (30% of cases)
Elevated calcium levels (Hypercalcemia)
Paraneoplastic disease

Causes

Renal cell carcinoma affects about three in 10,000 people, resulting in about 31,000 new cases in the US per year. Every year, about 12,000 people in the US die from renal cell carcinoma. It is more common in men than women, usually affecting men older than 55.

Kidney cancer both RCC & TCC currently is diagnosed in some 6,600 people in Britain/UK per annum and some 3,600 people who die are recorded as having died of kidney cancer in a given year. The morbidity rate recorded is thought to underestimate the percentage who die of kidney cancer. Often the cause of death recorded on the death certificate may not mention kidney cancer but the subsequent metastases. It is clear that well over 50% of those diagnosed with kidney cancer in Britain will die as a result of the disease.

Why the cells become cancerous is not known. A history of smoking greatly increases the risk for developing renal cell carcinoma. Some people may also have inherited an increased risk to develop renal cell carcinoma, and a family history of kidney cancer increases the risk.

Increasingly there is a belief that inhalation of a diversity of chemicals may be causal and it is also noted that there is a steady increase in diagnosis in women. That a disproportionate percentage of those diagnosed with kidney cancer are obese is increasingly believed to be a significant factor.

People with von Hippel-Lindau disease, a hereditary disease that also affects the capillaries of the brain, commonly also develop renal cell carcinoma, specifically the clear cell type of RCC. Kidney disorders that require dialysis for treatment also increase the risk for developing renal cell carcinoma.

Pathology

(Renal cell carcinoma)

Gross examination shows a yellowish, multilobulated tumor in the renal cortex, which frequently contains zones of necrosis, hemorrhage and scarring.

Light microscopy shows tumor cells forming cords, papillae, tubules or nests, and are atypical, polygonal and large. Because these cells accumulate glycogen and lipids, their cytoplasm appear "clear", lipid-laden, the nuclei remain in the middle of the cells, and the cellular membrane is evident. Some cells may be smaller, with eosinophilic cytoplasm, resembling normal tubular cells. The stroma is reduced, but well vascularized. The tumor compresses the surrounding parenchyma, producing a pseudocapsule.

Secretion of vasoactive substances (e.g. renin) may cause arterial hypertension, and release of erythropoietin may cause erythrocytosis (increased production of red blood cells).

Radiology

(Renal cell carcinoma)

The characteristic appearance of renal cell carcinoma (RCC) is a solid renal lesion which disturbs the renal contour. It will frequently have an irregular or lobulated margin. 85% of solid renal masses will be RCC. 10% of RCC will contain calcifications, and some contain macroscopic fat (likely due to invasion and encasement of the perirenal fat). Following intravenous contrast administration (computed tomography or magnetic resonance imaging), enhancement will be noted, and will increase the conspicuity of the tumor relative to normal renal parenchyma.

A list of solid renal lesions includes:

• renal cell carcinoma
• metastasis from an extra-renal primary neoplasm
• renal lymphoma
• squamous cell carcinoma
• juxtaglomerular tumor (reninoma)
• transitional cell carcinoma
  
• angiomyolipoma
• oncocytoma
• Wilm's tumor

In particular, reliably distinguishing renal cell carcinoma from an oncocytoma (a benign lesion) is not possible using current medical imaging or percutaneous biopsy.

Renal cell carcinoma may also be cystic. As there are several benign cystic renal lesions (simple renal cyst, hemorrhagic renal cyst, multilocular cystic nephroma, polycystic kidney disease), it may occasionally be difficult for the radiologist to differentiate a benign cystic lesion from a malignant one. A classification system for cystic renal lesions that classifies them based specific imaging features into groups that are benign and those that need surgical resection is available. At diagnosis, 30% of renal cell carcinoma has spread to that kidney's renal vein, and 5-10% has continued on into the inferior vena cava.

Percutaneous biopsy can be performed by a radiologist using ultrasound or computed tomography to guide sampling of the tumor for the purpose of diagnosis. However this is not routinely performed because when the typical imaging features of renal cell carcinoma are present, the possibility of an incorrectly negative result together with the risk of a medical complication to the patient make it unfavorable from a risk-benefit perspective.This is not completely accurate, there are new experimental treatments.

Treatment

If it is only in the kidneys, which is about 40% of cases, it can be cured roughly 90% of the time with surgery. If it has spread outside of the kidneys, often into the lymph nodes or the main vein of the kidney, then it must be treated with adjunctive therapy, including cytoreductive surgery.

Watchful waiting

Small renal tumors represent the majority of tumors that are treated today by way of partial nephrectomy. The average growth of these masses is about 4-5 mm per year, and a significant proportion (up to 40%) of tumors less than 4cm in diameter are benign. More centers of excellence are incorporating needle biopsy to confirm the presence of malignant histology prior to recommending definitive surgical extirpation. In the elderly, patients with co-morbidities and in poor surgical candidates, small renal tumors may be monitored carefully with serial imaging. Most clinicians conservatively follow tumors up to a size threshold between 3-5 cm, beyond which the risk of distant spread (metastases) is about 5%.

Surgery

Surgical removal of all or part of the kidney (nephrectomy) is recommended.This may include removal of the adrenal gland, retroperitoneal lymph nodes, and possibly tissues involved by direct extension (invasion) of the tumor into the surrounding tissues. In cases where the tumor has spread into the renal vein, inferior vena cava, and possibly the right atrium (angioinvasion), this portion of the tumor can be surgically removed, as well. In case of metastases surgical resection of the kidney ("cytoreductive nephrectomy") may improve survival, as well as resection of a solitary metastatic lesion.

Percutaneous therapies

Percutaneous, image-guided therapies, usually managed by radiologists, are being offered to patients with localized tumor, but who are not good candidates for a surgical procedure. This sort of procedure involves placing a probe through the skin and into the tumor using real-time imaging of both the probe tip and the tumor by computed tomography, ultrasound, or even magnetic resonance imaging guidance, and then destroying the tumor with heat (radiofrequency ablation) or cold (cryotherapy). These modalities are at a disadvantage compared to traditional surgery in that pathologic confirmation of complete tumor destruction is not possible.

Medications

RCC "elicits an immune response, which occasionally results in dramatic spontaneous remissions." This has encouraged a strategy of using immunomodulating therapies, such as cancer vaccines and interleukin-2 (IL-2), to reproduce this response. IL-2 has produced "durable remissions" in a small number of patients, but with substantial toxicity. Another strategy is to restore the function of the VHL gene, which is to destroy proteins that promote inappropriate vascularization. Bevacizumab, an antibody to VEGF, has significantly prolonged time to progression, but phase 3 trials have not been published. Sunitinib (Sutent), sorafenib (Nexavar), and temsirolimus, which are small-molecule inhibitors of proteins, have been approved by the U.S. F.D.A.

Sorafenib was FDA approved in December 2005 for treatment of advanced renal cell cancer, the first receptor tyrosine kinase (RTK) inhibitor indicated for this use.

A month later, Sunitinib was approved as well. Sunitinib—an oral, small-molecule, multi-targeted (RTK) inhibitor—and sorafenib both interfere with tumor growth by inhibiting angiogenesis as well as tumor cell proliferation. Sunitinib appears to offer greater potency against advanced RCC, perhaps because it inhibits more receptors than sorafenib. However, these agents have not been directly compared against one another in a single trial.

Temsirolimus (CCI-779) is an inhibitor of mTOR kinase (mamallian target of rapamycin) that was shown to prolong overall survival vs. interferon-α in patients with previously untreated metastatic renal cell carcinoma with three or more poor prognostic features. The results of this Phase III randomized study were presented at the 2006 annual meeting of the American Society of Clinical Oncology.

Chemotherapy

Chemotherapy may be used in some cases, but cure is unlikely unless all the cancer can be removed with surgery. The use of Tyrosine Kinase (TK) inhibitors, such as Sunitinib and Sorafenib, and Temsirolimus are described in a different section.

Vaccine

Cancer vaccines, such as TroVax, are in phase 3 trials for treatment of renal cell carcinoma.

Cryoablation

This involves destroying the kidney tumor without surgery, by freezing the tumor. The process can remove 95% of tumors in one treatment and can be tolerated by patients who are not good candidates for surgery (older or weak patients).

The outcome varies depending on the size of the tumor, whether it is confined to the kidney or not, and the presence or absence of metastatic spread. The Fuhrman grading, which measures the aggressiveness of the tumor, may also affect survival, though the data is not as strong to support this.

The five year survival rate is around 90-95% for tumors less than 4 cm. For larger tumors confined to the kidney without venous invasion, survival is still relatively good at 80-85%. For tumors that extend through the renal capsule and out of the local fascial investments, the survivability reduces to near 60%. If it has metastasized to the lymph nodes, the 5-year survival is around 5 % to 15 %. If it has spread metastatically to other organs, the 5-year survival rate is less than 5 %.

For those that have tumor recurrence after surgery, the prognosis is generally poor. Renal cell carcinoma does not generally respond to chemotherapy or radiation. Immunotherapy, which attempts to induce the body to attack the remaining cancer cells, has shown promise. Recent trials are testing newer agents, though the current complete remission rate with these approaches are still low, around 12-20% in most series.