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Anomalies of renal formation and position result in interesting radiographs, but their clinical importance lies in their associated conditions. For example, the multicystic dysplastic kidney (MCDK) often involutes, yet the initial evaluation needs to determine if the contralateral kidney is at risk for vesicoureteral reflux (VUR) or ureteropelvic junction (UPJ) obstruction. Although no therapy is needed for unilateral renal agenesis, the link between a solitary kidney and the VACTERL (vertebral, anal, cardiac, tracheoesophageal fistula, renal, limb) and Mayer–Rokitansky (vaginal agenesis) syndromes is the main reason for further evaluation. Hydronephrosis is often seen in abnormalities of position and rotation, but does not necessarily mean that obstruction is present. Therefore, anomalies of renal formation and position often pose more of a diagnostic problem than a surgical one.
The pronephros, which has no adult function, induces the mesonephros to differentiate into the mesonephric duct during the fourth to eighth week of fetal life. The mesonephric duct is the basis of the Wolffian system, which develops into the seminal vesicles, vas deferens, epididymis, and efferent ductules of the testis in boys, and the epoophoron and paraophoron (vestigial remnants between the fallopian tube and ovary) in girls. Between weeks 9 and 12, the ureteric bud branches off the mesonephric duct, contacts the metanephric blastema bud, and induces the development of the entire collecting system of ureter, renal pelvis, calyx, and collecting tubules. The kidney develops via induction of the metanephric blastema by the ureteric bud into Bowman’s capsule, the convoluted tubules, and the loop of Henle. Figure 53.1 illustrates the progression of development from pronephros, to mesonephros, to metanephros.
The kidneys begin at the upper sacral level, with the renal pelvis facing anteriorly. The kidneys ascend either because the lumbar and sacral regions grow faster than the cervical and thoracic regions between 4 and 8 weeks, or because there is active migration. As the kidneys ascend, the renal pelvis rotates medially by 90°, leading to the normal configuration of the renal pelvis lying medial to the parenchyma. During this time, the blood supply shifts from inferior branches of the aorta to more cephalad branches, with the final renal artery being located at about L2. Failure of normal ascent leads to the persistence of a low-lying blood supply.
As the development of the kidney depends on proper interaction between the ureteric bud and the metanephric blastema, it should not be surprising that an abnormality in the location of the ureteral orifice is associated with abnormally induced renal tissue. Examination of the thickness of the renal parenchyma and number of glomeruli associated with normal and ectopic ureters in fetal specimens suggests that it is the initial interaction between bud and blastema, rather than subsequent obstruction or VUR, that determines whether normal renal tissue will develop. Figure 53.2 shows how a ureter that arises in the proper trigonal location (A, E, F) is associated with normal renal parenchyma, whereas a ureter arising from a more cranial location (B, C, D) or caudal location (G, H) is associated with progressively less normal renal parenchyma.
Renal dysplasia and hypoplasia can be considered errors in renal induction. Figure 53.3 shows varying changes from agenesis to dysplasia and hypoplasia of the kidney. Although dysplasia is technically a histologic term, it refers to kidneys that contain primitive tubules either focally or diffusely. These ducts are lined by epithelium and surrounded by swirls of primitive collagen. No treatment is necessary for the dysplastic kidney, but there is an increased risk of reflux in the contralateral kidney. Hypoplastic kidneys are small but otherwise normal with a decreased number of nephrons. Dysplasia can also occur in hypoplastic kidneys. While secondary hypoplasia can occur due to infection or obstruction, two types of hypoplastic kidneys are clinically important: the oligomeganephronic type and the Ask–Upmark kidney. In oligomeganephronia, there is a decrease in the number of nephrons with an associated hypertrophy of the ones that are present. Patients present with polyuria and failure to concentrate their urine but no hypertension. Imaging with ultrasound (US) reveals small kidneys. Medical management with protein restriction and high fluid and salt intake is initiated. Once the glomerular filtration rate drops significantly, dialysis is required. The Ask–Upmark kidney was initially felt to be a developmental problem but is now believed to represent reflux nephropathy. The key finding is a small kidney with segmental hypoplasia, probably secondary to ascending pyelonephritis. VUR and hypertension are usually present. Most patients are older than 10 years of age with a 2:1 female:male ratio. If the disease is unilateral, nephrectomy may cure the hypertension. Bilateral disease is managed medically.
Absence of a kidney may be due to abnormal induction of the metanephric blastema or involution of a multicystic dysplastic kidney. The presence or absence of the ureter is helpful in suggesting the cause of the renal agenesis. Absence of a hemitrigone implies that the ureteral bud failed to form properly. A normal trigone, with some evidence of a ureter leading to a nubbin, suggests involution of a multicystic dysplastic kidney.
Unilateral renal agenesis occurs in 1 per 1000 live births, with a 2:1 male predominance. Unilateral renal agenesis can result in compensatory hypertrophy of the contralateral kidney. The left kidney is more likely to be affected in unilateral renal agenesis. As unilateral renal agenesis is asymptomatic and eventual renal function is normal, the diagnosis is usually made on prenatal US, or it is incidentally found during imaging for other abdominal symptoms. Sometimes it can be suspected on plain abdominal films if the colon is medially deviated at the splenic or hepatic flexures. These patients should consider obtaining a medical alert bracelet so that in case of traumatic injury, the solitary kidney is not inadvertently removed.
In a newborn with the prenatal diagnosis of unilateral renal agenesis, physical examination at the time of birth should be focused on detecting the anomalies present in the VACTERL association ( Box 53.1 ). A voiding cystourethrogram (VCUG) should also be obtained because approximately 30% of VACTERL patients with unilateral renal agenesis will have VUR in the contralateral kidney.
VACTERL evaluation
30% will have VUR in contralateral kidney
Can have abnormal ipsilateral Wolffian structures (vas deferens, seminal vesicle)
Testes are normal
Can have abnormal ipsilateral Müllerian structures (uterus, fallopian tubes, upper vagina—Mayer–Rokitansky syndrome)
Ovaries are normal
Males with unilateral renal agenesis are at risk for abnormal Wolffian structures. The vas and seminal vesicle may be absent (or the seminal vesicle may be present as a cyst), but the ipsilateral testis will be normal. As the seminal vesicle develops as a separate bud from the Wolffian duct at 12 weeks, it can be present in cases of unilateral renal agenesis due to regression of a multicystic dysplastic kidney. Seminal vesicle cysts that are causing symptomatic obstruction are usually removed via a transvesical approach. Conversely, if a vas is found to be abnormal or absent during a hernia repair or orchiopexy, the kidneys should be evaluated postoperatively with US.
Females with unilateral renal agenesis should have their genital anatomy evaluated, as up to 30% will have an abnormality of the Müllerian duct due to the Mayer–Rokitansky syndrome (Müllerian, or uterine, or upper vaginal duplications with or without obstruction, or vaginal agenesis). The abnormal induction of the mesonephric duct is believed to cause partial or complete nonunion of the paired Müllerian ducts. Conversely, 40% of patients with abnormalities of the Müllerian organs will have unilateral renal agenesis or ectopia. In patients with duplicated vaginas but with one of the vaginas being absent or atrophic, the side that is absent/atrophic is also the side without a kidney.
If the diagnosis of Mayer–Rokitansky is not made prenatally, the patients can present either as infants with hydrocolpos, or as adolescents with lower abdominal pain after the onset of menses due to an obstructed vagina or uterus (with or without duplication). Magnetic resonance imaging (MRI) is useful in delineating the pelvic anatomy in these cases. In vaginal agenesis, the vagina is present only as a shallow pouch. There is a wide variety of abnormalities of the vagina, uterus, and fallopian tubes ( Fig. 53.4 ), but the ovaries are embryologically normal.
Bilateral renal agenesis occurs once in 4800 live births and has a 3:1 male predominance. Infants affected with bilateral renal agenesis present with oligohydramnios, pulmonary hypoplasia, and Potter’s facies (low-set ears, broad flat nose, a prominent skin fold beginning over the eye and running to the cheek). The great majority die soon after birth from their pulmonary hypoplasia. The renal arteries and ureters are usually absent, and the bladder is underdeveloped. The vas is usually present, but female genital structures are usually abnormal. The adrenals are usually present but appear round, instead of flattened, due to the lack of compression by the kidneys. Prenatal evaluation and diagnosis are helpful in determining that heroic efforts with extracorporeal membrane oxygenation or hemodialysis are not indicated after delivery if there is no improvement in the thoracic to abdominal circumference during pregnancy. In one case, serial amnioinfusion during pregnancy was successful at reversing pulmonary hypoplasia, and the child did not require intubation after delivery. She underwent peritoneal dialysis and eventual renal transplantation.
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