Applied Radiology

Dr. Zayas is a Fellow in Musculoskeletal Radiology and Dr. Pierre-Jerome and Dr. Monu are Associate Professors in the Department of Radiology, University of Rochester School of Medicine and Dentistry, Rochester, NY; and Dr. Calimano and Dr. Acosta are Fellows in Musculoskeletal Radiology in the Department of Radiology, University of Florida College of Medicine, Gainesville, FL.

Gout is a metabolic disorder characterized by a derangement of purine metabolism manifested by hyperuricemia, deposition of monosodium urate monohydrate crystals in the synovial fluid leukocytes, gross deposits of sodium urate in the periarticular soft tissues, and recurrent episodes of arthritis. ¹ The disease primarily affects the musculoskeletal system. However, many patients also present with associated genitourinary manifestations, such as chronic interstitial nephropathy and urolithiasis.

Gout may be classified as primary or secondary (Table 1). Primary gout results from inborn errors in the metabolism of purines or inherited defects in the renal tubular secretion of urate. Primary gout accounts for 90% of all cases of gout. ² Primary gout is a disease of adult men with only 5% of cases occurring in postmenopausal women. Two effects of estrogen explain this fact. Estrogen promotes renal clearance of uric acid and protects against membranolysis by urate crystals. ³ Secondary gout occurs in disorders characterized by increased turnover of nucleic acids, drugs, or by acquired defects in the renal excretion of urates. Secondary gout accounts for 10% of all cases of gout. ³ Gout, in all of its forms, accounts for about 5% of all cases of arthritis. ⁴

The biochemical hallmark of gout is the elevation of serum urate levels. The risk of developing gout increases with the degree of hyperuricemia. Virtually all patients will have serum urate levels above 7 mg/dL. However, the pathogenesis of the disease is more closely related to the solubility of urate in the various body fluids than to its absolute concentration. Solubility of urate is affected by temperature and pH. ⁵ In the body, the solubility of urate is significantly less at the lower temperatures seen in the peripheral joints; this may partially explain the distribution of the disease in the skeletal system.

Clinical manifestations

The clinical history of gout comprises four distinct stages: asymptomatic hyperuricemia, acute gouty arthritis, chronic tophaceous gout, and nephrolithiasis/nephropathy. These stages proceed in a roughly chronological order in the majority of patients. However, nephrolithiasis may precede the arthritis in up to 20% of cases. ⁶

Asymptomatic hyperuricemia

This stage of gout refers to elevation of serum urate levels prior to the development of any symptoms. Acute attacks of arthritis, urolithiasis, or both mark the end of this stage of the disease.

Acute gouty arthritis

The most common manifestation of this stage is a painful arthritis. Approximately 90% of early gout attacks are monoarticular, usually involving the lower extremities. The first metatarsophalangeal joint is the most common site of initial involvement (seen in at least 50% of cases) and may be altered in up to 90% of patients with gout over the course of the disease. ⁷ Other initial sites of involvement include the ankles, heels, knees, wrists, fingers, and elbows. Inflammatory changes are uncommon in the spine, hips, shoulders, and sacroiliac, and temporomandibular joints. Any joint, however, may be affected by gout.

Acute attacks may be precipitated by events such as trauma, surgery, alcohol or other dietary indiscretions, or systemic infection. Although the course varies, initial attacks are usually self-limited with the pain resolving within a few hours or a few days even without treatment.

Chronic tophaceous gout

This phase occurs in <50% of patients who experience recurrent acute attacks. ⁶ The attacks in this stage will tend to be more severe and prolonged, and will commonly be polyarticular. At this point in the disease, there will be gross deposition of monosodium urate crystals around the joints (tophi).

The tophus is the pathognomonic lesion of gout and is essentially a foreign body granuloma. Tophaceous deposits appear in cartilage, ligaments and tendons, bursae, and synovial membranes and other periarticular soft tissues at a rate equal to the degree and duration of hyperuricemia. ⁴ Tophi are frequently seen in the external ear and pressure points over the elbows, hands, feet, knees, and forearms. Tophi may ulcerate and express whitish, chalky material. Although painless, their presence ultimately can limit joint motion. ⁵ As they become larger, tophi may calcify or ossify and produce tendon rupture, nerve compression, and/or paralysis.

Reactions to the deposition of crystals in the soft tissues include cartilage degeneration and destruction, synovial proliferation and pannus, destruction of subarticular bone, and proliferation of marginal bone. Fibrous or bony ankylosis may also occur.

Gouty nephropathy/ nephrolithiasis

Two renal syndromes are associated with hyperuricemia: acute urate nephropathy and uric acid urolithiasis. ⁵ Patients also have an increased incidence of calcium oxalate stones because urate crystals serve as nidus for calcium stone formation. Other renal manifestations include hypertension, isosthenuria (inability to concentrate urine), pyelonephritis, and proteinuria. Tophaceous deposits may be seen in the renal medullary interstitium and in the corpus cavernosum, leading to erectile dysfunction. ⁴

Radiologic manifestations

Only 45% of patients with gout manifest radiographic changes. ⁸ These changes develop late in the disease and only after repeated attacks. Therefore, negative radiographs do not exclude gout and are usually of little value in the early diagnosis or evaluation of the disease. Rarely, especially in atypical cases, the radiologist may be the first to raise suspicion about the presence of gout.

The earliest radiographic signs of gout are joint effusion and periarticular swelling. ⁹ These nonspecific changes reflect the inflammatory reaction elicited by the deposition of nonopaque urate crystals in the joint synovial membrane and on the surface of the articular cartilage. As the attack subsides, these radiographic changes will likely disappear.

Bone erosions

Deposits of urate crystals (tophi) form along the margins of the articular cortex and may erode the underlying bone, producing small, sharply marginated, punched-out defects at the joint margins of the small bones of the hand and foot. These erosions may have a cyst-like appearance with thin sclerotic borders (figure 1). They tend to be ovoid in shape, are oriented along the long axis of the bone (figure 1) and frequently have characteristic overhanging edges. ¹

The erosions may be intra-articular, para-articular, or located at a considerable distance from the joint. ⁷ The intra-articular erosions usually start in the margin of the joint and proceed centrally. Para-articular erosions tend to be eccentric and located beneath soft-tissue nodules. In advanced disease, the extensive bony erosions may produce joint destruction and mutilating arthritis (figures 2 and 3).

In about 40% of patients with erosions, an elevated bony margin, known as an overhanging edge, extends outward in the soft tissues apparently covering the tophus. ⁶ Although not pathognomonic, their appearance is strongly suggestive of gout (figure 4).

Soft-tissue abnormalities

The continued deposition of urate crystals in the para-articular tissues causes the development of characteristic large, lumpy soft-tissue nodules representing gouty tophi (figure 4). The lesions may not be seen in radiographs until they reach 5 to 10 mm in diameter. ⁶ In addition to the first metatarsophalangeal joint, other common sites of tophi include the ear, olecranon bursa, and the Achilles tendon (figure 5). Noncalcified tophi made up of only sodium urate have soft-tissue density. Deposition of calcium in the urate collections causes the tophaceous masses to become radiopaque (figure 6). Calcification of a tophus is unusual and may reflect an underlying abnormality of calcium metabolism. The calcific deposits will appear as irregular radiodense areas and are initially seen in the periphery of the tophus. Ossification of the tophi is uncommon.

Articular abnormalities

The joint space is well preserved until late in the course of the disease. ^3,10 The presence of relatively normal joint space and preservation of the articular cartilage with extensive erosions is a distinctive radiographic feature of gout (figure 7). Joint-space narrowing is frequent in advanced cases. Bony ankylosis has been observed, but is a rare finding.

Bone mineralization

In gout, the bone mineral density is preserved until late in the disease. Extensive osteoporosis is not a feature of gout. ^6,9,11 The presence of normal mineralization may help differentiate this condition from rheumatoid arthritis. It is believed that the reason for the presence of normal mineralization is that the duration of the attack is too short to allow the development of osteoporosis of disuse as is seen in rheumatoid arthritis.

Proliferative bony abnormalities and intraosseous manifestations

Bony proliferative changes are occasionally seen in gout. These may be seen as club-shaped metatarsals, metacarpals, and phalanges; enlargement of the ulnar styloid process; and diaphyseal thickening. ^3,7 Secondary osteoarthritic changes are common and can obscure the more characteristic features of the disease.

Intraosseous calcifications reflect the deposition of urate in the bone and are mostly seen in the hands and feet. These appear as punctate or circular calcific lesions usually located in the subchondral or subligamentous bony region. ⁶ The changes may resemble those of enchondromas or bone infarcts. Rarely, cysts in the bone (pseudotumors) representing true tophaceous or urate crystal-rich fluid deposits may be seen, especially in juxta-articular locations (figures 8 and 9). The lesions tend to be well marginated.

Chondrocalcinosis

Five percent of patients with gout have cartilage calcification or chondrocalcinosis. ⁶ Patients with gout often have chondrocalcinosis because they have a predisposition for calcium pyrophosphate dihydrate crystal deposition disease (CPPD). The presence of chondrocalcinosis in gout is usually localized to one or two joints and involves the fibrocartilage alone (figure 10). ⁷ The presence of tophi, intact joint spaces, osseous erosions, and the distribution of disease usually permit differentiation of the two disorders.

Bursitis

Bursal inflammation produces erosive and proliferative changes in the subjacent bone and soft-tissue swelling. ⁷ These changes are most commonly observed in the olecranon bursa along the extensor surface of the elbow (figure 11) and the prepatellar bursa of the knee.

Uric acid stones

Renal stones occur in nearly 20% of patients with gout. In patients with gout, 84% of stones are composed of pure uric acid, 4% are uric acid and calcium oxalate, and 12% are calcium oxalate or phosphate alone. ⁶ The incidence of stones increases with the degree of hyperuricemia. Pure uric acid stones are radiolucent on x-rays and appear as filling defects in the collecting system after contrast administration for intravenous pyelograms. However, pure uric acid stones are hyperdense on non-contrast CT and echogenic under ultrasound.

Differential diagnosis

Patients with gout do not develop radiographic changes until late in the disease and after repeated arthritic attacks. Radiographic evaluation helps establish the diagnosis and determine the severity and extent of the disease. Several arthritic processes form part of the radiographic differential diagnosis of gout; the most common processes will be discussed in this section.

CPPD

Calcium pyrophosphate dihydrate crystal deposition disease can produce an acute arthritis with symptoms identical to gout (pseudogout); up to 40% of patients with gout concomitantly have CPPD. The characteristic radiographic changes of CPPD are chondrocalcinosis and degenerative arthropathy. These changes are also seen in gout. However, the chondrocalcinosis seen in CPPD is polyarticular and involves both hyaline and fibrocartilage. ⁷ The arthropathy seen in CPPD involves the matacarpophalangeal, radiocarpal, elbow, shoulder, and knee joints with joint-space narrowing, subchondral sclerosis, and cyst formation. Although the changes could resemble those seen in gout, the absence of tophi and bone erosions helps distinguish CPPD from gouty arthritis.

Psoriasis

Psoriatic arthritis may appear similar to gouty arthropathy. Similar features include normal bone mineralization, erosion, and asymmetric distribution. Also, both processes can produce hyperuricemia, bony proliferation, and soft-tissue swelling. The distinguishing radiographic changes seen in psoriasis include progressive joint-space destruction, paravertebral ossification, and sacroiliac joint involvement.

Rheumatoid arthritis

Although rheumatoid arthritis (RA) and gout are common diseases, their coexistence is extremely rare. Rheumatoid arthritis is not usually mistaken for gout, even though both present with bone erosions and soft-tissue swelling. However, RA presents with marginal bone erosions that are nonproliferative and with soft-tissue swelling that is fusiform. The features that serve to distinguish RA from gout are the presence of symmetric distribution, early joint-space narrowing, and osteopenia.

Joint infection

The coexistence of joint infection and gout is unusual in the general population, but the two conditions may coexist in diabetic patients. Septic arthritis and gouty arthropathy may present with similar radiographic changes including soft-tissue swelling, bone erosions, and monoarticular distribution. The joint space is preserved in gout until late in the disease, whereas rapid destruction of joint space is the norm in septic arthritis.

In a septic joint, there is loss of the lamina dura (articular cortex) over a continuous segment of the bone. This is not usually seen in gout.

Amyloidosis

Amyloidosis may cause soft-tissue masses and cystic/erosive bony lesions indistinguishable from gout. However, amyloidosis tends to be bilateral and symmetric. Periarticular osteopenia is frequent.

Xanthomatosis

Xanthomas (foci of soft-tissue deposition of cholesterol and lipid products) are frequent in the extensor surfaces of the hand and foot, patellar and Achilles tendons, and the subcutaneous soft tissues of the elbows and knees. These xanthomas present radiographically as eccentric soft-tissue masses with associated subjacent bone erosions simulating gout. Differentiation from gout is made by laboratory work-up.

Osteoarthritis

Patients with osteoarthritis (OA) may develop distal nodal soft-tissue swelling and erosions (erosive OA) similar to those seen in gout. However, erosive OA is commonly a disease of elderly women and has a symmetric distribution.

Imaging of gout

The mainstay of imaging in gout is plain radiography of the bones and joints. Plain radiographs will demonstrate many of the features discussed above and enable an accurate diagnosis. Other imaging modalities may also be used in the evaluation or follow-up of a patient with gout. Intravenous urograms may be obtained in the work-up of urinary stones.

Computer tomography (CT) may be used to evaluate bones and joints that may be difficult to image satisfactorily with plain radiography. These include irregularly shaped structures like the pelvic bones, the vertebra, and the sacroiliac and facet joints. Computer tomography imaging will optimally demonstrate bony erosions, destruction, calcifications, and bony proliferations. However, CT does not play a significant role in the primary diagnosis of gout.

Ultrasound is not indicated in the primary work-up of gouty arthritis. It may be used to evaluate soft-tissue swelling or masses when the diagnosis is not known or clear. However, ultrasound may be used to evaluate the urinary system in cases of nephropathy, renal stones, and obstruction.

Radionuclide studies have no significant role in the work-up of gout. Bone scans will give nonspecific findings such as accumulation of radiotracer around areas of inflammation or soft-tissue calcifications.

Magnetic resonance imaging (MRI) is frequently requested when osteomyelitis or septic arthritis is suspected. In acute gout, MRI findings will be similar to those seen in infection. There may be para-articular inflammation seen as abnormal signal on T2-weighted images. In contrast-enhanced studies, there will be abnormal enhancement in the soft tissues around the joint (figure 12). The extent of abnormal signal in the tissues is usually less than would be seen in septic arthritis or osteomyelitis. Calcifications within a tophus will be seen as foci of low or absent signal on all pulse sequences. However, hydrated crystal may show as high signal on T2-weighted images (figure 11C). The MRI appearances of gout are varied and should never be used in isolation to evaluate the disease.

Management

The availability of numerous drugs that abort or prevent acute attacks of arthritis and mobilize tophaceous deposits underscores the importance of establishing an early diagnosis. The use of these drugs is important because many aspects of the disease are related to the duration and severity of the hyperuricemia. ⁵ Management differs according to the stage of the disease and the complications that are present.

Asymptomatic hyperuricemia usually requires no therapy except in patients with marked elevated serum uric acid and a family history of tophaceous gout. These patients should be treated with allopurinol under close medical observation.

Acute attacks are treated with joint immobilization, colchicine, non-steroidal anti-inflammatory agents (NSAIDs), and corticosteroids. Uricosuric agents and allopurinol are of no value in treatment of the acute attack. ⁴

During the interval phase (between acute attacks), patients should avoid high purine foods and excessive alcohol use. Patients should control their weight and hypertension, and maintain a high fluid intake to promote uric acid excretion.

Allopurinol is the drug of choice for treatment of chronic gouty arthritis. ⁵ Uricosuric drugs, such as probenecid and sulfinpyrazone, may also be used. In selected patients, large deforming tophi may be excised surgically. ⁴

Conclusion

Gout is a metabolic disorder characterized by hyperuricemia and tissue deposition of uric acid crystals in the joints, cartilage, and kidneys. The disease may mimic an array of many different skeletal abnormalities. Diagnosis mainly depends on laboratory analysis of serum and synovial fluid to demonstrate hyperuricemia and monosodium urate crystals. Radiologic studies provide a multisystem evaluation to help establish the diagnosis and assess the extent of disease. Plain radiographs of the musculoskeletal system are the mainstay of this imaging assessment. Establishing a prompt diagnosis allows for the timely implementation of therapy with different pharmacologic agents, which are available for both prevention of the disease and control of its more advanced manifestations. AR