Multiple Gouty Tophi with Bone Erosion and Destruction: A Report of an Early-onset Case in an Obese Patient.

A 27 year-old severely obese man (BMI, 35.1) had hyperuricemia and multiple gouty tophi with bone erosion and destruction, resulting in gait disturbance for 6 years after the early onset of gout at 21 years of age. His hyperuricemia was associated with hyperinsulinemia in obesity and a genetic variant of the ABCG2 gene. In addition, multiple gouty tophi with bone erosion and destruction might have been caused by hypoadiponectinemia and the elevation of the patient' s pro-inflammatory cytokine (IL-1β) level with the accumulation of visceral fat. In this case, bone and Ga-67 scintigraphy were useful for detecting the location and magnitude of gouty tophi.

Introduction

Long-term hyperuricemia leads to gouty arthritis. Hyperuricemia is triggered by several genetic factors as well as environmental factors such as the overconsumption of purine-rich foods and alcohol. Recently, the prevalence of obesity and obesity-related disease, including hyperuricemia has increased (1).

On the other hand, gouty tophi formation is caused by elevated serum uric acid levels, long-term gouty arthritis and the non-treatment period, as reported by many studies (2,3). The prevalence of hyperuricemia and gouty arthritis has increased in association with the degree of serum urate elevation in comparison to the previous decades. In contrast, since hyperuricemia can be effectively controlled by urate lowering therapy, opportunities to treat multiple gouty tophi are decreasing. We herein report the case of a severe obese patient who showed an early-onset gout attack and multiple gouty tophi with bone erosion and destruction that developed over a short period.

Case Report

A 27-year-old man complaining of bilateral knee pain and gait disturbance was admitted to our hospital. He had been obese since childhood. His growth was normal and psychological disorders, including self-mutilation behavior had not been observed. He had drunk alcohol by chance during the previous 7 years. A member of his family had hyperuricemia without gout. The detailed information of his family was unclear. At 21 years of age, he first displayed severe knee pain and gout was suspected by an orthopedist. At the time, he was treated with a painkiller but he had not received any further treatment. Since then, he sometimes suffered from pain. He had a history of excess dietary purine consumption prior to his first gout attack at 21 years of age. Following the attack, he reduced his excessive intake of purine rich foods such as beef, seafood, liver and organ meats; his intake of calories from other sources remained excessive. At 27 years of age, he consulted an orthopedist about gait disorder due to the limited movement of his knee joint. The physician pointed out gout and hyperuricemia. He was then transferred and admitted to our department to undergo further examination and treatment for severe hyperuricemia.

On admission, he was 173 cm tall and weighed 106 kg (body mass index: 35.4 kg/m2). He had severe obesity with visceral fat accumulation (visceral fat area, 176 cm2 ≥100 cm2). His blood pressure was 131/75 mmHg, his pulse rate was 82/min, and his body temperature was 36.3℃. Radiography of the thorax and an electrocardiogram revealed normal findings. The joints of the bilateral fingers and knees had rubor and swelling (Fig. 1). The results of the laboratory tests at admission summarized in Table 1, the patient had severe hyperuricemia (uric acid, 9.7 mg/dL), and his CRP level was slightly elevated (0.31 mg/dL). An examination of the patient's bone metabolism revealed an elevated TRACP-5b level (bone resorption marker), but the patient's BAP (a bone formation marker), Ca, P and vitamin D levels were all within the normal ranges. The patient's rheumatoid factor (RF) and matrix metalloproteinase-3 (MMP-3) were also within the normal ranges. His serum adiponectin level was decreased and his interleukin-1β level was elevated in comparison to the normal ranges.

Figure 1.

A photograph of the bilateral hands and knees.

Table 1.

Laboratory Data on Admission.

Hematological Data			Urinalysis
RBC	538×104 /μL		PH	5.5
Hb	16.0 g/dL		Protein	(-)
WBC	8,900 μL		Glucose	(-)
Plt	24.1×104 /μL		segment	cast (-)
Biochemical and Serological Data
TP	7.6 g/dL		γGTP	52 U/L
Alb	4.6 g/dL		LDH	175 U/L
BUN	8 mg/dL		ALP	261 U/L
Cr	0.54 mg/dL		T-chol	213 mg/dL
UA	9.7 mg/dL		LDL-c	83 mg/dL
Na	139 mEq/L		HDL-c	31 mg/dL
K	4.1 mEq/L		TG	757 mg/dL
Cl	103 mEq/L		FPG	98 mg/dL
Ca	10.0 mg/dL		HbA1c	5.4 %
P	3.8 mg/dL		F-IRI	10.0 μU/mL
AST	15 U/L		CRP	0.31 mg/dL
ALT	14 U/L
RF	<10 U/mL	(<10 U/mL)
MMP-3	43.2 ng/mL	(35.2-123.8 ng/mL)
Adiponectin	1.63 μg/mL	(>4.0 μg/mL)
IL-1β	33 pg/mL	(<10 pg/mL)
PTH	46.6 pg/mL	(10-60 pg/mL)
BAP	15.4μg /L	(3.7-20.9 μg/L)
PINP	54.8 μg/L	(19.5-71.2 μg/L)
OC	2.7 ng/mL	(8.3-32.7 ng/mL)
TRACP-5b	1,620 mU/dL	(170-590 mU/dL)
U-DPD	9.5 nmol/mmoL Cr	(2.1-5.4 nmol/mmoL Cr)
I-CTP	13.0 ng/mL	(<4.5 ng/mL)
1,25(OH)2D3	39 pg/mL	(20-60 pg/mL)
25(OH)D	9 ng/mL	(7-41 ng/mL)		( ): normal range

IRI: immunoreactive insulin

OC: osteocalcin

MMP-3: Matrix Metalloproteinase-3

TRACP-5b: tartrate-resistant acid phopshatate-5b

BAP: Bone Specific Alkaline Phosphatase

U-DPD: urinary deoxypyridinoline

PINP: N-terminal propeptide of type I collagen

I-CTP: carboxyterminal telopeptide of type I collagen

A plain radiograph of the right knee showed a punched-out lesion characterized by gouty tophi (Fig. 2a, arrows). T1-weighted magnetic resonance imaging (MRI) of the left knee, revealed that the nodule had a low signal intensity (Fig. 2b, asterisk), indicating bone erosion and destruction (Fig. 2b, arrows).

Figure 2.

a) A lateral radiograph of the right knee joint. b) Sagittal T1-weighted magnetic resonance imaging of the right knee joint.

A needle biopsy specimen taken from his right elbow showed deposits of an amorphous material that consisted of urate crystals (Fig. 3, asterisk) surrounded by granulomatous inflammation (Fig. 3, arrows). These histological features were compatible with a gouty tophus.

Figure 3.

The histological examination of a punch biopsy specimen from the patient’s right elbow. A representative Hematoxylin and Eosin staining section is shown.

99mTc HMDP bone scintigraphy showed severe accumulation in the joints of both knees and ankles and in the right elbow joint and the left second metacarpophalangeal joint. 99mTc HMDP bone scintigraphy also revealed moderate accumulation in both sternoclavicular and shoulder joints and the right carpometacarpal joint (Fig. 4a). Ga-67 citrate scintigraphy showed the abnormal accumulation in similar sites, which corresponded to the abnormalities on 99mTc HMDP bone scintigraphy (Fig. 4b). Abdominal echography revealed right renal calculi of approximately 1 cm in diameter.

Figure 4.

Whole body scintigraphy. a) 99mTc HMDP bone scintigraphy. b) Ga-67 citrate scintigraphy.

The 24-hour urinary uric acid excretion (UUAE) of the patient ranged from 381 to 792 mg/day during hospitalization. Thus, the UUAE values were not as high as the cut-off point (880 mg/day/1.73 m2) proposed in a previous study (4). On the other hand, the renal clearance of uric acid (CUA) and the renal clearance of uric acid per creatinine clearance (fractional excretion of uric acid, FEUA) were reduced (CUA 1.91 to 4.15 mL/min, FEUA 1.72 to 2.28%, respectively) (Fig. 5a). The plasma levels of hypoxanthine and xanthine were 0.028 mg/dL (reference value, 0-0.05 mg/dL) and 0.0088 mg/dL (reference value, 0-0.31 mg/dL), respectively. The HPRT gene and its associated activity were normal. Genetic variants of the ABCG2 genes (c.376C>T, c.421C>A) and SLC16A9/MCT9 (c.773C>A) were detected, whereas other serum uric acid-related genes such as Uromodulin, SCL17A1NPT1, SLC17A3/NPT4, and ABCC4/MRP4 gene mutations were not detected (5-8). These findings were likely to be associated with the elevation of the patient's serum level of uric acid.

Figure 5.

A summary of the clinical course. a) The clinical course in the hospital. b) The clinical course in the overall treatment period.

After hospitalization, the patient first underwent diet therapy (2,000 kcal/day) without medication for hyperuricemia. However, his serum UA levels remained high. Thus, on the 40th day of hospitalization, the use of pharmacological urate-lowering therapy was initiated. Because of his renal calculi, treatment with a xanthine oxidase inhibitor (febuxostat, 10 mg per day) was initiated (Fig. 5a). After discharge, the dose was increased, and his UA level gradually decreased. However, his UA level remained at 8.5 mg/dL despite the use of febuxostat (60 mg per day). On day 286, additional treatment with benzbromarone (25 mg per day) was initiated because his FEUA had remained low. His FEUA increased to 5.25% and his UA level decreased to 6.1 mg/dL after the use of benzbromarone (50 mg per day) (Fig. 5b and Table 2).

Table 2.

Clinical Course of Indices Related to Excretion of Uric Acid.

Day	7	11	25	42	376	397
							Reference Range
UUAE(mg/kg/h)	0.17	0.33	0.16	0.20	0.19	0.34	(0.483-0.509)
CUA (mL/min)	2.13	4.15	1.91	2.74	3.61	2.40	(7.3-14.7)
FEUA (%)	1.72	2.28	1.98	1.82	2.57	5.25	(5.5-11.1)

Discussion

The clinical course of this case provided two interesting findings. The first finding was the early onset and relatively acute progression of gout. The second was multiple gouty tophi with bone erosion and destruction. Patients with multiple gouty tophi are rarely encountered because hyperuricemia can now be effectively treated. However, this patient developed multiple gouty tophi over the course of only 6 years. Moreover, it was also interesting that inflammation and bone lesions due to gouty tophi could be detected throughout the whole body on nuclear images.

The etiology of the patient's severe hyperuricemia and gout was considered to include mutations of his uric acid transporters and severe obesity. In the present case, an ABCG2 gene mutation and a variant of SLC16A9/MCT9 were detected. Matsuo et al. reported that ABCG2 gene mutations were present in 78.6% of gout patients, and that the presence of the minor alleles of Q126X and Q141K leads to a remarkable decrease in the function of ABCG2. These dysfunctional genotype combinations lead to a more than 75% reduction in the function of ABCG2, and markedly increase the gout risk, conferring an OR of 25.8 (9). In addition, Matsuo et al. reported that severe ABCG2 dysfunction (25% of function) leads to a significant increase in the risk of early-onset gout, with an OR of 22.2 (10). The age of onset in patients with severe ABCG2 dysfunction is 6.5 years younger than that in patients with full function (10). Furthermore, Nakayama et al. reported that a genetic variant of SLC16A9/MCT9 slightly increased the risk of hyperuricemia and gout (11), suggesting that the patient's SLC16A9/MCT9 mutation had a limited role in his hyperuricemia and gout. Although ABCG2 dysfunction has been reported to increase UUAE (12), the UUAE of the patient in the present case did not increase during the clinical course. Thus, it is suggested that other mechanisms, in addition to ABCG2 dysfunction, were important in the uric acid metabolism of the present case. We therefore hypothesized that that the patient's hyperuricemia and gout might have also been caused by his severe obesity. Hyperuricemia has previously been reported to be associated with the impaired renal clearance of uric acid in severely obese subjects (13,14). In addition, we reported that both the visceral fat area and the serum adiponectin concentration were significant explanatory variables for serum uric acid levels (15). Moreover, the change in the visceral fat area was corresponded to the changes in serum uric acid levels over a one-year period in general subjects (15). Several studies have reported that hyperinsulinemia might contribute to a mechanism of impaired renal clearance of uric acid in obese subjects (14,16,17). In the present patient, it is suggested that severe obesity with visceral fat accumulation and hyperinsulinemia were considerably associated with the etiology of hyperuricemia through the decreased renal clearance of uric acid (CUA and EFUA). Since, ABCG2 dysfunction is reported to decrease the renal clearance of uric acid (18), the patient's hyperuricemia might have been partly affected by the decreased renal clearance derived from his ABCG2 dysfunction, in addition to his severe obesity.

In the present case, it was clinically interesting that multiple hot spots in whole body were detected on nuclear imaging, which showed the existence of inflammation (Ga-67 scintigraphy) and bone lesions (99mTc HMDP bone scintigraphy) due to gout. Chowalloor et al. reported that bone scans are highly sensitive but not highly specific in detecting osseous abnormalities (19); although a few reports have already described the evaluation of gouty tophi on nuclear imaging (20-23). The scintigraphic findings in the present case were helpful for the assessment of the location and magnitude of gouty arthritis and tophi (19). Follow-up Ga-67 scintigraphy performed one year after discharge still showed multiple hot spots in the bilateral knee and ankle joints in spite the fact that there was no symptomatic gout attack. It is therefore possible that nuclear imaging is useful for assessing the recovery phase of gout after urate lowering therapy.

The mechanism through which gouty tophi with bone destruction developed in the present patient is considered to involve the activation of osteoclasts because of the elevation of bone resorption markers such as TRACP-5b. Dalbeth et al. demonstrated, through the use of cell culture experiments, that MSU crystals promoted the formation of osteoclasts through the inhibition of osteoprotegerin, which is known to suppress the differentiation of osteoclasts (24). In the present case, the elevation of the patient's bone resorption marker levels might imply that enhanced osteoclastogenesis was involved in the development of bone erosions and destruction. In addition, it is reported that increased levels of pro-inflammatory cytokines such as interleukin (IL)-1β are also associated with the development of bone erosion and destruction (25-27). The levels of these cytokines are elevated in obese subjects. Thus, we suggested that severe obesity-related pro-inflammatory cytokine (IL-1β) elevation partially contributed to development of bone erosion and destruction in the present case. Furthermore, adiponectin is also associated with the bone metabolism. Oshima et al. reported that adiponectin increased bone mass by both suppressing osteoclastogenesis and activating osteoblastogenesis (28). In the present case, the serum adiponectin level was decreased; thus, hypoadiponectinemia might have also been partially involved in bone absorption.

Collectively, in addition to the patient's ABCG2 (and SCL16A9/MCT9) gene mutations, his severe obesity and visceral fat accumulation, hyperinsulinemia and hypoadiponectinemia might have led to the development of severe hyperuricemia and the early onset of multiple gouty tophi with bone lesions, which resulted in gait disturbance, over a period of only 6 years. Thus, the early diagnosis of gout and the early initiation of an appropriate therapy for hyperuricemia are very important when orthopedists and physicians encounter patients with severe obesity and arthritis.

Conclusion

We reported an unusual early-onset case (21 year of age) of multiple gouty tophi including bone erosion and destruction a short period after (6 years) the initial manifestation of gouty arthritis. It is possible that the combination of severe obesity, hypoadiponectinemia and the mutations of genes involved in uric acid transport led to severe hyperuricemia and multiple gouty tophi with bone lesions in the present case. In the present case involving a patient with gouty arthritis and multiple gouty tophy, whole body scintigraphy was useful for investigating the patient's condition and for assessing the location and magnitude of his multiple gouty tophi.

The authors state that they have no Conflict of Interest (COI).