Polymyalgia rheumatica (PMR) is the most common inflammatory rheumatic disease in patients older than 50 years, with a higher incidence in women. PMR shares many pathogenetic and epidemiological features with giant cell arteritis (GCA)1, and 50% of patients with GCA also develop PMR symptomatology.2 The typical symptoms of PMR are bilateral aching of the shoulder girdle, neck and hip girdle, and morning stiffness lasting for 30 minutes or more. These symptoms are probably related to inflammation of the subacromial, subdeltoid and trochanteric bursae, and the glenohumeral or hip joints.3,4 The diagnosis of PMR is made primarily on clinical grounds and is bolstered by laboratory evidence of an acute phase reaction. There is no single diagnostic test for PMR, but several diagnostic and classification criteria have been suggested by some groups.5–9 Each set of criteria has advantages and disadvantages. A PMR-associated ultrasound lesion(s) in the shoulders and/or hips is currently acknowledged as diagnostic criteria for the scoring algorithm in the differential diagnosis of PMR.10 However, additional imaging methods for assessing rheumatic diseases are warranted.
Prolonged febrile illness with concomittant non-specific symptoms can be also a sign of PMR as well as GCA. Thus, patients may be referred during differential diagnostics of inflammatory or malignant disease to whole body positron emission tomography (PET) or a combination of PET with computed tomography (PET/CT) using 18F-fluorodeoxyglucose (18F-FDG).11–14 Both GCA and PMR have their own characteristic 18F-FDG PET/CT features, which may occur in a non-mutually exclusive manner.
PMR presents with increased 18F-FDG accumulation in periarticular areas of shoulder and hip girdle and of sternoclavicular joints.15–17 The other location with metabolically active inflammation in PMR patients are the extraarticular synovial structures (bursae). It appears that 18F-FDG detection of extraarticular bursitis using PET/CT might be routinely achievable for PMR patients, with reasonable sensitivity (85.7%) and specificity (88.2%), by considering high 18F-FDG uptake in at least 2 of 3 locations (ischial tuberosity, greater trochanter, spinous processes).18
Contrasting at least in part with PMR, GCA imaging typically reveals increased avidity in the wall of whole aorta, including its branches (subclavian and brachial arteries, brachiocephalic trunk, common iliac arteries and femoral arteries).19–21 Importantly, from the clinical point of view, 18F-FDG uptake in pertinent locations decreases in response to effective treatment in both PMR and GCA. Thus, 18F-FDG PET/CT evaluation may be used for monitoring therapy and for follow up.15,19,22,23
In our previous study, increased 18F-FDG accumulation was detected in the praepubic region in some patients.17 However, a deeper description and pathophysiological explanation of this increased praepubic accumulation is needed. The aim of the present study is to confirm a decrease of praepubic 18F-FDG accumulation in response to treatment and to describe potential correlations to other 18F-FDG PET/CT scan characteristics and to the course of disease, and thereby to support the validation of the praepubic avidity within the general 18F-FDG PET/ CT features of PMR. As a secondary objective, we provide a description of the pathological aspect of the observed praepubic 18F-FDG uptake.
Patients with suspected new or relapsed PMR who underwent 18F-FDG PET/CT examination at Masaryk Memorial Cancer Institute in Brno between February 2010 and March 2016 were retrospectively screened for visually detected presence of praepubic 18F-FDG accumulation. Patients for whom follow up 18F-FDG PET/CT was performed during corticosteroid therapy within the clinical remission phase were eligible for further analysis. All patient had to meet ACR 2012 diagnostic criteria for PMR. Patients who were previously treated for known PMR (with at least 15 months from the termination of therapy) were eligible as well. All patients initially provided their signed informed consent with participation on further retrospective studies and this analysis was approved by the institutional review board. Treatment consisted by prednisone, methylprednisolone or methotrexate in various dosages as listed in Table 1.
Imaging and laboratory results of all patients. Reported baseline treatment was initiated several days after baseline PET/CT B/C = baseline and control; C, L, Th = cervical, lumbal, thoracic interspinous space; FW = Fåhræus-Westergren test; H = hip; M = methylprednisolone; Isch = ischiogluteal bursae; MTX = methotrexate; N = newly diagnosed; P = prednisone; R = relapse; S = shoulder; Scl = sternoclavicular joint; V = vascular uptake with number indicating presence in regions from 6 measuredNo Disease Date of baseline Time to B/FU B/FU FW B/FU CRP B/FU B/ FU region of positivity of B/FU 1 R 11-18-2014 4.0 1.134 44 23 P 15 S 2.23, H 1.25, Scl 1.13, Isch no positivity 3-20-2015 0.576 16 1.4 P 5 H 1.11 no positivity 2 N 2-23-2010 48.7 1.234 120 49 P 15 S 1.65, H 1.24, Scl 1.24, Isch no positivity 3-15-2014 0.812 26 16.9 M 8 no positivity no positivity 3 N 9-1-2014 3.2 2.148 120 137 P 60 S 1.87, Scl 1.45, H 2.31, Isch no positivity 12-8-2014 0.992 35 16.7 P 10 S 1.36 no positivity 4 N 7-24-2010 6.1 1.891 120 56.8 P 40 S 1.78, Scl 1.54, H 1, Isch 2.21, no positivity 1-25-2011 0.345 30 5.7 P 2.5 no positivity no positivity 5 N 3-13-2014 12.0 1.772 60 28.5 P 20 S 2.02, H 1.47, Scl 1.24, Isch V3/6 3-13-2015 0.987 7 1 P 0 no positivity V1/6 6 N 10-14-2013 16.9 1.298 54 45 P 20 S1.78, H1.88, Scl 1.95, L 1.25, 3-13-2015 0.537 6 5.3 P 2.5 no positivity no positivity 7 R 1-3-2014 13.1 1.302 77 78.3 M 16 S 1.78, H 1.87, Scl 1.35, Isch V4/6 2-6-2015 0.403 5 1.9 M 2 no positivity no positivity 8 N 6-9-2012 33.1 1.835 50 76 P 30 S 2.21, H 2.16, Scl 1.8, Isch V4/6 3-13-2015 0.54 14 3.1 P 0 H 1.23 V2/6 9 N 6-3-2015 3.1 1.502 60 41.5 P 15 S 2.36, H 2.24, Scl 2.03, Isch no positivity 9-4-2015 0.76 16 13.4 P 10 no positivity no positivity 10 N 1-8-2014 21.7 1.209 80 78.3 P 60 S 1.84, H1.78, Scl 1.69, Isch 10-30-2015 0.395 10 2.5 P 7.5 no positivity no positivity 11 R 3-4-2015 8.1 1.546 62 16.5 M 48 + S 2.66, H 2.74, Scl 2.0, Isch V5/6 11-5-2015 0.811 30 3.3 MTX 10/ H 1.14, C 1.08, S 1.11, Scl 1.07 V3/6 12 N 2-6-2015 8.3 1.789 120 98.7 M 32 3.03, L 1.45 no positivity 10-16-2015 0.97 40 7.5 M 8 Scl 1.14, Isch 1.21 no positivity 13 N 1-23-2015 14 1.123 70 67.5 P 15 S 1.78, H 1.87, Scl 1.69, Isch no positivity 3-24-2016 0.441 6 1.4 P 5 no positivity no positivity 14 N 9-16-2015 5.8 1.282 74 52 P 20 S 2.44, H 3.04, Scl 2.07, L 1.21 3-9-2016 0.41 24 3.2 P 7.5 no positivity no positivity 15 N 10-26-2015 3.2 1.892 80 118.8 P 30 S 2.93, H 2.97, Isch 3.22, C V4/6 2-1-2016 0.678 5 1.3 P20 no positivity no positivity
18F-FDG PET/CT examination was performed utilizing the hybrid scanner Biograph 64 HR+ Siemens Erlangen, Germany. CT scan was performed in low dose CT (25 mAs eff/120 kV) as well as diagnostic or contrast enhanced CT scan (160 mAs eff/12 kV) (intravenous Iomeron 400, BRACCO, Milan, Italy). All patients had standard preparation prior to examination, including restriction of physical activity for 12 h, fasting for at least 6 h, capillary glycemia below 10 mmol/L (180 mg/dL) prior to 18F-FDG administration and peroral hydration with 500-1,000 mL of plain water. 18F-FDG (UJV Rez, Czech Republic) was administered in a dose range of 327-434 (median 366 MBq) in the baseline study and in a dose range of 301-400 (median 362 MBq) in the follow up examination. After an
18F-FDG uptake was assessed visually and also semi-quantitatively in the defined region of interest (ROI) with calculation of target-to-liver ratios. Liver 18F-FDG uptake (SUVmax) was used as a reference base (measured within the ROI located in the centrum of the right liver lobe). Praepubic 18F-FDG accumulation was semiquantitavely assessed as SUVmax within elliptic ROI located through both preapubic regions while keeping in the safe distance from the bladder based on the investigator discretion. Praepubic-to-liver ratio (SUVmax) was subsequently calculated.
Other regions typical for PMR were systematically described with measurement of SUVmax: shoulders, hips and sternoclavicular joints and extraarticular sites – in ischial tuberosity and between spinous processes where ischiogluteal and interspinous bursae are often presented, respectively. A target-to-liver ratio higher than 1.0 was considered positive in all mentioned regions. For paired organs, the higher value (from the right or left site) was used for target-to-liver calculation. 18F-FDG uptake (SUVmax) within the typical sites for GCA was also systematically evaluated, namely in the walls of following arteries: thoracic aorta, abdominal aorta, brachial and subclavian arteries, iliac and femoral arteries. An artery wall-to-liver ratio higher than 1.0 was also considered positive. The number of positive vascular regions out of six evaluated regions is reported. Again, for paired structures, the higher value (from the right or left site) was used for target-to-liver calculation. The same scan evaluation was performed for follow up scans.
From 89 screened patients, 23 (26%) presented with initial praepubic 18F-FDG PET/CT positivity. 15 patients, 10 women and 5 men with a median age of 70 years, range 53 to 78, underwent also follow up 18F-FDG PET/CT and met inclusion criteria for the presented analysis (Table 2). Twelve out of 15 patients were classified as newly diagnosed; prior to the initiation of corticosteroid therapy, the other three patients had been previously treated for known PMR (with at least 15 months from the termination of therapy). Laboratory values for FW and CRP were obtained for all patients, ± 14 days around 18F-FDG PET/CT (Table 3). Patient number 5 had accompanied giant cell arteritis confirmed histologically by temporal artery biopsy.
Patients’ baseline characteristics Changes in analysed laboratory parameters between baseline and follow up examinationCharacteristics Numbers (%) females 10 (66.7 %) males 5 (33.3 %) median (min-max) 70 years (53-78) median (min-max) 8 months (3-49) Baseline Follow up p-value CRP 57 mg/l (17-137) 3 mg/l (1-17) 0.001 FW 74 mm/hod (44-120) 16 mm/hod (5-40) 0.001
18F-FDG PET/CT characteristic including 18F-FDG dosage are summarized in Table 4. Increased 18F-FDG accumulation (positivity) was observed at baseline in all patients in the praepubic region, with praepubic-to-liver ratios higher than 1.0. This accumulation was obvious by visual evaluation only, as presented in Figure 1, and this finding was always accompanied by additional positivity in 18F-FDG PET/CT scans (Table 1). Other sites with increased accumulation were as follow: around the shoulder girdle in all 15 patients, around the hip girdle in 15 patients, and around sternoclavicular joints in 14 out of 15 patients. 18F-FDG PET/CT positivity was observed also in extraarticular synovial structures, in ischiogluteal bursa in 14 patients and between spinous processes of the vertebrae in 14 patients, most commonly within lumbal region in 13 patients.
Nuclear medicine data at baseline and follow up examinationBaseline Follow up p-value 366 MBq (327-434) 362 MBq (301-400) 0.271 1.50 (1.12-2.15) 0.58 (0.35-0.99) 0.001
Five out of 15 patients presented with increased 18F-FDG accumulation in large arteries as a sign of large vessel vasculitis of GCA. In those with large vessel vasculitis, 18F-FDG PET/CT positivity was at least in 3 of 6 evaluated vascular regions. Increased values of FW and CRP were detected in all patients during initial examination and were correlated to newly diagnosed PMR or to its relapse (Table 3).
Given the retrospective nature of this study, it was not possible to keep a strict interval between baseline and follow up 18F-FDG PET/CT scans. Follow up examinations were timed by clinical purposes rather than by experimental needs. Follow up 18F-FDG PET/CT (median time 8 months, range 3-49) revealed continuing positivity around the shoulder girdle in only 2/15 patients, around hip joints in 3/15, around the sternoclavicular joint in 2/15, in extraarticular synovial structures in ischiogluteal bursae in 1/15 and in interspinous regions of cervical vertebrae in 1/15 patients. In three out of 15 patients, positivity in continuous large vessels was observed, maximally in 3 vessel regions out of 6 measured. In all evaluated locations in all analysed patients, a decrease in 18F-FDG accumulation (target-to-liver ratio) was observed, and no new positivity was indicated, including periarticular, extraarticular tissues or target large vessels. Praepubic accumulation of 18F-FDG was diminished in all patients after treatment with steroids. Praepubic-to-liver ratio was lower than 1.0 post therapy and this decrease in accumulation was clear by visual assessment (Figure 2).
During follow up 18F-FDG PET/CT examination, all patients were undergoing steroid treatment and they reported subjective improvement in health condition, and disease remission was confirmed by attending rheumatologist. The laboratory signs of inflammation, FW, and CRP were decreased as well (Table 3).
In the presented retrospective analysis of 18F-FDG PET/CT findings in patients with proven PMR, 25.8% patients presented with praepubic 18F-FDG uptake with fifteen patients from our cohort being able to undergo follow up 18F-FDG PET/CT examination. We were not able to perform follow up 18F-FDG PET/CT scan in a prospectively defined phase of treatment; instead, the aim was to obtain 18F-FDG PET/CT study during disease remission. During this follow up 18F-FDG PET/CT exam, praepubic accumulation of 18F-FDG was diminished in all 15 patients after treatment with steroids.
In our previous study, praepubic positivity was described only in 5/67 (8%) PMR patients representing only a relatively rare sign of the disease.17 However, 32/67 (48%) patients were examined on an older PET scanner with the rest undergoing examination in a newer hybrid PET/CT scanner with better image resolution. Lower detectability of targed lesions may have occured on 18F-FDG PET scanner alone and also underevaluation of accumulation quantification may result in false negativity (praepubic-to-liver ratio < 1.0). Even if visual accumulation was clearly positive, no patient from our previous cohort met the criterion for positivity. Given the above findings, it is reasonable to speculate that the percentage of positive preapubic accumulation in patients with active PMR would be higher when examined on a hybrid 18F-FDG PET/ CT rather than a PET camera. The overall number of patients with initial praepubic 18F-FDG PET/CT positivity was 23/89 (25.8%). Thus, praepubic accumulation should not be considered a constant and frequent sign of 18F-FDG PET/CT results as it is in periarticular 18F-FDG accumulation in shoulders and hips. In cohorts from previous studies, accumulation in the shoulder groin girdle was observed in 33/35 (94%), in 12/14 (86%) and in 58/67 (87%) and in the hips in 31/35 (89%), in 12/14 (86%) and in 47/67 (70%) PMR patients, respectively.15–17
In a recently published report of 15 patients with PMR and of 9 patients with Elderly-Onset Rheumatoid Arthritis (EORA), praepubic 18F-FDG uptake was recommended as one of the signs to enable differentiation between these two conditions. 24 The incidence of praepubic 18F-FDG uptake (pectineus enthesitis) was relatively high with 9 patients from 15 evaluated which may be related to sample size bias. Patients with PMR developed significantly higher uptake compared to those with EORA.24 Patients in the present study represent a retrospectively described cohort of patients with praepubic 18F-FDG PET/CT positivity that includes post-treatment follow up examination. In light of these findings, it seems possible that increased praepubic accumulation may have been present in previously published case reports including those where axial slices indicating ischiogluteal bursitis were published.18,25-27 Sondag
It is difficult to exactly determine the pathological background of increased 18F-FDG uptake in the praepubic region in patients with PMR. The described accumulation seems to be relatively bordered and with spheric shape in some patients, while with blurry margins in others. MRI may be helpful in further evaluation of this region. Based on the MRI finding presented by Mackie
Our observations confirm that 18F-FDG PET/CT examination seems to be an advantageous one-step diagnostic modality for detecting different variants of PMR, for assessing extent and severity, and for excluding occult malignancy. The follow up exam may be useful in monitoring disease activity including the praepubic location. It is conceivable that the praepubic region will become part of targeted examination for other imaging strategies as is US or MRI and that clinical significance and correlations will be further discovered.
Increased praepubic tracer accumulation is becoming an integral part of 18F-FDG PET/CT evaluation of polymyalgia rheumatica, and is probably a correlate of enthesitis and tenosynovitis at the origin of pectineus and adductor longus muscles ventrally from the pubis. The findings described here were consistently presented in combination with other periarticular accumulations (shoulder and hip girdle and surrounded bursae, sternoclavicular joint) and other extraarticular bursae at some distance from joints such as the ischiogluteal bursae and interspinous bursae in spine. Some patients presented with signs of large vessels vasculitis of GCA. In accordance with other 18F-FDG PET/CT positive locations, praepubic accumulation was decreased in relation to PMR treatment. Our findings support the clinical value of 18F-FDG PET/CT examination of patients with suspected or proved PMR.