Introduction. The healing of Achilles tendon rupture is slow and jogging is usually allowed already 6 months after injury. However, the metabolic status of the healing tendon is largely unknown at the time-points when increased loading is allowed. The purpose of this study was to investigate tendon metabolic response and blood flow at 3, 6 and 12 months after Achilles tendon rupture by positron emission tomography (PET) and ultrasound-Power Doppler (UPD). Materials and Methods. 23 patients that had surgical repair of a total Achilles tendon rupture (3 (n=7), 6 (n=7) or 12 (n=9) months earlier) participated in the study. The triceps surae complex was loaded during 20 min of slow treadmill walking. A radioactive tracer (FDG) was administered during this walking and glucose uptake was measured bilaterally by the use of PET. Blood flow was recorded by UPD and patient reported outcome scored by Achilles tendon rupture score (ATRS) and VISA-A. Non-parametric statistics were used for statistical analysis. Results. Metabolic activity was higher in the healing tendon compared to intact tendon at all time-points, however the activity decreased over time (510%, 260% and 62% higher on the healing side compared to the intact side at 3, 6 and 12 months respectively, p<0.001). The metabolic activity was higher in the core than the periphery of the healing tendon, at 3 and 6 months (p<0.02), but lower at 12 months (p=0.06). Interestingly, metabolic activity was negatively related to ATRS, 6 months after rupture (r=−0.89, p<0.01). UPD was also 100-fold and 61-fold higher respectively in the healing than the intact healthy tendon at 3 months (p<0.05) and 6 months (p=0.06), but not at 12 months. Discussion. These results demonstrate that the healing process measured by metabolic and blood flow activity still remains high 6 months after rupture when increased loading is allowed. In fact, PET determined metabolic activity remained elevated up to a year after injury when measures of hyper-vascularization were normalized. Although speculative, the strong negative correlation between tendon metabolism and patient reported outcome indicates that a high metabolic activity 6 months after the injury may be related to poor healing outcome

The pathology of the posterior acetabular legion in femoroacetabular impingement (FAI) syndrome, so called “contre-coup region”, is still unclear. . 18. F-fluoride positron emission tomography (PET) is a functional imaging modality, which reflects the osteoblast activity. Recent technological advances in PET combined with computed tomography (CT) imaging allowed us to obtain detailed 3-dimensional (3D) morphological information. We evaluated the abnormal uptake of . 18. F-fluoride PET/CT on posterior acetabular lesion in FAI syndrome cases. We enrolled forty-one hips from 41 patients who were diagnosed as FAI syndrome and were performed . 18. F-fluoride PET/CT between October 2014 and October 2016. In each hip, the maximum standardized uptake value (SUV. max. ) on the posterior acetabular was measured. The cases were divided into 4 groups; cam-type (11 cases), pincer-type (7), combined-type (11), dysplastic developmental hip (DDH) with cam morphology (12). The average SUV. max. of the pincer-type was significantly smaller than that of the other 3 groups (p < .05). The percentage of the cases with SUV. max. ≥ 6 was 81.8% in cam-type, 28.6% in pincer-type, 90.9% in combined-type, 91.7% in DDH with cam morphology. Furthermore, the average degree of α angle of the cases of SUV. max. ≥ 6 was significantly higher than that of the cases of SUV. max. < 6 (p = .005). Although actual biomechanical mechanism in contre-coup region is still controversial, this result indicated that the cam morphology related to the posterior acetabular lesion with accelerated bone metabolism

We performed positron emission tomography (PET) with . 18. fluorine-fluoro-2-deoxy-D-glucose (FDG) on 55 patients with tumours involving the musculoskeletal system in order to evaluate its role in operative planning. The standardised uptake value (SUV) of FDG was calculated and, to distinguish malignancies from benign lesions, the cases were divided into high (≥ 1.9) and low (< 1.9) SUV groups. The sensitivity of PET for correctly diagnosing malignancy was 100% with a specificity of 76.9% and an overall accuracy of 83.0%. The mean SUV for metastatic lesions was twice that for primary sarcomas (p < 0.0015). Our results suggest that the SUV may be useful in differentiating malignant tumours from benign lesions. However, some of the latter, such as schwannomas, had high SUVs so that biopsy or wide resection was selected as the first operation. Thus, some other quantitative analysis may be required for preoperative planning in cases of high-SUV neurogenic benign tumours. The reverse transcription-polymerase chain reaction revealed that the RNA message of a key enzyme in glucose metabolism, phosphohexose isomerase (PHI)/autocrine motility factor, was augmented in only high FDG-uptake lesions, suggesting that a high expression of the PHI message may be associated with accumulation of FDG in musculoskeletal tumours

The clinical success of posterior lumbar interbody fusion (PLIF) may be limited by pseudarthrosis, defined as the absence of solid fusion 1 year after surgery. Currently, CT is used to diagnose pseudarthrosis but is not able to be conclusive earlier than 1 year after surgery. No non-invasive technique is available to reliably assess bone graft incorporation in the early phase after PLIF. Positron Emission Tomography (PET) is a nuclear imaging modality that is able to identify changes at the cellular and molecular level in an early stage, well before manifestation of anatomical changes. PET/CT with the bone seeking tracer . 18. F-fluoride allows localization and quantification of bone metabolism. This study investigates whether an . 18. F-fluoride PET/CT scan early after PLIF is able to predict the fusion status at 1 year postoperative on CT. Twenty patients after PLIF were enrolled after written informed consent. At 6 weeks and at 1 year after PLIF, intravenous injection of . 18. F-fluoride was followed by a static scan at 60 minutes (Philips, Gemini TF PET/CT). Processing of images resulted in a bone metabolism parameter i.e. standardized uptake value (SUV). This parameter was determined for 3 regions of interest (ROIs): the intervertebral disc space (IDS) and the upper and lower endplate (UE and LE, respectively) of the operated segment. Interbody fusion was scored on a diagnostic CT scan made 1 year postoperatively and was defined as the amount of complete bony bridges between vertebrae, i.e 0, 1 or 2. Based on these scores, patients were divided in either the pseudarthrosis group (score 0) or the fusion group (scores 1 and 2). Differences between groups were analyzed using the independent samples Mann-Whitney U-test. Ten patients were classified as pseudarthrosis (0 bridges: n=10) and 10 patients as fused (1 bridge: n=5, 2 bridges: n=5). Patients in the pseudarthrosis group showed significantly lower bone metabolism values in the IDS on the 6 weeks PET/CT scan compared to patients in the fusion group (SUV. IDS,6w. 13.3±5.62 for pseudarthrosis and 22.6±6.42 for the fusion group, p=0.003), whereas values at the endplates were similar (SUV. UE,6w. 20.3±5.85 for pseudarthrosis and 21.6±4.24 for the fusion group, p=0.282). Furthermore, only in the pseudarthrosis group, bone metabolism in the IDS was significantly lower than at the endplates (p=0.006). In the fusion group, bone metabolism in the IDS and at the endplates was similar (p=0.470). The PET/CT scan at 1 year postoperative showed that in the pseudarthrosis group, bone metabolism of the IDS remained lower compared to the endplates (SUV. IDS,1y. 13.2±4.37, SUV. UE,1y. 16.4±5.33, p=0.004), while in the fusion group, IDS and endplate bone metabolism was similar (SUV. IDS,1y. 13.6±2.91, SUV. UE,1y. 14.4±3.14, p=0.397). This study shows that low bone metabolism values in the IDS of the operated segment as seen on . 18. F-fluoride PET/CT 6 weeks after PLIF, is related to development of pseudarthrosis 1 year postoperatively. These results suggest that . 18. F-fluoride PET/CT might be an early diagnostic tool to identify patients prone to develop pseudarthrosis after PLIF

Focal knee resurfacing implants (FKRIs) are typically intended to treat focal cartilage defects in middle-aged patients. All currently available FKRIs are (partly) composed of metal, which potentially leads to degeneration of the opposing articulating cartilage and hampers follow-up using magnetic resonance imaging (MRI). The purpose of this study was to investigate the in vivo osseointegration process of a novel non-degradable thermoplastic polycarbonate-urethane (TPU) osteochondral implant. Bi-layered implants measuring 6 mm in diameter, with a double-curvature to match the approximate curvature of the goat medial femoral condyle were fabricated. TPU implants were composed of an articulating Bionate® II 80A top layer, and a Bionate® 75D bottom layer (DSM Biomedical, Geleen, the Netherlands) which is intended to osseointegrate. A biphasic calcium phosphate coating formulation, optimized during a prior in vitro study, was applied to half of the TPU implants, while the other half was left uncoated. Bi-layered metal implants (articulating cobalt-chromium top layer and titanium bottom layer) were used as positive control implants. Eight implants per group were implanted bilaterally in the medial femoral condyle of the stifle joints in 12 Dutch milk goats. 18F-sodium fluoride (18F-NaF) positron emission tomography-computed tomography (PET-CT) scanning was performed at 3 and 12 weeks postoperatively, and the corrected maximum standard uptake values (cSUVmax) was calculated to assess the peri-implant bone metabolism. After sacrifice 12 weeks postoperatively, bone histomorphometric analysis was performed to assess the bone-to-implant contact area (BIC). Student's T-test was used in case of normal distribution and the Mann-Whitney-U-test was used in case of abnormal distribution for comparison of BIC and cSUVmax. The BIC value of 10.27 ± 4.50% (mean ± SD) for the BCP-coated TPU implants was significantly (P=0.03) higher than the 4.50 ± 2.61% for the uncoated TPU implants. The uncoated TPU implants scored significantly (P=0.04) lower than the BIC of 12.81 ± 7.55% for the metal implants, whereas there was no significant difference between BCP-coated TPU implants and the metal implants (P=0.68). There was a strong correlation between the cSUVmax values and the BIC values at 12 weeks (Pearson's R=0.74, P=0.001). The cSUVmax values significantly decreased between 3 and 12 weeks for the metal implants (p=0.04). BCP-coated TPU implants followed a similar trend but did not reach statistical significance (p=0.07). cSUVmax in the uncoated TPU implants did not show a significant difference between the time-points (p=0.31). Osseointegration of BCP-coated TPU implants did not significantly differ from metal implants. 18F-NaF PET-CT is a feasible modality to assess osseointegration patterns and showed a similar trend between the BCP-coated and metal implants. Hence, an implant fully composed of TPU may avoid the typical metal-related drawbacks of currently available FKRIs. Long-term follow-up studies are advocated to address the effects of the implant to the opposing cartilage, and are therefore warranted