ObjectivesThe primary aim of this study was to verify if shear-wave elastography (SWE) can be used to diagnose ulnar neuropathy at the elbow (UNE). The secondary objective was to compare the cross-sectional areas (CSA) of the ulnar nerve in the cubital tunnel and to determine a cut-off value for this parameter accurately identifying persons with UNE.MethodsThe study included 34 patients with UNE (mean age, 59.35 years) and 38 healthy controls (mean age, 57.42 years). Each participant was subjected to SWE of the ulnar nerve at three levels: in the cubital tunnel (CT) and at the distal arm (DA) and mid-arm (MA). The CSA of the ulnar nerve in the cubital tunnel was estimated by means of ultrasonographic imaging.ResultsPatients with UNE presented with significantly greater ulnar nerve stiffness in the cubital tunnel than the controls (mean, 96.38 kPa vs. 33.08 kPa, p < 0.001). Ulnar nerve stiffness of 61 kPa, CT to DA stiffness ratio equal 1.68, and CT to MA stiffness ratio of 1.75 provided 100% specificity, sensitivity, positive and negative predictive value in the detection of UNE. Mean CSA of the ulnar nerve in the cubital tunnel turned out to be significantly larger in patients with UNE than in healthy controls (p < 0.001). A weak positive correlation was found in the UNE group between the ulnar nerve CSA and stiffness (R = 0.31, p = 0.008).ConclusionsSWE seems to be a promising, reliable and simple quantitative adjunct test to support the diagnosis of UNE.Key Points• SWE enables reliable detection of cubital tunnel syndrome• Significant increase of entrapped ulnar nerve stiffness is observed in UNE• SWE is a perspective screening tool for early detection of compressive neuropathies
Objective We wanted to evaluate dermoscopy as a tool to predict the efficacy of port‐wine stain (PWS) laser treatment. Study Design and Methods Large spot 532 nm laser was used for the treatment of 67 PWS. Efficacy was assessed with an objective 3D digital imaging analysis. Dermoscopy images were taken before the treatment and analyzed semi quantitatively for features and patterns. Results The following dermoscopic features: “superficial vessels,” “deep vessels,” “deep lakes,” “superficial lakes,” and “thick vessels total” were identified as positive determinants of maximal global clearance effect (GCEmax), whereas “thin long vessels,” “bright background total,” “whitish veil,” “white circles,” and “perifollicular erythema” were found to be negative determinants. Rapid response correlated positively with “superficial vessels,” “superficial lakes,” and “thick vessels total” scores and showed inverse correlations with “bright‐red background,” “bright background total,” “white circles,” “peacock eyes,” and “perifollicular erythema” scores. “Superficial vessels,” “thick vessels total,” and “pale‐pink patchy background” were predictors of the lack of response. Dominance of “deep vessels” was a predictor of 75% of responses and dominance of “brown areas” feature was the predictor of clearance. Patients responded to treatment differently, depending on the dermoscopic pattern of PWS. Conclusion Dermoscopy may be useful to predict the response of PWS to laser treatment: its rapidity, the risk of no response, and 75% response and clearance. Lasers Surg. Med. © 2019 Wiley Periodicals, Inc.
SummaryThis article presents possible applications of ultrasound elastography in musculoskeletal imaging based on the available literature, as well as the possibility of extending indications for the use of elastography in the future. Ultrasound elastography (EUS) is a new method that shows structural changes in tissues following application of physical stress. Elastography techniques have been widely used to assess muscles and tendons in vitro since the early parts of the twentieth century. Only recently with the advent of new technology and creation of highly specialized ultrasound devices, has elastography gained widespread use in numerous applications.The authors performed a search of the Medline/PubMed databases for original research and reviewed publications on the application of ultrasound elastography for musculoskeletal imaging.All publications demonstrate possible uses of ultrasound elastography in examinations of the musculoskeletal system. The most widely studied areas include the muscles, tendons and rheumatic diseases. There are also reports on the employment in vessel imaging.The main limitation of elastography as a technique is above all the variability of applied pressure during imaging, which is operator-dependent. It would therefore be reasonable to provide clear guidelines on the technique applied, as well as clear indications for performing the test. It is important to develop methods for creating artifact-free, closed-loop, compression-decompression cycles.The main advantages include cost-effectiveness, short duration of the study, non-invasive nature of the procedure, as well as a potentially broader clinical availability. There are no clear guidelines with regard to indications as well as examination techniques.Ultrasound elastography is a new and still poorly researched method. We conclude, however, that it can be widely used in the examinations of musculoskeletal system. Therefore, it is necessary to conduct large, multi-center studies to determine the methodology, indications and technique of examination.
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