带腓肠腱膜的腓肠神经营养皮瓣修复KuwadeⅣ型跟腱缺损

目的:回顾性分析带腓肠肌腱膜的腓肠神经营养皮瓣修复KuwadeⅣ型跟腱缺损的临床病例,探讨其手术注意事项及治疗经验。方法:总结2008年5月-2013年8月收治的KuwadeⅣ型跟腱缺损19例,应用带腓肠肌腱膜的腓肠神经营养皮瓣进行一期修复。7例为新鲜损伤,12例为陈旧性缺损。19例跟腱缺损均伴有皮肤及软组织坏死,皮肤缺损范围为4.0 cm×6.0 cm-6.0cm×12.0 cm,跟腱缺损长度为5-9 cm,术中皮瓣切取范围为6.0 cm×5.5 cm-12.0 cm×8.0cm,腓肠腱膜切取范围5.5 cm×6.0cm-10.0 cm×6.0 cm;供区游离植皮修复。客观性评价指标包括关节跖屈、背伸动度及形态学,主观性评价采用AOFAS评分。结果:术后17例跟腱功能重建良好,2例感染控制不良,跟腱移植体部分坏死。皮瓣完全成活13例,创面Ⅰ期愈合。2例术后6天皮瓣远端表皮坏死,经换药后愈合。2例术后10天皮瓣远端部分坏死,经局部皮瓣移位修复愈合,2例感染控制不良者,皮瓣未愈合,移植跟腱部分坏死,经再次清创后,行阔筋膜条修复术,局部皮瓣移位修复。术后19例均获随访,随访时间6~24个月,平均18个月。术后皮瓣略臃肿,但不影响穿鞋,行走功能恢复良好,术后1年AOFAS评分平均80.31分。结论:带腓肠肌腱膜的腓肠神经营养皮瓣用于治疗KuwadeⅣ型跟腱缺损,可以同时修复皮肤及跟腱缺损,是一种较为理想的一期修复方法。     

The AutoQual ultrasound elastography method for quantitative assessment of lateral strain in post-rupture Achilles tendons

This paper presents the AutoQual elastography method: a novel algorithm that improves the quality of 2D displacement field calculation from ultrasound radio frequency (RF) sequences of acutely ruptured Achilles tendons to determine image-lateral strain fields and has potential use for ligaments and muscles. This method uses 2D bicubic spline interpolation of the RF signal, Quality Determined Search, Automatic Search Range and Adaptive Block Size components as a novel combination that is designed to improve continuity and decrease displacement field noise, especially in areas of low signal strength. We present a simple experiment for quantitatively comparing the AutoQual method to a multiscale (MS) elastography method from ultrasound RF sequences of a 5% agar phantom for rigid body motion and known lateral strain loads with speeds up to 5 mm/s. We finally present examples of four in vivo Achilles tendons in various damage states and with manual or artificially controlled passive flexion of the foot. Results show that the AutoQual method offers a substantial improvement on the MS method, achieving similar performance for rigid body tracking at all speeds, a lower normalized square error at all strains induced and a more continuous strain field at higher compression rates. AutoQual also showed a greater average normalized cross correlation for image blocks in the area of interest, a lower standard deviation of the strain field and a visually more acceptable point tracking for in vivo examples. This work demonstrates lateral ultrasound elastography which is robust to the complex passive motion of the Achilles and to various imaging artifacts associated with imaging tendon rupture. This method potentially has a wide clinical application for assessing in vivo strains in and hence mechanical function of any near skin surface tissues that are longitudinally loaded.     

Quantitative Ultrasound Assessment of Cortical Bone Properties Beyond Bone Mineral Density

The development of quantitative ultrasound (QUS) technologies to measure bone is motivated by the need to overcome the limitations of X-ray based methods, measuring bone mineral density (BMD) which is the gold standard to date for the diagnosis of osteoporosis. Because it uses mechanical waves, the ultrasound modality is a particularly relevant means to probe bone mechanical resistance. The vast majority of QUS technologies commercialized to date merely aim to provide surrogate markers for BMD. During the past decade, innovative QUS approaches have emerged to assess bone beyond BMD. This may be achieved by (1) specifically assessing the cortical bone compartment, independently of trabecular bone, and (2) providing intrinsic bone properties such as cortical bone thickness and material properties. One specific motivation is to estimate intracortical porosity, a quantity reflected in material properties. This article aims at an overview of recent QUS developments to measure cortical bone properties. We also draw a picture of the current knowledge on bone material properties of interest for bone QUS. We discuss the potential of ultrasound to provide novel biomarkers of bone health through the assessment of material properties.