Imaging and Treatment of Chronic Midportion Achilles Tendinopathy Robert-Jan de Vos ISBN: 978-90-8559-053-8 Cover by: Robert-Jan de Vos, Evelien Kerkhof and Remko Verhagen Layout and printing: Optima Grafische Communicatie, Rotterdam, the Netherlands © R.J. de Vos, the Netherlands, 2010. All rights reserved. No part of this thesis may be reproduced or transmitted in any form or by any means, without prior written permis- sion by the author Imaging and Treatment of Chronic Midportion Achilles Tendinopathy Beeldvorming en behandeling van chronische midportion Achilles tendinopathie Proefschrift ter verkrijging van de graad van doctor aan de Erasmus Universiteit Rotterdam op gezag van de rector magnificus Prof.dr. H.G. Schmidt en volgens het besluit van het College voor Promoties De openbare verdediging zal plaatsvinden op woensdag 22 September 2010 om 15.30 uur Door Robert Johannes de Vos Geboren te Gouda PRoMoTIeCoMMIssIe Promotoren Prof.dr.ir. H. Weinans Prof.dr. J.A.N. Verhaar overige leden Prof.dr. B.W. Koes Prof.dr. R.L. Diercks Prof.dr. C.N. van Dijk Copromotoren dr. J.L. Tol dr. H.T.M. van Schie Contents Chapter 1 General Introduction 7 Chapter 2 Interobserver reliability of neovascularisation score using Power 23 Doppler ultrasonography in midportion Achilles tendinopathy Chapter 3 The value of Power Doppler ultrasonography in Achilles 35 tendinopathy – a prospective study Chapter 4 Ultrasonographic Tissue Characterisation of human Achilles 49 tendons: quantification of tendon structure through a novel non-invasive approach Chapter 5 Tendon structure is not related to clinical outcome following 63 eccentric exercises in chronic midportion Achilles tendinopathy Chapter 6 Effects of platelet-rich plasma on ultrasonographic findings in 79 chronic midportion Achilles tendinopathy Chapter 7 The additional value of a night splint to eccentric exercises 95 in chronic midportion Achilles tendinopathy – a randomised controlled trial Chapter 8 Autologous growth factor injections in chronic tendinopathy – 111 a systematic review Chapter 9 Platelet-rich plasma injection for chronic Achilles tendinopathy – 129 a randomised controlled trial Chapter 10 General Discussion 145 Chapter 11 Summary 161 Appendices Nederlandse samenvatting 171 Dankwoord 179 Curriculum Vitae 183 PhD Portfolio Summary 185 List of publications 189 VISA-A questionnaire 193 Chapter 1 General Introduction General Introduction 9 PRefACe According to the Greek mythology Achilles, the legendary warrior from Iliad, was in- vulnerable except for his heel. Since he died due to an arrow that pierced his Achilles tendon, the “Achilles’ heel” symbolises a person’s principal weakness. Nowadays, weak- ness of the Achilles tendon is increasingly gaining attention to medical specialists. Achilles tendon disorders are a common entity in middle-aged active people, but can also affect the sedentary individuals.1-3 With increasing sports participation in the general population, the number of overuse injuries has increased.1 Tendon disorders comprise 30-50% of all sports-related injuries 3 and there is a lifetime risk of 52% in elite long-distance runners of suffering from an Achilles tendon injury.4 Despite the high prevalence there is still a lack of knowledge about the aetiology and pathogenesis of these injuries. The terminology used to describe chronic tendon disorders has changed in the past few decades.5 For many years this condition was persistently defined as “tendinitis”, de- noting an inflammation of the tendon. Several authors proposed abandoning this term, as there were no signs of inflammation in chronic painful tendons analysed after biopsy or with microdialysis.5-8 To redress this confusing terminology, the term “tendinopathy” was introduced to describe the clinical condition. Histopathological studies showed that tendinopathy is frequently characterised by degeneration of the tendon tissue, also referred to as “tendinosis”.7 The term tendinosis is based on histopathological character- istics and should only be used after histopathological confirmation.3 The treatment of tendinopathy has been challenging in sports medicine and orthopaedics and therefore it is becoming a major problem in this field. Below an overview will be given on several aspects of chronic Achilles tendon disorders, with a special focus on the imaging and treatment modalities. AnAToMy of The AChIlles Tendon The Achilles tendon is the strongest and largest tendon in the human body, which con- nects the calf muscles with the calcaneal bone.9 The midportion of the tendon shows a spiral rotation around its axis that works as an elastic coil functioning as an energy- storing tendon to improve the efficiency of locomotion.9,10 During running the Achilles tendon is subjected to tensile loads up to twelve times the body weight.11 These forces are transmitted through the tendon collagen bundles, which are hierarchically arranged and well ordered predominantly in a longitudinal direction (Figure 1.1).12 The densely packed collagen, mainly type I fibres, gives the tendon its typical white glistening ap- pearance.13 Tendon collagen is the main extracellular matrix (ECM) component and it is 10 Chapter 1 figure 1.1 – The hierarchical structure of a tendon. Collagen forms microfibrils, fibrils, and fibres. A group of fibres constitutes a fascicle. The fascicles unite to form bundles, and are surrounded by the endotenon. The endotenon is a mesh of connective tissue that holds the bundles together and allows some movement of the bundles relative to each other. It carries the longitudinally running blood vessels and nerves. A fine connective tissue sheath, the epitenon, is continuous throughout its inner surface with the endotenon and surrounds the whole tendon. The paratenon is a thin membrane surrounding the epitenon and functions as an elastic sleeve permitting free movement of the tendon against adjacent structures. The peritendon is a general descriptor that consists of the epitenon and the paratenon (modified from Kirkendall & Garret, 1997). produced by sparsely distributed tenocytes.2,7 The tenocytes, or specialised fibroblasts, normally have a flat phenotype. The major non-collagenous ECM constituents are water and proteoglycans which are core proteins that link the glycosaminoglycans (GAGs) to one large glycosaminoglycan chain.14 The GAGs contain large amounts of bonded negatively charged sulphate ions and thereby extract also free positive charged ions (sodium) from the environment. The subsequent resulting high concentrations of ions attract water in order to balance the internal and external ion concentrations.15 As long as the collagen fibres are well-organised and intact, the matrix does not expand due to the water attraction. The collagen fibres are exposed to an internal stress that balances the water impression. The collagen fibres in the ECM of healthy tendons are in a state of dynamic equilibrium between synthesis and degradation regulated by matrix metal- loproteinases and their inhibitors.7,16 Small blood vessels run throughout the Achilles tendon in the longitudinal plane. The blood supply of the Achilles tendon is physiologically the lowest in the midportion, 2-7 cm proximal from the insertion of the tendon on the calcaneal bone.13,14 This area is therefore defined as the “watershed region”, although this limited blood supply should be sufficient for the metabolic needs of the tendon.17 The longitudinally arranged blood vessels are accompanied by nerves and it is known that the body of the tendon is poorly innervated.
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