Efficacy of tarsal immobilization to alleviate Achilles tendon strain in vivo – direct measurements via a differential variable reluctance transducer™ (DVRT) strain gauge in a canine model

Lister, Stephanie A.

January 1900

Master of Science / Department of Clinical Sciences / Walter C. Renberg / Objective: To measure strain in vivo in the calcanean tendon during trotting in canines, and to compare to strain present after tibiotarsal immobilization. Animals: 6 canines Procedures: A Differential Variable Reluctance Transducer[superscript]TM (DVRT®) strain gauge was surgically implanted on the common gastrocnemius tendon. Surface EMG, % strain, and ground reaction forces were measured prior to intervention and after immobilization. Peak vertical force (Fz), vertical impulse, initial, maximum and final strain, and peak-to-peak EMG amplitude were recorded. Data was analyzed using repeated measures analysis of variance and paired t-tests (p[equal to or less than]0.05). Results: Timing of strain data correlated closely to the hind limb footstrike and EMG activity in all dogs. Maximum tendon strain occurred simultaneous with peak Fz. Continued muscle contraction was evident after immobilization. There was no statistical difference in maximum strain after immobilization compared to normal motion. Minimum strain, both at the beginning and end of the strain curve, was significantly decreased with the immobilized state compared to non-immobilized joints. Conclusions and Clinical Relevance: Tibiotarsal immobilization did not eliminate calcaneal tendon strain during weight bearing. Decreased isometric muscle contraction during swing phase of the gait would account for smaller minimum strain in immobilized joints. Immobilization is frequently applied after Achilles tendon rupture to alleviate strain and force on the sutured repair, with possible complications due to the immobilization method. Direct correlation of strain with tendon force was not made in this study. This would be an important factor before adjusting current treatment recommendations.

Calcaneal tendon

Tendon strain

Immobilization

Biology, Veterinary Science (0778)

Quantification of Achilles tendon force and triceps surae muscle energy production during human locomotion / Consideration of monoarticular and biarticular mechanisms

Kharazi, Mohamadreza

25 August 2023

Aktuelle In-vivo-Methoden zur Bewertung der Belastung und Dehnung der Achillessehne (AT) in der biomechanischen Literatur haben bestimmte Einschränkungen, die sorgfältig berücksichtigt werden müssen. Daher hatte die erste Studie zum Ziel, die AT-Dehnung und -Kraft während der Fortbewegung mithilfe einer genauen, nicht-invasiven Methode zu messen. Die Länge der AT wurde unter Berücksichtigung ihrer Krümmung mit reflektierenden Folienmarkern von der Insertion am Fersenbein bis zum Übergang zwischen der Muskel-Sehnen-Verbindung des Musculus gastrocnemius medialis (GM-MTJ) gemessen. Die Kraft der AT wurde durch Anpassung einer quadratischen Funktion an die experimentelle Kraft-Längen-Kurve der Sehne ermittelt, die aus maximalen freiwilligen isometrischen Kontraktionen (MVC) gewonnen wurde. Die Ergebnisse der zweiten Studie zeigen, dass eine Erhöhung der Gehgeschwindigkeit zu einer 21%igen Abnahme der maximalen AT-Kraft bei höheren Geschwindigkeiten im Vergleich zur bevorzugten Geschwindigkeit führt, während die Nettobelastung der AT-Kraft am Sprunggelenk (ATF-Arbeit) in Abhängigkeit von der Gehgeschwindigkeit zunimmt. Darüber hinaus trugen eine frühere Plantarflexion, erhöhte elektromyografische Aktivität der Muskeln Sol und GM sowie der Energieübertrag von Knie- zu Sprunggelenk durch die biartikulären Musculi gastrocnemii zu einer 1,7- bzw. 2,4-fachen Zunahme der netto ATF-Mechanik-Arbeit bei Übergangs- und maximalen Gehgeschwindigkeiten bei. Das Ziel der dritten Studie war es, die in der ersten Studie vorgeschlagene Methode zu vereinfachen, indem die Anzahl der reflektierenden Folienmarker reduziert wurde, jedoch die hohe Genauigkeit beibehalten wurde. Die Krümmung der AT wurde mithilfe von reflektierenden Folienmarkern zwischen dem Ursprung des GM-MTJ und dem Einführungsmarker am Fersenbein beurteilt. Unsere Ergebnisse zeigen, dass eine Reduzierung der Anzahl der Folienmarker um 70% beim Gehen und um 50% beim Laufen zu einem marginalen Fehler führen würde und somit einen vernachlässigbaren Effekt auf die Länge der AT und die maximale Dehnungsmessung hätte. / Current in vivo methods to assess the Achilles tendon (AT) strain and loading in the biomechanics literature have certain limitations that require careful consideration. Therefore, the first study was to measure the AT strain and quantify AT force during locomotion with an accurate non-invasive method. AT length was measured considering its curvature using reflective foil markers from AT insertion at calcaneus to gastrocnemius medialis muscle-tendon junction (GM-MTJ). The force of the AT was calculated by fitting a quadratic function to the experimental tendon force-length curve obtained from maximum voluntary isometric contractions (MVC). The findings in second study indicate that an increase in walking speed leads to a 21% decrease in maximum AT force at higher speeds compared to the preferred speed, yet the net work of the AT force at the ankle joint (ATF-work) increased as a function of walking speed. Additionally, an earlier plantar flexion, increased electromyographic activity of the Sol and GM muscles, and knee-to-ankle joint energy transfer via the biarticular gastrocnemii contributed to a 1.7 and 2.4-fold increase in the net ATF-mechanical work in the transition and maximum walking speeds. The objective of the third study was to simplify the proposed method in the first study by reducing the number of foil reflective markers while preserving high accuracy. The AT curvature was assessed using reflective foil markers between the GM-MTJ origin and the calcaneal insertion marker. Our results indicate that reducing the number of foil markers by 70% during walking and 50% during running would result in a marginal error and, thus, a negligible effect on the AT length and maximum strain measurement.

Achillessehne

Zerrung der Achillessehne

Achillessehnenkraft

Energiespeicherung und Rückstoß

Muskel-Sehnen-Anpassung

Energieübertragung

Sprunggelenk-Kraft

Maximale Gehgeschwindigkeit

Ultraschall

Gehen und Laufen

Achilles tendon

Achilles tendon strain

Achilles tendon force

Energy storage and recoil

Muscle-tendon adoptation

Energy transfer

Ankle power

Maximum walking speed

Ultrasound

Walking and running

001 Wissen

ZX 9628

ZX 7958

WX 8200

ddc:790

ddc:152

ddc:001