Tibial Bone Strength is Negatively Affected by Volumetric Muscle Loss Injury to the Adjacent Muscle in Male Mice

Overview

Journal J Orthop Res

Publisher Wiley

Specialty Orthopedics

Date 2023 Jun 19

PMID 37337074

Authors

Albino G Schifino

Marion A Cooley

Roger X Zhong

Junwon Heo

Daniel B Hoffman

Gordon L Warren

Sarah M Greising

Jarrod A Call

Affiliations

Soon will be listed here.

Abstract

This study's objective was to investigate how contractile strength loss associated with a volumetric muscle loss (VML) injury affects the adjacent tibial bone structural and functional properties in male C57BL/6J mice. Mice were randomized into one of two experimental groups: VML-injured mice that were injured at age 12 weeks and aged to 20 weeks (8 weeks postinjury, VML) and 20-week-old age-matched uninjured mice (Uninjured-20). Tibial bone strength, mid-diaphysis cortical geometry, intrinsic material properties, and metaphyseal trabecular bone structure were assessed by three-point bending and microcomputed tomography (µCT). The plantar flexor muscle group (gastrocnemius, soleus, plantaris) was analyzed for its functional capacities, that is, peak-isometric torque and peak-isokinetic power. VML-injured limbs had 25% less peak-isometric torque and 31% less peak-isokinetic power compared to those of Uninjured-20 mice (p < 0.001). Ultimate load, but not stiffness, was significantly less (10%) in tibias of VML-injured limbs compared to those from Uninjured-20 (p = 0.014). µCT analyses showed cortical bone thickness was 6% less in tibias of VML-injured limbs compared to Uninjured-20 (p = 0.001). Importantly, tibial bone cross-section moment of inertia, the primary determinant of bone ultimate load, was 16% smaller in bones of VML-injured limbs compared to bones from Uninjured-20 (p = 0.046). Metaphyseal trabecular bone structure was also altered up to 23% in tibias of VML-injured limbs (p < 0.010). These changes in tibial bone structure and function after a VML injury occur during a natural maturation phase between the age of 12 and 20 weeks, as evidenced by Uninjured-20 mice having greater tibial bone size and strength compared to uninjured-aged 12-week mice.

Citing Articles

Low intensity, high frequency vibration training to improve musculoskeletal function in a mouse model of volumetric muscle loss.

Hoffman D, Schifino A, Cooley M, Zhong R, Heo J, Morris C J Orthop Res. 2024; 43(3):622-631.

PMID: 39610268 PMC: 11806655. DOI: 10.1002/jor.26023.

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