Serial Sarcomere Number is Substantially Decreased Within the Paretic Biceps Brachii in Individuals with Chronic Hemiparetic Stroke

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2021 Jun 26

PMID 34172565

Citations 15

Authors

Amy N Adkins

Julius P A Dewald

Lindsay P Garmirian

Christa M Nelson

Wendy M Murray

Affiliations

Soon will be listed here.

Abstract

A muscle's structure, or architecture, is indicative of its function and is plastic; changes in input to or use of the muscle alter its architecture. Stroke-induced neural deficits substantially alter both input to and usage of individual muscles. We combined in vivo imaging methods (second-harmonic generation microendoscopy, extended field-of-view ultrasound, and fat-suppression MRI) to quantify functionally meaningful architecture parameters in the biceps brachii of both limbs of individuals with chronic hemiparetic stroke and in age-matched, unimpaired controls. Specifically, serial sarcomere number (SSN) and physiological cross-sectional area (PCSA) were calculated from data collected at three anatomical scales: sarcomere length, fascicle length, and muscle volume. The interlimb differences in SSN and PCSA were significantly larger for stroke participants than for participants without stroke ( = 0.0126 and = 0.0042, respectively), suggesting we observed muscle adaptations associated with stroke rather than natural interlimb variability. The paretic biceps brachii had ∼8,200 fewer serial sarcomeres and ∼2 cm smaller PCSA on average than the contralateral limb (both < 0.0001). This was manifested by substantially smaller muscle volumes (112 versus 163 cm), significantly shorter fascicles (11.0 versus 14.0 cm; < 0.0001), and comparable sarcomere lengths (3.55 versus 3.59 μm; = 0.6151) between limbs. Most notably, this study provides direct evidence of the loss of serial sarcomeres in human muscle observed in a population with neural impairments that lead to disuse and chronically place the affected muscle at a shortened position. This adaptation is consistent with functional consequences (increased passive resistance to elbow extension) that would amplify already problematic, neurally driven motor impairments.

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