A comparative probabilistic analysis of human and chimpanzee rotator cuff functional capacity

Computational musculoskeletal modeling represents a valuable approach to examining biological systems in physical anthropology. Probabilistic modeling builds on computational musculoskeletal models by associating mathematical distributions of specific musculoskeletal features within known ranges of...

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Veröffentlicht in:	Journal of anatomy 2023-09, Vol.243 (3), p.431-447
Hauptverfasser:	MacLean, Kathleen F. E., Langenderfer, Joseph E., Dickerson, Clark R.
Format:	Artikel
Sprache:	eng
Schlagworte:	biomechanics Computer applications Force glenoid inclination glenoid stability human evolution Mathematical models Monkeys & apes muscle attachments Muscle contraction Original Phenotypes Rotator cuff rotator cuff pathology shoulder function stochastic modeling
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container_title	Journal of anatomy
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creator	MacLean, Kathleen F. E. Langenderfer, Joseph E. Dickerson, Clark R.
description	Computational musculoskeletal modeling represents a valuable approach to examining biological systems in physical anthropology. Probabilistic modeling builds on computational musculoskeletal models by associating mathematical distributions of specific musculoskeletal features within known ranges of biological variability with functional outcomes. The purpose of this study was to determine if overlap in rotator cuff muscle force predictions would occur between species during the performance of an evolutionarily relevant horizontal bimanual arm suspension task. This necessitated creating novel probabilistic models of the human and chimpanzee glenohumeral joint through augmentation of previously published deterministic models. Glenohumeral musculoskeletal features of anthropological interest were probabilistically modeled to produce distributions of predicted human and chimpanzee rotator cuff muscle force that were representative of the specific anatomical manipulations. Musculoskeletal features modeled probabilistically included rotator cuff origins and deltoid insertion, glenoid inclination, and joint stability. Predicted human rotator cuff muscle force distributions were mostly limited to alternating between infraspinatus and teres minor, with both 100% and 0% muscle force predicted for both muscles. The chimpanzee model predicted low‐to‐moderate muscle force across all rotator cuff muscles. Rotator cuff muscle force predictions were most sensitive to changes of muscle origins and insertions. Results indicate that functional rotator cuff overlap is unlikely between chimpanzees and humans without greater modifications of the glenohumeral musculoskeletal phenotypes. The results also highlight the low efficacy of the human upper extremity in overhead, weight‐bearing tasks, and propensity for rotator cuff injury. Human and chimpanzee rotator cuff functional overlap was explored using probabilistic musculoskeletal modeling simulations. Regardless of probabilistic modification to anthropologically significant musculoskeletal shoulder anatomy, humans were predicted to overload infraspinatus and teres minor in the computational simulations. The lack of functional species convergence in rotator cuff action and human‐specific infraspinatus overload reveals an anatomical evolutionary pathway for rotator cuff pathology in humans
doi_str_mv	10.1111/joa.13882
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Glenohumeral musculoskeletal features of anthropological interest were probabilistically modeled to produce distributions of predicted human and chimpanzee rotator cuff muscle force that were representative of the specific anatomical manipulations. Musculoskeletal features modeled probabilistically included rotator cuff origins and deltoid insertion, glenoid inclination, and joint stability. Predicted human rotator cuff muscle force distributions were mostly limited to alternating between infraspinatus and teres minor, with both 100% and 0% muscle force predicted for both muscles. The chimpanzee model predicted low‐to‐moderate muscle force across all rotator cuff muscles. Rotator cuff muscle force predictions were most sensitive to changes of muscle origins and insertions. Results indicate that functional rotator cuff overlap is unlikely between chimpanzees and humans without greater modifications of the glenohumeral musculoskeletal phenotypes. The results also highlight the low efficacy of the human upper extremity in overhead, weight‐bearing tasks, and propensity for rotator cuff injury. Human and chimpanzee rotator cuff functional overlap was explored using probabilistic musculoskeletal modeling simulations. Regardless of probabilistic modification to anthropologically significant musculoskeletal shoulder anatomy, humans were predicted to overload infraspinatus and teres minor in the computational simulations. 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This necessitated creating novel probabilistic models of the human and chimpanzee glenohumeral joint through augmentation of previously published deterministic models. Glenohumeral musculoskeletal features of anthropological interest were probabilistically modeled to produce distributions of predicted human and chimpanzee rotator cuff muscle force that were representative of the specific anatomical manipulations. Musculoskeletal features modeled probabilistically included rotator cuff origins and deltoid insertion, glenoid inclination, and joint stability. Predicted human rotator cuff muscle force distributions were mostly limited to alternating between infraspinatus and teres minor, with both 100% and 0% muscle force predicted for both muscles. The chimpanzee model predicted low‐to‐moderate muscle force across all rotator cuff muscles. Rotator cuff muscle force predictions were most sensitive to changes of muscle origins and insertions. Results indicate that functional rotator cuff overlap is unlikely between chimpanzees and humans without greater modifications of the glenohumeral musculoskeletal phenotypes. The results also highlight the low efficacy of the human upper extremity in overhead, weight‐bearing tasks, and propensity for rotator cuff injury. Human and chimpanzee rotator cuff functional overlap was explored using probabilistic musculoskeletal modeling simulations. Regardless of probabilistic modification to anthropologically significant musculoskeletal shoulder anatomy, humans were predicted to overload infraspinatus and teres minor in the computational simulations. 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source	Wiley Online Library Journals Frontfile Complete
subjects	biomechanics Computer applications Force glenoid inclination glenoid stability human evolution Mathematical models Monkeys & apes muscle attachments Muscle contraction Original Phenotypes Rotator cuff rotator cuff pathology shoulder function stochastic modeling
title	A comparative probabilistic analysis of human and chimpanzee rotator cuff functional capacity
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