A novel device for investigating structure-function relationships and mechanoadaptation of biological tissues

A novel device for investigating structure-function relationships and mechanoadaptation of biological tissues

Exploring the structure-function relationships of cartilage on a microstructural level is crucial for tissue engineering approaches aiming to restore function. Therefore, a combination of mechanical testing with cell and tissue-level imaging would allow for longitudinal studying loading mechanisms,...

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Veröffentlicht in:Journal of the mechanical behavior of biomedical materials 2023-06, Vol.142, p.105868-105868, Article 105868
Hauptverfasser: Boos, Manuela A., Ryan, Frances A., Linnenschmidt, Felix, Rathnayake, Manula S.B., Nowell, Cameron J., Lamandé, Shireen R., Stok, Kathryn S.
Format: Artikel
Sprache:eng
Schlagworte:
Animals
Cartilage
Cartilage, Articular - physiology
Chondrocytes
Imaging
Mechanical testing
Multiphoton microscopy
Reproducibility of Results
Structure-Activity Relationship
Swine
Tissue Engineering - methods
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container_issue
container_start_page 105868
container_title Journal of the mechanical behavior of biomedical materials
container_volume 142
creator Boos, Manuela A.
Ryan, Frances A.
Linnenschmidt, Felix
Rathnayake, Manula S.B.
Nowell, Cameron J.
Lamandé, Shireen R.
Stok, Kathryn S.
description Exploring the structure-function relationships of cartilage on a microstructural level is crucial for tissue engineering approaches aiming to restore function. Therefore, a combination of mechanical testing with cell and tissue-level imaging would allow for longitudinal studying loading mechanisms, biological responses and mechanoadaptation of tissues at a microstructural level. This paper describes the design and validation of FELIX, a custom-built device for non-destructive image-guided micromechanical evaluation of biological tissues and tissue-engineered constructs. It combines multiphoton microscopy with non-destructive mechanical testing of native soft tissues. Ten silicone samples of the same size were mechanically tested with FELIX by different users to assess the repeatability and reproducibility. The results indicate that FELIX can successfully substitute mechanical testing protocols with a commercial device without compromising precision. Furthermore, FELIX demonstrated consistent results across repeated measurements, with very small deviations. Therefore, FELIX can be used to accurately measure biomechanical properties by different users for separate studies. Additionally, cell nuclei and collagen of porcine articular cartilage were successfully imaged under compression. Cell viability remained high in chondrocytes cultured in agarose over 21 days. Furthermore, there were no signs of contamination indicating a cell friendly, sterile environment for longitudinal studies. In conclusion, this work demonstrates that FELIX can consistently quantify mechanical measures without compromising precision. Furthermore, it is biocompatible allowing for longitudinal measurements. [Display omitted] •New device for image-guided assessment of tissues and tissue engineered constructs.•Combines imaging and mechanical testing to investigate microstructural interactions.•Longitudinal investigation of loading mechanisms and biological responses.•Explores mechanoadaptation of biological specimens at a microstructural level.
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Therefore, a combination of mechanical testing with cell and tissue-level imaging would allow for longitudinal studying loading mechanisms, biological responses and mechanoadaptation of tissues at a microstructural level. This paper describes the design and validation of FELIX, a custom-built device for non-destructive image-guided micromechanical evaluation of biological tissues and tissue-engineered constructs. It combines multiphoton microscopy with non-destructive mechanical testing of native soft tissues. Ten silicone samples of the same size were mechanically tested with FELIX by different users to assess the repeatability and reproducibility. The results indicate that FELIX can successfully substitute mechanical testing protocols with a commercial device without compromising precision. Furthermore, FELIX demonstrated consistent results across repeated measurements, with very small deviations. Therefore, FELIX can be used to accurately measure biomechanical properties by different users for separate studies. Additionally, cell nuclei and collagen of porcine articular cartilage were successfully imaged under compression. Cell viability remained high in chondrocytes cultured in agarose over 21 days. Furthermore, there were no signs of contamination indicating a cell friendly, sterile environment for longitudinal studies. In conclusion, this work demonstrates that FELIX can consistently quantify mechanical measures without compromising precision. Furthermore, it is biocompatible allowing for longitudinal measurements. [Display omitted] •New device for image-guided assessment of tissues and tissue engineered constructs.•Combines imaging and mechanical testing to investigate microstructural interactions.•Longitudinal investigation of loading mechanisms and biological responses.•Explores mechanoadaptation of biological specimens at a microstructural level.</description><identifier>ISSN: 1751-6161</identifier><identifier>EISSN: 1878-0180</identifier><identifier>DOI: 10.1016/j.jmbbm.2023.105868</identifier><identifier>PMID: 37119723</identifier><language>eng</language><publisher>Netherlands: Elsevier Ltd</publisher><subject>Animals ; Cartilage ; Cartilage, Articular - physiology ; Chondrocytes ; Imaging ; Mechanical testing ; Multiphoton microscopy ; Reproducibility of Results ; Structure-Activity Relationship ; Swine ; Tissue Engineering - methods</subject><ispartof>Journal of the mechanical behavior of biomedical materials, 2023-06, Vol.142, p.105868-105868, Article 105868</ispartof><rights>2023 The Authors</rights><rights>Copyright © 2023 The Authors. 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Therefore, a combination of mechanical testing with cell and tissue-level imaging would allow for longitudinal studying loading mechanisms, biological responses and mechanoadaptation of tissues at a microstructural level. This paper describes the design and validation of FELIX, a custom-built device for non-destructive image-guided micromechanical evaluation of biological tissues and tissue-engineered constructs. It combines multiphoton microscopy with non-destructive mechanical testing of native soft tissues. Ten silicone samples of the same size were mechanically tested with FELIX by different users to assess the repeatability and reproducibility. The results indicate that FELIX can successfully substitute mechanical testing protocols with a commercial device without compromising precision. Furthermore, FELIX demonstrated consistent results across repeated measurements, with very small deviations. 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subjects Animals
Cartilage
Cartilage, Articular - physiology
Chondrocytes
Imaging
Mechanical testing
Multiphoton microscopy
Reproducibility of Results
Structure-Activity Relationship
Swine
Tissue Engineering - methods
title A novel device for investigating structure-function relationships and mechanoadaptation of biological tissues
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