The mechanical fingerprint of murine excisional wounds

[Display omitted] A multiscale mechanics approach to the characterization of murine excisional wounds subjected to uniaxial tensile loading is presented. Local strain analysis at a physiological level of tension uncovers the presence of two distinct regions within the wound: i) a very compliant peri...

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Veröffentlicht in:	Acta biomaterialia 2018-01, Vol.65, p.226-236
Hauptverfasser:	Pensalfini, Marco, Haertel, Eric, Hopf, Raoul, Wietecha, Mateusz, Werner, Sabine, Mazza, Edoardo
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Sprache:	eng
Schlagworte:	Animals Axial stress Biomechanical Phenomena Coiling Collagen Collagen network Deformation Deformation behavior Female Fibers Fibrillar Collagens - metabolism Formability Genetic modification Injuries Mechanical properties Mice Multiscale mechanics Murine excisional wounds Skin Skin - injuries Skin - metabolism Skin - physiopathology Tension Time Factors Tissues Wound healing Wound Healing - physiology Wounds Wounds and Injuries - metabolism Wounds and Injuries - physiopathology
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description	[Display omitted] A multiscale mechanics approach to the characterization of murine excisional wounds subjected to uniaxial tensile loading is presented. Local strain analysis at a physiological level of tension uncovers the presence of two distinct regions within the wound: i) a very compliant peripheral cushion and ii) a core area undergoing modest deformation. Microstructural visualizations of stretched wound specimens show negligible engagement of the collagen located in the center of a 7-day old wound; fibers remain coiled despite the applied tension, confirming the existence of a mechanically isolated wound core. The compliant cushion located at the wound periphery appears to protect the newly-formed tissue from excessive deformation during the phase of new tissue formation. The early remodeling phase (day 14) is characterized by a restored mechanical connection between far field and wound center. The latter remains less deformable, a characteristic possibly required for cell activities during tissue remodeling. The distribution of fibrillary collagens at these two time points corresponds well to the identified heterogeneity of mechanical properties of the wound region. This novel approach provides new insight into the mechanical properties of wounded skin and will be applicable to the analysis of compound-treated wounds or wounds in genetically modified tissue. Biophysical characterization of healing wounds is crucial to assess the recovery of the skin barrier function and the associated mechanobiological processes. For the first time, we performed highly resolved local deformation analysis to identify mechanical characteristics of the wound and its periphery. Our results reveal the presence of a compliant cushion surrounding a stiffer wound core; we refer to this heterogeneous mechanical behavior as “mechanical fingerprint” of the wound. The mechanical response is shown to progress towards that of the intact skin as healing takes place. Histology and multiphoton microscopy suggest that wounded skin recovers its mechanical function via progressive reconnection of the newly-deposited collagen fibers with the surrounding intact matrix.
doi_str_mv	10.1016/j.actbio.2017.10.021
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Local strain analysis at a physiological level of tension uncovers the presence of two distinct regions within the wound: i) a very compliant peripheral cushion and ii) a core area undergoing modest deformation. Microstructural visualizations of stretched wound specimens show negligible engagement of the collagen located in the center of a 7-day old wound; fibers remain coiled despite the applied tension, confirming the existence of a mechanically isolated wound core. The compliant cushion located at the wound periphery appears to protect the newly-formed tissue from excessive deformation during the phase of new tissue formation. The early remodeling phase (day 14) is characterized by a restored mechanical connection between far field and wound center. The latter remains less deformable, a characteristic possibly required for cell activities during tissue remodeling. The distribution of fibrillary collagens at these two time points corresponds well to the identified heterogeneity of mechanical properties of the wound region. This novel approach provides new insight into the mechanical properties of wounded skin and will be applicable to the analysis of compound-treated wounds or wounds in genetically modified tissue. Biophysical characterization of healing wounds is crucial to assess the recovery of the skin barrier function and the associated mechanobiological processes. For the first time, we performed highly resolved local deformation analysis to identify mechanical characteristics of the wound and its periphery. Our results reveal the presence of a compliant cushion surrounding a stiffer wound core; we refer to this heterogeneous mechanical behavior as “mechanical fingerprint” of the wound. The mechanical response is shown to progress towards that of the intact skin as healing takes place. Histology and multiphoton microscopy suggest that wounded skin recovers its mechanical function via progressive reconnection of the newly-deposited collagen fibers with the surrounding intact matrix.</description><identifier>ISSN: 1742-7061</identifier><identifier>EISSN: 1878-7568</identifier><identifier>DOI: 10.1016/j.actbio.2017.10.021</identifier><identifier>PMID: 29031511</identifier><language>eng</language><publisher>England: Elsevier Ltd</publisher><subject>Animals ; Axial stress ; Biomechanical Phenomena ; Coiling ; Collagen ; Collagen network ; Deformation ; Deformation behavior ; Female ; Fibers ; Fibrillar Collagens - metabolism ; Formability ; Genetic modification ; Injuries ; Mechanical properties ; Mice ; Multiscale mechanics ; Murine excisional wounds ; Skin ; Skin - injuries ; Skin - metabolism ; Skin - physiopathology ; Tension ; Time Factors ; Tissues ; Wound healing ; Wound Healing - physiology ; Wounds ; Wounds and Injuries - metabolism ; Wounds and Injuries - physiopathology</subject><ispartof>Acta biomaterialia, 2018-01, Vol.65, p.226-236</ispartof><rights>2017 Acta Materialia Inc.</rights><rights>Copyright © 2017 Acta Materialia Inc. 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Local strain analysis at a physiological level of tension uncovers the presence of two distinct regions within the wound: i) a very compliant peripheral cushion and ii) a core area undergoing modest deformation. Microstructural visualizations of stretched wound specimens show negligible engagement of the collagen located in the center of a 7-day old wound; fibers remain coiled despite the applied tension, confirming the existence of a mechanically isolated wound core. The compliant cushion located at the wound periphery appears to protect the newly-formed tissue from excessive deformation during the phase of new tissue formation. The early remodeling phase (day 14) is characterized by a restored mechanical connection between far field and wound center. The latter remains less deformable, a characteristic possibly required for cell activities during tissue remodeling. The distribution of fibrillary collagens at these two time points corresponds well to the identified heterogeneity of mechanical properties of the wound region. This novel approach provides new insight into the mechanical properties of wounded skin and will be applicable to the analysis of compound-treated wounds or wounds in genetically modified tissue. Biophysical characterization of healing wounds is crucial to assess the recovery of the skin barrier function and the associated mechanobiological processes. For the first time, we performed highly resolved local deformation analysis to identify mechanical characteristics of the wound and its periphery. Our results reveal the presence of a compliant cushion surrounding a stiffer wound core; we refer to this heterogeneous mechanical behavior as “mechanical fingerprint” of the wound. The mechanical response is shown to progress towards that of the intact skin as healing takes place. 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Local strain analysis at a physiological level of tension uncovers the presence of two distinct regions within the wound: i) a very compliant peripheral cushion and ii) a core area undergoing modest deformation. Microstructural visualizations of stretched wound specimens show negligible engagement of the collagen located in the center of a 7-day old wound; fibers remain coiled despite the applied tension, confirming the existence of a mechanically isolated wound core. The compliant cushion located at the wound periphery appears to protect the newly-formed tissue from excessive deformation during the phase of new tissue formation. The early remodeling phase (day 14) is characterized by a restored mechanical connection between far field and wound center. The latter remains less deformable, a characteristic possibly required for cell activities during tissue remodeling. The distribution of fibrillary collagens at these two time points corresponds well to the identified heterogeneity of mechanical properties of the wound region. This novel approach provides new insight into the mechanical properties of wounded skin and will be applicable to the analysis of compound-treated wounds or wounds in genetically modified tissue. Biophysical characterization of healing wounds is crucial to assess the recovery of the skin barrier function and the associated mechanobiological processes. For the first time, we performed highly resolved local deformation analysis to identify mechanical characteristics of the wound and its periphery. Our results reveal the presence of a compliant cushion surrounding a stiffer wound core; we refer to this heterogeneous mechanical behavior as “mechanical fingerprint” of the wound. The mechanical response is shown to progress towards that of the intact skin as healing takes place. Histology and multiphoton microscopy suggest that wounded skin recovers its mechanical function via progressive reconnection of the newly-deposited collagen fibers with the surrounding intact matrix.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>29031511</pmid><doi>10.1016/j.actbio.2017.10.021</doi><tpages>11</tpages><orcidid>https://orcid.org/0000-0003-3296-9388</orcidid></addata></record>
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subjects	Animals Axial stress Biomechanical Phenomena Coiling Collagen Collagen network Deformation Deformation behavior Female Fibers Fibrillar Collagens - metabolism Formability Genetic modification Injuries Mechanical properties Mice Multiscale mechanics Murine excisional wounds Skin Skin - injuries Skin - metabolism Skin - physiopathology Tension Time Factors Tissues Wound healing Wound Healing - physiology Wounds Wounds and Injuries - metabolism Wounds and Injuries - physiopathology
title	The mechanical fingerprint of murine excisional wounds
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