Tissue alignment enhances remodeling potential of tendon-derived cells - Lessons from a novel microtissue model of tendon scarring
| Autor: | Jess G. Snedeker, Stefania L. Wunderli, Jasper Foolen, S Sandra Loerakker |
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| Přispěvatelé: | Orthopaedic Biomechanics, Soft Tissue Biomech. & Tissue Eng., University of Zurich, Snedeker, Jess G |
| Rok vydání: | 2017 |
| Předmět: |
0301 basic medicine
Cells 0206 medical engineering 610 Medicine & health 02 engineering and technology Matrix (biology) Matrix metalloproteinase Models Biological Tendon Injuries/metabolism Extracellular matrix Tendons 03 medical and health sciences Cicatrix Mice Models Tendon Injuries ddc:570 1312 Molecular Biology medicine Animals Molecular Biology Process (anatomy) Actin Cells Cultured Wound Healing Cultured Tissue Scaffolds Chemistry Anatomy Biological medicine.disease Life sciences 020601 biomedical engineering Actins Tendon Cell biology Tendons/cytology 030104 developmental biology medicine.anatomical_structure Actins/metabolism Cicatrix/metabolism 10046 Balgrist University Hospital Swiss Spinal Cord Injury Center Tendinopathy Wound healing |
| Zdroj: | Matrix Biology, 65, 14-29. Elsevier Matrix Biology, 65 |
| ISSN: | 1569-1802 0945-053X |
| Popis: | Tendinopathy is a widespread and unresolved clinical challenge, in which associated pain and hampered mobility present a major cause for work-related disability. Tendinopathy associates with a change from a healthy tissue with aligned extracellular matrix (ECM) and highly polarized cells that are connected head-to-tail, towards a diseased tissue with a disorganized ECM and randomly distributed cells, scar-like features that are commonly attributed to poor innate regenerative capacity of the tissue. A fundamental clinical dilemma with this scarring process is whether treatment strategies should focus on healing the affected (disorganized) tissue or strengthen the remaining healthy (anisotropic) tissue. The question was thus asked whether the intrinsic remodeling capacity of tendon-derived cells depends on the organization of the 3D extracellular matrix (isotropic vs anisotropic). Progress in this field is hampered by the lack of suitable in vitro tissue platforms. We aimed at filling this critical gap by creating and exploiting a next generation tissue platform that mimics aspects of the tendon scarring process; cellular response to a gradient in tissue organization from isotropic (scarred/non-aligned) to highly anisotropic (unscarred/aligned) was studied, as was a transient change from isotropic towards highly anisotropic. Strikingly, cells residing in an ‘unscarred’ anisotropic tissue indicated superior remodeling capacity (increased gene expression levels of collagen, matrix metalloproteinases MMPs, tissue inhibitors of MMPs), when compared to their ‘scarred’ isotropic counterparts. A numerical model then supported the hypothesis that cellular remodeling capacity may correlate to cellular alignment strength. This in turn may have improved cellular communication, and could thus relate to the more pronounced connexin43 gap junctions observed in anisotropic tissues. In conclusion, increased tissue anisotropy was observed to enhance the cellular potential for functional remodeling of the matrix. This may explain the poor regenerative capacity of tenocytes in chronic tendinopathy, where the pathological process has resulted in ECM disorganization. Additionally, it lends support to treatment strategies that focus on strengthening the remaining healthy tissue, rather than regenerating scarred tissue. Matrix Biology, 65 ISSN:0945-053X ISSN:1569-1802 |
| Databáze: | OpenAIRE |
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