Gözde Dursun scite author profile

The effects of mechanical stress on cells and their extracellular matrix, especially in gliding sections of tendon, are still poorly understood. This study sought to compare the effects of uniaxial stretching on both gliding and traction areas in the same tendon. Flexor digitorum longus muscle tendons explanted from rats were subjected to stretching in a bioreactor for 6, 24, or 48 h, respectively, at 1 Hz and an amplitude of 2.5%. After stimulation, marker expression was quantified by histological and immunohistochemical staining in both gliding and traction areas. We observed a heightened intensity of scleraxis after 6 and 24 h of stimulation in both tendon types, though it had declined again 48 h after stimulation. We observed induced matrix metalloproteinase-1 and -13 protein expression in both tendon types. The bioreactor produced an increase in the mechanical structural strength of the tendon during the first half of the loading time and a decrease during the latter half. Uniaxial stretching of flexor tendon in our set-up can serve as an overloading model. A combination of mechanical and histological data allows us to improve the conditions for cultivating tendon tissues.

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Chondrocyte colonisation of a tissue-engineered cartilage substitute under a mechanical stimulus

Nachtsheim

Dursun

Markert

et al. 2019

Medical Engineering & Physics

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Chondrocyte migration in an acellular tissue‐engineered cartilage substitute

Nachtsheim

Dursun

Markert

et al. 2018

Proc Appl Math and Mech

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Acellular tissue‐engineered cartilage substitutes are promising replacement materials to mend small focal defects. The underlying therapeutic idea is to initially stabilise the defect zone and in a long‐term manner allowing for remodelling processes towards a hyaline cartilage tissue. Crucial for remodelling processes inside the implant, is the cell migration from the adjacent tissue, which will be assessed in this study.

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Development of convolutional neural networks for recognition of tenogenic differentiation based on cellular morphology

Dursun

Tandale

Gulakala

et al. 2021

Computer Methods and Programs in Biomedicine

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Gözde Dursun

Sample-specific adaption of an improved electro-mechanical model of in vitro cardiac tissue

Impact of Uniaxial Stretching on Both Gliding and Traction Areas of Tendon Explants in a Novel Bioreactor

Chondrocyte colonisation of a tissue-engineered cartilage substitute under a mechanical stimulus

Chondrocyte migration in an acellular tissue‐engineered cartilage substitute

Development of convolutional neural networks for recognition of tenogenic differentiation based on cellular morphology

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