Changes in Collagen With Aging Maintain Molecular Stability After Overload: Evidence From an In Vitro Tendon Model
Soft tissue injuries are poorly understood at the molecular level. Previous work using differential scanning calorimetry (DSC) has shown that tendon collagen becomes less thermally stable with rupture...
Soft tissue injuries are poorly understood at the molecular level. Previous work using differential scanning calorimetry (DSC) has shown that tendon collagen becomes less thermally stable with rupture...
Strain Measurement of Pure Titanium Covered With Soft Tissue Using X-Ray Diffraction
Measurement of the stress and strain applied to implants and bone tissue in the human body are important for fracture prediction and evaluations of implant adaptation. The strain of titanium (Ti) mate...
Measurement of the stress and strain applied to implants and bone tissue in the human body are important for fracture prediction and evaluations of implant adaptation. The strain of titanium (Ti) mate...
Spatiotemporal Measurement of Freezing-Induced Deformation of Engineered Tissues
J. Biomech. Eng. -- March 2010 -- Volume 132, Issue 3, 031003 (8 pages)
doi:10.1115/1.4000875
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In order to cryopreserve functional engineered tissues (ETs), the microstructure of the extracellular matrix (ECM) should be maintained, as well as the cellular viability since the functionality is closely related to the ECM microstructure. Since the post-thaw ECM microstructure is determined by the deformation of ETs during cryopreservation, freezing-induced deformation of ETs was measured with a newly developed quantum dot (QD)-mediated cell image deformetry system using dermal equivalents as a model tissue. The dermal equivalents were constructed by seeding QD-labeled fibroblasts in type I collagen matrices. After 24 h incubation, the ETs were directionally frozen by exposing them to a spatial temperature gradient (from 4°C to −20°C over a distance of 6 mm). While being frozen, the ETs were consecutively imaged, and consecutive pairs of these images were two-dimensionally cross-correlated to determine the local deformation during freezing. The results showed that freezing induced the deformation of ET, and its magnitude varied with both time and location. The maximum local dilatation was 0.006 s−1 and was always observed at the phase change interface. Due to this local expansion, the unfrozen region in front of the freezing interface experienced compression. This expansion-compression pattern was observed throughout the freezing process. In the unfrozen region, the deformation rate gradually decreased away from the freezing interface. After freezing/thawing, the ET experienced an approximately 28% decrease in thickness and 8% loss in weight. These results indicate that freezing-induced deformation caused the transport of interstitial fluid, and the interstitial fluid was extruded. In summary, the results suggest that complex cell-fluid-matrix interactions occur within ETs during freezing, and these interactions determine the post-thaw ECM microstructure and eventual post-thaw tissue functionality.
©2010 American Society of Mechanical Engineers
| History: | Received 12 August 2009; revised 2 October 2009; accepted manuscript posted 22 December 2009; published 4 February 2010 | |
| doi: | http://dx.doi.org/10.1115/1.4000875 | |
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BibSonomy
KEYWORDS and PACS
biological fluid dynamics,
biological techniques,
biological tissues,
biothermics,
cellular transport,
deformation,
freezing,
melting,
quantum dots,
spatiotemporal phenomena,
tissue engineering
- 87.19.R-
Mechanical and electrical properties of tissues and organs (higher organisms) - 87.64.-t
Spectroscopic and microscopic techniques in biophysics and medical physics - 87.80.Dj
Spectroscopies (biophysical research methods) - 87.19.rh
Fluid transport and rheology in tissues and organs (higher organisms) - 87.19.Pp
Biothermics and thermal processes in biology (higher organisms) - 87.17.-d
Cell processes - YEAR: 2010
