11 research outputs found
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The mechanical properties of amniotic membrane influence its effect as a biomaterial for ocular surface repair
The human amniotic membrane (AM) is a tissue of fetal origin and has proven to be clinically useful as
a biomaterial in the management of various ocular surface disorders including corneal stem cell
transplantation. However, its success rate displays a degree of clinical unpredictability. We suggest that
the measured variability inAMstiffness offers an explanation for the poor clinical reproducibility when
it is used as a substrate for stem cell expansion and transplantation. Corneal epithelial stem cells were
expanded upon AM samples possessing different mechanical stiffness. To investigate further the
importance of biological substrate stiffness on cell phenotype we replaced AM with type I collagen gels
of known stiffness. Substrate stiffness was measured using shear rheometry and surface topography
was characterized using scanning electron microscopy and atomic force microscopy. The
differentiation status of epithelial cells was examined using RT-PCR, immunohistochemistry and
Western blotting. The level of corneal stem cell differentiation was increased in cells expanded upon
AM with a high dynamic elastic shear modulus and cell expansion on type I collagen gels confirmed
that the level of corneal epithelial stem cell differentiation was related to the substrate’s mechanical
properties. In this paper we provide evidence to show that the preparatory method of AM for clinical
use can affect its mechanical properties and that these measured differences can influence the level of
differentiation within expanded corneal epithelial stem cells
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Deconstruction of a Metastatic Tumor Microenvironment Reveals a Common Matrix Response in Human Cancers.
We have profiled, for the first time, an evolving human metastatic microenvironment by measuring gene expression, matrisome proteomics, cytokine and chemokine levels, cellularity, extracellular matrix organization, and biomechanical properties, all on the same sample. Using biopsies of high-grade serous ovarian cancer metastases that ranged from minimal to extensive disease, we show how nonmalignant cell densities and cytokine networks evolve with disease progression. Multivariate integration of the different components allowed us to define, for the first time, gene and protein profiles that predict extent of disease and tissue stiffness, while also revealing the complexity and dynamic nature of matrisome remodeling during development of metastases. Although we studied a single metastatic site from one human malignancy, a pattern of expression of 22 matrisome genes distinguished patients with a shorter overall survival in ovarian and 12 other primary solid cancers, suggesting that there may be a common matrix response to human cancer.Significance: Conducting multilevel analysis with data integration on biopsies with a range of disease involvement identifies important features of the evolving tumor microenvironment. The data suggest that despite the large spectrum of genomic alterations, some human malignancies may have a common and potentially targetable matrix response that influences the course of disease. Cancer Discov; 8(3); 304-19. ©2017 AACR.This article is highlighted in the In This Issue feature, p. 253
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The bioactivity of composite Fmoc-RGDS-collagen gels
The incorporation of small bioactive peptide motifs within robust hydrogels constitutes a facile procedure to chemically functionalise cell and tissue scaffolds. In this study, a novel approach to utilise Fmoc-linked peptide amphiphiles comprising the bio-functional cell-adhesion RGDS motif within biomimetic collagen gels was developed. The composite scaffolds thus created were shown to maintain the mechanical properties of the collagen gel while presenting additional bio-activity. In particular, these materials enhanced the adhesion and proliferation of viable human corneal stromal fibroblasts by 300% compared to nonfunctionalised gels. Furthermore, the incorporation of Fmoc-RGDS nanostructures within the collagen matrix significantly suppressed gel shrinkage resulting from the contractile action of encapsulated fibroblasts once activated by serum proteins. These mechanical and biological properties demonstrate that the incorporation of peptide amphiphiles provides a suitable and easy method to circumvent specific biomaterial limitations, such as cell-derived shrinkage, for improved performance in tissue engineering and regenerative medicine applications
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Photochemical cross-linking of plastically compressed collagen gel produces an optimal scaffold for corneal tissue engineering
The experiments were designed to use photochemically
cross-linked plastically compressed collagen (PCPCC) gel
to support corneal epithelial cells. A plastically compressed collagen (PCC) scaffold was photo cross-linked by UVA in the presence of riboflavin to form a biomaterial with optimal mechanical properties. The breaking force, rheology, surgical suture strength, transparency, ultrastructure, and cell-based biocompatibility were compared between PCPCC and PCC gels. The breaking force increased proportionally with an increased concentration of riboflavin. The stress required to reach breaking point of the PCPCC scaffolds was over two times higher compared to the stress necessary to break PCC scaffolds in the presence of 0.1% riboflavin. Rheology results indicated that the structural properties of PCC remain unaltered after UVA cross-linking. The PCC gels were more easily broken than PCPCC gels when sutured on to bovine corneas. The optical density values of PCPCC and PCC showed no significant
differences (p > 0.05). SEM analyses showed that the
collagen fibres within the PCPCC gels were similar in morphology to PCC gels. No difference in cell-based biocompatibility was seen between the PCPCC and PCC scaffolds in terms of their ability to support the ex vivo expansion of corneal epithelial cells or their subsequent differentiation evidenced by similar levels of cytokeratin 14. In conclusion, PCPCC scaffold is an optimal biomaterial for use in therapeutic tissue engineering of the cornea
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Collagen stimulating effect of peptide amphiphile C16−KTTKS on human fibroblasts
The collagen production of human dermal and corneal fibroblasts in contact with solutions of the peptide amphiphile (PA) C16−KTTKS is investigated and related to its self-assembly into nanotape structures. This PA is used in antiwrinkle cosmeceutical applications (trade name Matrixyl). We prove that C16−KTTKS stimulates collagen production in a concentration-dependent manner close to the critical aggregation concentration determined from pyrene
fluorescence spectroscopy. This suggests that self-assembly and the stimulation of collagen production are inter-related