Nicole Diamantides
Cornell University
8 Papers
1 Citations
Nicole Diamantides is an academic researcher from Cornell University. The author has contributed to research in topics: Chemistry & Chondrocyte. The author has an hindex of 4, co-authored 6 publications. Previous affiliations of Nicole Diamantides include Bucknell University.
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Papers
Correlating rheological properties and printability of collagen bioinks: the effects of riboflavin photocrosslinking and pH
Nicole Diamantides,Louis Wang,Tylar Pruiksma,Joseph Siemiatkoski,Caroline Dugopolski,Sonya Shortkroff,Stephen Kennedy,Lawrence J. Bonassar +7 more
TL;DR: Correlations between rheological parameters and printability showed that the modulus associated with the bioink immediately after extrusion and before deposition was the best predictor of bioink printability.
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High density cell seeding affects the rheology and printability of collagen bioinks
TL;DR: Overall, this study shows that collagen bioinks are conducive to bioprinting with a wide range of cell densities while maintaining high printability and chondrocyte viability and function.
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Multiscale mechanics of tissue-engineered cartilage grown from human chondrocytes and human-induced pluripotent stem cells.
Jill M. Middendorf,Nicole Diamantides,Sonya Shortkroff,Caroline Dugopolski,Stephen Kennedy,Itai Cohen,Lawrence J. Bonassar +6 more
TL;DR: A comparison of multiple mechanical properties of Ch-iPSC and chondrocyte constructs shows that using Ch- iPSCs can produce equivalent or better global mechanical properties to chondROcytes, therefore, iPSC seeded cartilage constructs could be a promising solution to repair focal cartilage defects.
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The Role of Buckling Instabilities in the Global and Local Mechanical Response in Porous Collagen Scaffolds
B. Kim,Jill M. Middendorf,Nicole Diamantides,Caroline Dugopolski,Stephen Kennedy,Eric Blahut,Itai Cohen,Nikolaos Bouklas,Lawrence J. Bonassar +8 more
TL;DR: Differences in mechanical response between scaffold architectures were detected primarily at the micro-scale which stems from the disparity in pore architecture, and tools like confocal strain mapping combined with DIC are critical for designing and optimizing architectures for porous materials.
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Pre‐glycation impairs gelation of high concentration collagen solutions
TL;DR: In this article , the effects of pre-glycation with high sugar concentrations and extended glycation times (up to 21 days) on high concentration collagen (8 mg/ml) were quantified.
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