Time dependency of morphological remodeling of endothelial cells in response to substrate stiffness

Goli-Malekabadi, Zahra; Tafazzoli-Shadpour, Mohammad; Tamayol, Ali; Seyedjafari, Ehsan

doi:10.15171/bi.2017.06

Cited by 14 publications

(9 citation statements)

References 35 publications

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“…The cell resistance of the PCUL1‐PO samples, regardless of the VEGF surface density [Figure (A)], could be assigned to the low stiffness of the bulk material that possessed the lowest hard segment content (29.6%) among the three PCUL x ‐PO materials ( x = 1, 2, and 3, Table ). Previous studies have demonstrated that soft materials inhibit EC adhesion and proliferation, and grafting with growth factors cannot change the stiffness‐dependent manner of endothelial function . Both PCUL2‐PO and PCUL3‐PO possessed similar hard segment contents (39.7% vs. 38.9%, Table ), but the latter possessed much more PEG content (11.2% vs. 31.1%, Table ).…”

Section: Discussionmentioning

confidence: 95%

Toward endothelialization via vascular endothelial growth factor immobilization on cell‐repelling functional polyurethanes

Liao

Yang

et al. 2018

J Biomed Mater Res

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We screened a family of nonspecific cell-repelling polyurethanes (PUs) whose backbones are attached with epoxy group-terminated polyethylene glycol (PEG) side chains. Water incubation of the PU films (with 9.2-31.1 wt % PEG) caused a surface enrichment of PEG chains where vascular endothelial growth factor (VEGF) was grafted by forming secondary amine linkages between VEGF molecules and the PEG spacer. These linkages are still ionizable similar to original primary amines in VEGF, thereby retaining the original charge distribution on VEGF macromolecules. This charge conservation together with PEG steric repulsion helped to preserve VEGF conformation and bioactivity. The PU substrates with suitable hard segments contents and VEGF surface densities can selectively induce endothelial cells (ECs) adhesion and proliferation toward endothelialization. Moreover, the PU substrates, even grafted with fibrinogen (Fg), cannot trigger platelet adhesion and deformation, suggesting an inactive conformation of the grafted Fg. Thus enough antithrombogenicity of the PU substrates could be expected before full endothelialization. These PU materials might be applied onto the lumens of vascular grafts, potentially stimulating luminal endothelialization in vivo.

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Section: Discussionmentioning

confidence: 95%

Toward endothelialization via vascular endothelial growth factor immobilization on cell‐repelling functional polyurethanes

Liao

Yang

et al. 2018

J Biomed Mater Res

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“…However, it is important to note that the ECs were co-cultured with a lung cancer cell line, so the observed process may deviate from angiogenesis in healthy tissue. Another study found enhanced anchorage and cell survival of HUVECs on stiffer PDMS substrates with a Young’s modulus of 2000 kPa compared with soft surfaces with a Young’s modulus of 50 kPa [ 238 ]. They stated that the improved anchorage through enrichment of lamellipodia and filopodia in the initial hours of culture possibly contributes to a better cell adherence and spreading which, in turn, induces enhanced cell viability on the long term [ 238 ].…”

Section: Biological Response To Biomaterialsmentioning

confidence: 99%

In vitroangiogenesis in response to biomaterial properties for bone tissue engineering: a review of the state of the art

Ellermann

Meyer

Cameron

et al. 2023

Regenerative Biomaterials

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Bone tissue engineering (BTE) aims to improve the healing of bone fractures using scaffolds that mimic the native extracellular matrix. For successful bone regeneration, scaffolds should promote simultaneous bone tissue formation and blood vessel growth for nutrient and waste exchange. However, a significant challenge in regenerative medicine remains the development of grafts that can be vascularised successfully. Amongst other things, optimisation of physicochemical conditions of scaffolds is key to achieving appropriate angiogenesis in the period immediately following implantation. Calcium phosphates and collagen scaffolds are two of the most widely studied biomaterials for BTE, due to their close resemblance to inorganic and organic components of bone, respectively, and their bioactivity, tunable biodegradability and the ability to produce tailored architectures. While various strategies exist to enhance vascularisation of these scaffolds in vivo, further in vitro assessment is crucial to understand the relation between physicochemical properties of a biomaterial and its ability to induce angiogenesis. While mono-culture culture studies can provide evidence regarding cell-material interaction of a single cell type, a co-culture procedure is crucial for assessing the complex mechanisms involved in angiogenesis. A co-culture more closely resembles the natural tissue both physically and biologically by stimulating natural intercellular interactions and mimicking the organisation of the in vivo environment. Nevertheless, a co-culture is a complex system requiring optimisation of various parameters including cell types, cell ratio, culture medium and seeding logistics. Gaining fundamental knowledge of the mechanism behind the bioactivity of biomaterials and understanding the contribution of surface and architectural features to the vascularisation of scaffolds, and the biological response in general, can provide an invaluable basis for future optimisation studies. This review gives an overview of the available literature on scaffolds for BTE, and trends are extracted on the relationship between architectural features, biochemical properties, co-culture parameters and angiogenesis.

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“…Gorgani et al also showed that pre‐PGS/PLLA scaffold had a non‐toxicity behavior. This could be due to the scaffold's high hydrophilic characteristics and sufficient elastic modulus, creating a more favorable environment for cell adhesion, which resulted in efficient cell adaptation 98,99 . Consequently, the cells adhered successfully to the scaffold progressed through the proliferative phase and produced colonies that allowed the cells to proliferate and multiply properly.…”

Section: Processing Parameters Of Pgs Electrospun Scaffolds: Blend Sy...mentioning

confidence: 99%

Shape memory poly (glycerol sebacate)‐based electrospun fiber scaffolds for tissue engineering applications: A review

Zulkifli

Tan

Ishak

et al. 2022

J of Applied Polymer Sci

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Electrospun fiber scaffolds has made a huge progress in tissue engineering applications owing to their continuous morphology with variable chemical, physical, and biological properties. In this review paper, we reviewed the electrospinning technique, its processing parameters and characterizations involved. A focus on shape memory poly (glycerol sebacate) (PGS)-based electrospun fiber scaffolds for tissue engineering field was explored. The stimuli responsive PGS scaffold has gained much attention due to its ability to self-expanding, self-deploying, or self-fitting. Herein, the electrospinning of shape memory PGS-based scaffolds, particularly their processing parameters, properties, and characterizations have been reviewed. Besides, other issues concerning the technology constraints, challenges, and future directions are also discussed.

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Time dependency of morphological remodeling of endothelial cells in response to substrate stiffness

Cited by 14 publications

References 35 publications

Toward endothelialization via vascular endothelial growth factor immobilization on cell‐repelling functional polyurethanes

Toward endothelialization via vascular endothelial growth factor immobilization on cell‐repelling functional polyurethanes

In vitroangiogenesis in response to biomaterial properties for bone tissue engineering: a review of the state of the art

Shape memory poly (glycerol sebacate)‐based electrospun fiber scaffolds for tissue engineering applications: A review

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