Surface functionalization of nanobiomaterials for application in stem cell culture, tissue engineering, and regenerative medicine

Rana, Deepti; Ramasamy, Keerthana; Leena, M. Maria; Jiménez, Constanza; Campos, Javier; Ibarra, Paula; Haidar, Ziyad S.; Ramalingam, Murugan

doi:10.1002/btpr.2262

Cited by 43 publications

(17 citation statements)

References 85 publications

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“…A simple physical adsorption method is limited as the cell adhesion molecules might be detached from the surface and results in adverse repercussions on cell adhesion, growth, and differentiation . Moreover, lack of controllability on the orientation of adsorbed cell‐adhesive biomolecules is another drawback that highly decreases the efficiency of this method . Chen et al investigated the effects of physical adsorption and covalent attachment of laminin molecules on the surface of electrospun silica nanofibrous scaffolds (SNF2) .…”

Section: Surface Modification Methodsmentioning

confidence: 71%

Controlling Cell Behavior through the Design of Biomaterial Surfaces: A Focus on Surface Modification Techniques

Amani

Arzaghi

Bayandori

et al. 2019

Adv Materials Inter

285

181

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Surface interaction at the biomaterial–cell interface is essential for a variety of cellular functions, such as adhesion, proliferation, and differentiation. Nevertheless, changes in the biointerface enable to trigger specific cell signaling and result in different cellular responses. In order to manufacture biomaterials with higher functionality, biomaterials containing immobilized bioactive ligands have been widely introduced and employed for tissue engineering and regenerative medicine applications. Moreover, a number of physical and chemical strategies have been used to improve the functionality of biomaterials and specifically at the material interface. Here, the interactions between materials and cells at the interface levels are described. Then, the importance of surface properties in cell function is discussed and recent methods for surface modifications are systematically highlighted. Additionally, the impact of bulk material properties on the cellular responses is briefly reviewed.

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Section: Surface Modification Methodsmentioning

confidence: 71%

Controlling Cell Behavior through the Design of Biomaterial Surfaces: A Focus on Surface Modification Techniques

Amani

Arzaghi

Bayandori

et al. 2019

Adv Materials Inter

285

181

View full text Add to dashboard Cite

show abstract

“…Our results are in good agreement with other studies indicating that the chemical and mechanical unfolding of proteins can lead to very different denaturation states [ 44 , 45 ]. Modifying culture substrates with extracellular matrix proteins to direct stem cell migration and differentiation is a vibrant field of research [ 46 ], mainly due to the fact that we still lack ways to control the orientation, conformation, and denaturation states of adsorbed proteins [ 47 ]. Using these results, we could design specific culture surfaces either to promote mES cell self-renewal to provide sufficient numbers of cells to be therapeutically relevant, or to drive differentiation of the cells for a specific application.…”

Section: Discussionmentioning

confidence: 99%

The Role of Controlled Surface Topography and Chemistry on Mouse Embryonic Stem Cell Attachment, Growth and Self-Renewal

et al. 2017

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Abstract:The success of stem cell therapies relies heavily on our ability to control their fate in vitro during expansion to ensure an appropriate supply. The biophysical properties of the cell culture environment have been recognised as a potent stimuli influencing cellular behaviour. In this work we used advanced plasma-based techniques to generate model culture substrates with controlled nanotopographical features of 16 nm, 38 nm and 68 nm in magnitude, and three differently tailored surface chemical functionalities. The effect of these two surface properties on the adhesion, spreading, and self-renewal of mouse embryonic stem cells (mESCs) were assessed. The results demonstrated that physical and chemical cues influenced the behaviour of these stem cells in in vitro culture in different ways. The size of the nanotopographical features impacted on the cell adhesion, spreading and proliferation, while the chemistry influenced the cell self-renewal and differentiation.

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“…Many authors have chosen to functionalize the electrospun scaffolds and modify their surfaces by blending the polymer solution with bioactive molecules prior to electrospinning [ 19 , 31 , 32 , 33 , 34 ]. Others have used a wet chemistry surface modification approach to functionalize electrospun scaffolds by immersing them into harsh chemicals such as strong acids or alkalis [ 35 , 36 , 37 , 38 , 39 , 40 ] in which hydroxyl or carboxyl groups are formed by hydrolyses of ester bonds. Although this treatment has shown to improve hydrophilic properties of the scaffolds with an improvement in cell adhesion and spreading [ 35 , 37 , 38 , 39 , 40 ], treated materials exhibited a strong shrinkage and the fibers lost their alignment with a decrease in the Young’s modulus properties by using a high NaOH concentration [ 38 ].…”

Section: Introductionmentioning

confidence: 99%

Fabrication and Plasma Surface Activation of Aligned Electrospun PLGA Fiber Fleeces with Improved Adhesion and Infiltration of Amniotic Epithelial Stem Cells Maintaining their Teno-inductive Potential

et al. 2020

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Electrospun PLGA microfibers with adequate intrinsic physical features (fiber alignment and diameter) have been shown to boost teno-differentiation and may represent a promising solution for tendon tissue engineering. However, the hydrophobic properties of PLGA may be adjusted through specific treatments to improve cell biodisponibility. In this study, electrospun PLGA with highly aligned microfibers were cold atmospheric plasma (CAP)-treated by varying the treatment exposure time (30, 60, and 90 s) and the working distance (1.3 and 1.7 cm) and characterized by their physicochemical, mechanical and bioactive properties on ovine amniotic epithelial cells (oAECs). CAP improved the hydrophilic properties of the treated materials due to the incorporation of new oxygen polar functionalities on the microfibers’ surface especially when increasing treatment exposure time and lowering working distance. The mechanical properties, though, were affected by the treatment exposure time where the optimum performance was obtained after 60 s. Furthermore, CAP treatment did not alter oAECs’ biocompatibility and improved cell adhesion and infiltration onto the microfibers especially those treated from a distance of 1.3 cm. Moreover, teno-inductive potential of highly aligned PLGA electrospun microfibers was maintained. Indeed, cells cultured onto the untreated and CAP treated microfibers differentiated towards the tenogenic lineage expressing tenomodulin, a mature tendon marker, in their cytoplasm. In conclusion, CAP treatment on PLGA microfibers conducted at 1.3 cm working distance represent the optimum conditions to activate PLGA surface by improving their hydrophilicity and cell bio-responsiveness. Since for tendon tissue engineering purposes, both high cell adhesion and mechanical parameters are crucial, PLGA treated for 60 s at 1.3 cm was identified as the optimal construct.

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Surface functionalization of nanobiomaterials for application in stem cell culture, tissue engineering, and regenerative medicine

Cited by 43 publications

References 85 publications

Controlling Cell Behavior through the Design of Biomaterial Surfaces: A Focus on Surface Modification Techniques

Controlling Cell Behavior through the Design of Biomaterial Surfaces: A Focus on Surface Modification Techniques

The Role of Controlled Surface Topography and Chemistry on Mouse Embryonic Stem Cell Attachment, Growth and Self-Renewal

Fabrication and Plasma Surface Activation of Aligned Electrospun PLGA Fiber Fleeces with Improved Adhesion and Infiltration of Amniotic Epithelial Stem Cells Maintaining their Teno-inductive Potential

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