Your search keyword '"Neural regeneration"' showing total 7 results

1. Calming the Nerves via the Immune Instructive Physiochemical Properties of Self‐Assembling Peptide Hydrogels.

Author

Mahmoudi, Negar, Mohamed, Elmira, Dehnavi, Shiva Soltani, Aguilar, Lilith M. Caballero, Harvey, Alan R., Parish, Clare L., Williams, Richard J., and Nisbet, David R.

Subjects

*PEPTIDES, *HYDROGELS, *BRAIN injuries, *DRUG efficacy, *NERVES, *BIOMATERIALS

Abstract

Current therapies for the devastating damage caused by traumatic brain injuries (TBI) are limited. This is in part due to poor drug efficacy to modulate neuroinflammation, angiogenesis and/or promoting neuroprotection and is the combined result of challenges in getting drugs across the blood brain barrier, in a targeted approach. The negative impact of the injured extracellular matrix (ECM) has been identified as a factor in restricting post‐injury plasticity of residual neurons and is shown to reduce the functional integration of grafted cells. Therefore, new strategies are needed to manipulate the extracellular environment at the subacute phase to enhance brain regeneration. In this review, potential strategies are to be discussed for the treatment of TBI by using self‐assembling peptide (SAP) hydrogels, fabricated via the rational design of supramolecular peptide scaffolds, as an artificial ECM which under the appropriate conditions yields a supramolecular hydrogel. Sequence selection of the peptides allows the tuning of these hydrogels' physical and biochemical properties such as charge, hydrophobicity, cell adhesiveness, stiffness, factor presentation, degradation profile and responsiveness to (external) stimuli. This review aims to facilitate the development of more intelligent biomaterials in the future to satisfy the parameters, requirements, and opportunities for the effective treatment of TBI. [ABSTRACT FROM AUTHOR]

Published

2024

2. Calming the Nerves via the Immune Instructive Physiochemical Properties of Self‐Assembling Peptide Hydrogels

Author

Negar Mahmoudi, Elmira Mohamed, Shiva Soltani Dehnavi, Lilith M. Caballero Aguilar, Alan R. Harvey, Clare L. Parish, Richard J. Williams, and David R. Nisbet

Subjects

bioactive scaffolds, foreign body reaction, neural regeneration, self‐assembling peptide‐based hydrogels, tissue engineering, Science

Abstract

Abstract Current therapies for the devastating damage caused by traumatic brain injuries (TBI) are limited. This is in part due to poor drug efficacy to modulate neuroinflammation, angiogenesis and/or promoting neuroprotection and is the combined result of challenges in getting drugs across the blood brain barrier, in a targeted approach. The negative impact of the injured extracellular matrix (ECM) has been identified as a factor in restricting post‐injury plasticity of residual neurons and is shown to reduce the functional integration of grafted cells. Therefore, new strategies are needed to manipulate the extracellular environment at the subacute phase to enhance brain regeneration. In this review, potential strategies are to be discussed for the treatment of TBI by using self‐assembling peptide (SAP) hydrogels, fabricated via the rational design of supramolecular peptide scaffolds, as an artificial ECM which under the appropriate conditions yields a supramolecular hydrogel. Sequence selection of the peptides allows the tuning of these hydrogels' physical and biochemical properties such as charge, hydrophobicity, cell adhesiveness, stiffness, factor presentation, degradation profile and responsiveness to (external) stimuli. This review aims to facilitate the development of more intelligent biomaterials in the future to satisfy the parameters, requirements, and opportunities for the effective treatment of TBI.

Published

2024

3. 4D Self‐Morphing Culture Substrate for Modulating Cell Differentiation

Author

Shida Miao, Haitao Cui, Timothy Esworthy, Bhushan Mahadik, Se‐jun Lee, Xuan Zhou, Sung Yun Hann, John P. Fisher, and Lijie Grace Zhang

Subjects

4D culture substrates, cell differentiation, neural regeneration, programmable culture substrates, regenerative medicine, stem cells, Science

Abstract

Abstract As the most versatile and promising cell source, stem cells have been studied in regenerative medicine for two decades. Currently available culturing techniques utilize a 2D or 3D microenvironment for supporting the growth and proliferation of stem cells. However, these culture systems fail to fully reflect the supportive biological environment in which stem cells reside in vivo, which contain dynamic biophysical growth cues. Herein, a 4D programmable culture substrate with a self‐morphing capability is presented as a means to enhance dynamic cell growth and induce differentiation of stem cells. To function as a model system, a 4D neural culture substrate is fabricated using a combination of printing and imprinting techniques keyed to the different biological features of neural stem cells (NSCs) at different differentiation stages. Results show the 4D culture substrate demonstrates a time‐dependent self‐morphing process that plays an essential role in regulating NSC behaviors in a spatiotemporal manner and enhances neural differentiation of NSCs along with significant axonal alignment. This study of a customized, dynamic substrate revolutionizes current stem cell therapies, and can further have a far‐reaching impact on improving tissue regeneration and mimicking specific disease progression, as well as other impacts on materials and life science research.

Published

2020

4. 4D Self‐Morphing Culture Substrate for Modulating Cell Differentiation.

Author

Miao, Shida, Cui, Haitao, Esworthy, Timothy, Mahadik, Bhushan, Lee, Se‐jun, Zhou, Xuan, Hann, Sung Yun, Fisher, John P., and Zhang, Lijie Grace

Subjects

*CELL differentiation, *NEURAL stem cells, *STEM cells, *REGENERATIVE medicine, *STEM cell treatment

Abstract

As the most versatile and promising cell source, stem cells have been studied in regenerative medicine for two decades. Currently available culturing techniques utilize a 2D or 3D microenvironment for supporting the growth and proliferation of stem cells. However, these culture systems fail to fully reflect the supportive biological environment in which stem cells reside in vivo, which contain dynamic biophysical growth cues. Herein, a 4D programmable culture substrate with a self‐morphing capability is presented as a means to enhance dynamic cell growth and induce differentiation of stem cells. To function as a model system, a 4D neural culture substrate is fabricated using a combination of printing and imprinting techniques keyed to the different biological features of neural stem cells (NSCs) at different differentiation stages. Results show the 4D culture substrate demonstrates a time‐dependent self‐morphing process that plays an essential role in regulating NSC behaviors in a spatiotemporal manner and enhances neural differentiation of NSCs along with significant axonal alignment. This study of a customized, dynamic substrate revolutionizes current stem cell therapies, and can further have a far‐reaching impact on improving tissue regeneration and mimicking specific disease progression, as well as other impacts on materials and life science research. [ABSTRACT FROM AUTHOR]

Published

2020

5. Programmable Culture Substrates: 4D Self‐Morphing Culture Substrate for Modulating Cell Differentiation (Adv. Sci. 5/2020)

Author

Sung Yun Hann, Shida Miao, Haitao Cui, Xuan Zhou, Se-Jun Lee, John P. Fisher, Bhushan Mahadik, Lijie Grace Zhang, and Timothy Esworthy

Subjects

Chemistry, General Chemical Engineering, Cellular differentiation, Inside Back Cover, General Engineering, General Physics and Astronomy, Medicine (miscellaneous), regenerative medicine, Substrate (printing), programmable culture substrates, Biochemistry, Genetics and Molecular Biology (miscellaneous), Regenerative medicine, Morphing, cell differentiation, stem cells, Biophysics, General Materials Science, Stem cell, 4D culture substrates, Neural regeneration, neural regeneration

Abstract

In article number https://doi.org/10.1002/advs.201902403, Lijie Grace Zhang and co‐workers develop a 4D culture substrate with a time‐dependent topographic transformation to replicate the dynamic process of neural development. The advances in the regulation of the stem cell behaviors with spatiotemporal controllability are essential in developing dynamic biological tissue systems and have a far‐reaching impact on materials and life science research.

Published

2020

6. 4D Self‐Morphing Culture Substrate for Modulating Cell Differentiation

Author

Xuan Zhou, John P. Fisher, Haitao Cui, Shida Miao, Se-Jun Lee, Lijie Grace Zhang, Bhushan Mahadik, Timothy Esworthy, and Sung Yun Hann

Subjects

General Chemical Engineering, Cellular differentiation, Cell, regenerative medicine, General Physics and Astronomy, Medicine (miscellaneous), Model system, 02 engineering and technology, Biology, 010402 general chemistry, 01 natural sciences, Biochemistry, Genetics and Molecular Biology (miscellaneous), Regenerative medicine, stem cells, medicine, General Materials Science, 4D culture substrates, lcsh:Science, Full Paper, Cell growth, General Engineering, programmable culture substrates, Full Papers, 021001 nanoscience & nanotechnology, Neural stem cell, 3. Good health, 0104 chemical sciences, Cell biology, cell differentiation, medicine.anatomical_structure, lcsh:Q, Neural differentiation, Stem cell, neural regeneration, 0210 nano-technology

Abstract

As the most versatile and promising cell source, stem cells have been studied in regenerative medicine for two decades. Currently available culturing techniques utilize a 2D or 3D microenvironment for supporting the growth and proliferation of stem cells. However, these culture systems fail to fully reflect the supportive biological environment in which stem cells reside in vivo, which contain dynamic biophysical growth cues. Herein, a 4D programmable culture substrate with a self‐morphing capability is presented as a means to enhance dynamic cell growth and induce differentiation of stem cells. To function as a model system, a 4D neural culture substrate is fabricated using a combination of printing and imprinting techniques keyed to the different biological features of neural stem cells (NSCs) at different differentiation stages. Results show the 4D culture substrate demonstrates a time‐dependent self‐morphing process that plays an essential role in regulating NSC behaviors in a spatiotemporal manner and enhances neural differentiation of NSCs along with significant axonal alignment. This study of a customized, dynamic substrate revolutionizes current stem cell therapies, and can further have a far‐reaching impact on improving tissue regeneration and mimicking specific disease progression, as well as other impacts on materials and life science research., A 4D programmable culture substrate with self‐morphing ability is presented to enhance dynamic growth and induce differentiation of stem cells. The result indicates the great potential of 4D culture substrates to serve as a new generation of commercially available scaffolds and devices that can be used to manipulate cell functions and fates.

Published

2020

7. Programmable Culture Substrates: 4D Self‐Morphing Culture Substrate for Modulating Cell Differentiation (Adv. Sci. 5/2020).

Author

Miao, Shida, Cui, Haitao, Esworthy, Timothy, Mahadik, Bhushan, Lee, Se‐jun, Zhou, Xuan, Hann, Sung Yun, Fisher, John P., and Zhang, Lijie Grace

Subjects

*CELL differentiation, *NERVOUS system regeneration, *BIOLOGICAL systems, *REGENERATIVE medicine, *CULTURE

Published

2020