Bionic microenvironment-inspired synergistic effect of anisotropic micro-nanocomposite topology and biology cues on peripheral nerve regeneration

Li, Guicai; Zheng, Tiantian; Wu, Linliang; Han, Qi; Lei, Yifeng; Xue, Longjian; Zhang, Luzhong; Gu, Xiaosong; Yang, Yumin

doi:10.1126/sciadv.abi5812

Cited by 49 publications

(41 citation statements)

References 45 publications

(47 reference statements)

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“…As the gold standard, the application of nerve transplantation therapy is limited because of the shortage of donor nerves and the functional damage of donor nerve target organs. In this context, the strategy of using tissue engineering to repair PNI has gradually attracted the attention of researchers [ 77 , 78 , 79 ]. Several studies have proven that CHs have great advantages in repairing PNI.…”

Section: Challenges and Futuresmentioning

confidence: 99%

Application of Hybrid Electrically Conductive Hydrogels Promotes Peripheral Nerve Regeneration

Zhang

Liu

et al. 2022

Gels

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Peripheral nerve injury (PNI) occurs frequently, and the prognosis is unsatisfactory. As the gold standard of treatment, autologous nerve grafting has several disadvantages, such as lack of donors and complications. The use of functional biomaterials to simulate the natural microenvironment of the nervous system and the combination of different biomaterials are considered to be encouraging alternative methods for effective tissue regeneration and functional restoration of injured nerves. Considering the inherent presence of an electric field in the nervous system, electrically conductive biomaterials have been used to promote nerve regeneration. Due to their singular physical properties, hydrogels can provide a three-dimensional hydrated network that can be integrated into diverse sizes and shapes and stimulate the natural functions of nerve tissue. Therefore, conductive hydrogels have become the most effective biological material to simulate human nervous tissue’s biological and electrical characteristics. The principal merits of conductive hydrogels include their physical properties and their electrical peculiarities sufficient to effectively transmit electrical signals to cells. This review summarizes the recent applications of conductive hydrogels to enhance peripheral nerve regeneration.

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Section: Challenges and Futuresmentioning

confidence: 99%

Application of Hybrid Electrically Conductive Hydrogels Promotes Peripheral Nerve Regeneration

Zhang

Liu

et al. 2022

Gels

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“…This is a key feature of in vivo biology, connected with changes in gene expression ( Tajik et al, 2016 ) and behaviour ( Liverani et al, 2019 ), whose study in the lab has been enabled by 3D cell cultures. As an example, in vivo -like cell alignment, induced by the surrogate ECM features, was shown to result in improved tissue regeneration and repair ( Lu et al, 2021 ; Li et al, 2021a ). While a comprehensive analysis of cell–cell and cell-environment interactions is beyond the scope of this review, the interested reader is referred to Delle Cave et al (2021) and Bechtel et al (2021) for more information.…”

Section: Matrix Interactionmentioning

confidence: 99%

Non-destructive monitoring of 3D cell cultures: new technologies and applications

Cortesi

Giordano

2022

PeerJ

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3D cell cultures are becoming the new standard for cell-based in vitro research, due to their higher transferrability toward in vivo biology. The lack of established techniques for the non-destructive quantification of relevant variables, however, constitutes a major barrier to the adoption of these technologies, as it increases the resources needed for the experimentation and reduces its accuracy. In this review, we aim at addressing this limitation by providing an overview of different non-destructive approaches for the evaluation of biological features commonly quantified in a number of studies and applications. In this regard, we will cover cell viability, gene expression, population distribution, cell morphology and interactions between the cells and the environment. This analysis is expected to promote the use of the showcased technologies, together with the further development of these and other monitoring methods for 3D cell cultures. Overall, an extensive technology shift is required, in order for monolayer cultures to be superseded, but the potential benefit derived from an increased accuracy of in vitro studies, justifies the effort and the investment.

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“…28,29 Specifically, the microgrooved surface structure has been reported to facilitate the cell growth and development of SCs and achieve aligned axon growth, which reduces the wrong target reinnervation. 30,31 Athough RGD peprtides as biological signals or anisotropic topography as a key physical factor to provide guidence cues has been explored for directing axon regeneration and nerve repair indepently, the desirable repair of large-gap peripheral nerve injuries with functional recovery still remains a great challenge. Therefore, it is necessary to develop bioengineered NGCs with therapeutic multicues to achieve improved peripheral nerve regeneration.…”

mentioning

confidence: 99%

“…Accordingly, the expression of Ncam was significantly lower in SCs on SFRGD hydrogels, indicating that the SFRGD hydrogel holds stronger capacity on promoting myelination of SCs because the RGD can enhance the adhesion and myelinogenic capability of SCs via interactions with α5β1 integrins to create appropriate cell adhesion sites on the surface of the scaffolds, which can further initiate myelination-associated intracellular signaling cascades such as the TGF-β pathway. 19,30 Meanwhile, for T30 hydrogels, the expressions of both Pmp22 and Krox20 were also significantly higher, indicating that hydrogels with grooved micropatterns can not only direct cell growth of SCs but also promisingly promote the myelination process of SCs for axon regeneration (Figure 4f). Dorsal root ganglion (DRG) as a sensory neuron plays a key role in the recovery of neurosensory function, which exists in both the peripheral nervous system and the central nervous system.…”

mentioning

confidence: 99%

“…Based on superior spatial and temporal precision of light, the phototriggered gelation system has been regarded as a powerful tool for introducing biochemical signals to scaffolds in a noninvasive and highly controllable manner for directing cell fate. − Significantly, due to the high efficiency of rapid photochemistry upon simple irradiation, photo-cross-linking reactions provide a multifunctional strategy not only to incorporate biomolecules but also to spatially create robust physical microenvironments within biomaterials, such as surface topographic structure and stiffening and softening regions. , Currently, introducing anisotropic topography, a key physical factor of biomedical materials has shown success in promoting axon regeneration. , Specifically, the microgrooved surface structure has been reported to facilitate the cell growth and development of SCs and achieve aligned axon growth, which reduces the wrong target reinnervation. , …”

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confidence: 99%

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Anisotropic Silk-Inspired Nerve Conduit with Peptides Improved the Microenvironment for Long-Distance Peripheral Nerve Regeneration

Tang

Huang

et al. 2021

ACS Macro Lett.

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A lack of effective bioactivity to create a desirable microenvironment for peripheral nerve regeneration has been challenging in successful treatment of long-distance injuries using nerve guidance conduits (NGCs) clinically. Herein, we developed a silk-inspired phototriggered gelation system combining dual therapeutic cues of anisotropic topography and adhesive ligands for improving peripheral nerve regeneration. Importantly, enhanced cell recruitment and myelination of Schwann cells were successfully achieved by the Arg-Gly-Asp (RGD)-peptide-immobilized hydrogel scaffolds to promote axon growth. Moreover, as the orientated growth of Schwann cells and rapid axon growth were facilitated by aligned grooved micropatterns, this multifunctional bioactive system provides remarkable nerve regeneration with function recovery for long-distance nerve injury. Therefore, this bioengineered silk-inspired nerve guidance conduit delivers a platform for desirable peripheral nerve repair.

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Bionic microenvironment-inspired synergistic effect of anisotropic micro-nanocomposite topology and biology cues on peripheral nerve regeneration

Cited by 49 publications

References 45 publications

Application of Hybrid Electrically Conductive Hydrogels Promotes Peripheral Nerve Regeneration

Application of Hybrid Electrically Conductive Hydrogels Promotes Peripheral Nerve Regeneration

Non-destructive monitoring of 3D cell cultures: new technologies and applications

Anisotropic Silk-Inspired Nerve Conduit with Peptides Improved the Microenvironment for Long-Distance Peripheral Nerve Regeneration

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