Development of a
                    <i>nerve stretcher</i>
                    for
                    <i>in vivo</i>
                    stretching of nerve fibres

A deeper understanding of the brain and its function remains one of the most significant scientific challenges. It not only is required to find cures for a plethora of brain-related diseases and injuries but also opens up possibilities for achieving technological wonders, such as brain–machine interface and highly energy-efficient computing devices. Central to the brain's function is its basic functioning unit (i.e., the neuron). There has been a tremendous effort to understand the underlying mechanisms of neuronal growth on both biochemical and biophysical levels. In the past decade, this increased understanding has led to the possibility of controlling and modulating neuronal growth in vitro through external chemical and physical methods. We provide a detailed overview of the most fundamental aspects of neuronal growth and discuss how researchers are using interdisciplinary ideas to engineer neuronal networks in vitro. We first discuss the biochemical and biophysical mechanisms of neuronal growth as we stress the fact that the biochemical or biophysical processes during neuronal growth are not independent of each other but, rather, are complementary. Next, we discuss how utilizing these fundamental mechanisms can enable control over neuronal growth for advanced neuroengineering and biomedical applications. At the end of this review, we discuss some of the open questions and our perspectives on the challenges and possibilities related to controlling and engineering the growth of neuronal networks, specifically in relation to the materials, substrates, model systems, modulation techniques, data science, and artificial intelligence.

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“…Most recently, Sahar and colleagues have proposed devices that can mimic this axon stretch growth in vivo . 201,202 …”

Section: Neuronal Growth Control Using External Cuesmentioning

confidence: 99%

Understanding, engineering, and modulating the growth of neural networks: An interdisciplinary approach

2021

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“…Negative pressure was applied to the nerve ends continuously for 7 days and set to the respective group pressure value. 40 Postoperatively, the rats recovered in their cages. The rats were closely monitored after the procedure for any adverse effects.…”

Section: Postoperative Carementioning

confidence: 99%

Negative Pressure Neurogenesis: A Novel Approach to Accelerate Nerve Regeneration after Complete Peripheral Nerve Transection

Mettyas

Barton

Sahar

et al. 2021

Plastic and Reconstructive Surgery - Global Open

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Background: Various modalities to facilitate nerve regeneration have been described in the literature with limited success. We hypothesized that negative pressure applied to a sectioned peripheral nerve would enhance nerve regeneration by promoting angiogenesis and axonal lengthening. Methods: Wistar rats’ sciatic nerves were cut (creating ~7 mm nerve gap) and placed into a silicone T-tube, to which negative pressure was applied. The rats were divided into 4 groups: control (no pressure), group A (low pressure: 10 mm Hg), group B (medium pressure: 20/30 mm Hg) and group C (high pressure: 50/70 mm Hg). The nerve segments were retrieved after 7 days for gross and histological analysis. Results: In total, 22 rats completed the study. The control group showed insignificant nerve growth, whereas the 3 negative pressure groups showed nerve growth and nerve gap reduction. The true nerve growth was highest in group A (median: 3.54 mm) compared to group B, C, and control (medians: 1.19 mm, 1.3 mm, and 0.35 mm); however, only group A was found to be significantly different to the control group (** P < 0.01). Similarly, angiogenesis was observed to be significantly greater in group A (** P < 0.01) in comparison to the control. Conclusions: Negative pressure stimulated nerve lengthening and angiogenesis within an in vivo rat model. Low negative pressure (10 mm Hg) provided superior results over the higher negative pressure groups and the control, favoring axonal growth. Further studies are required with greater number of rats and longer recovery time to assess the functional outcome.

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Histological, immunohistochemical, and morphometric analysis of negative pressure-assisted in-vivo nerve stretch-growth

Sahar

Mettyas

Shah

et al. 2022

Neuroscience Letters

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Development of a nerve stretcher for in vivo stretching of nerve fibres

Cited by 5 publications

References 15 publications

Understanding, engineering, and modulating the growth of neural networks: An interdisciplinary approach

Understanding, engineering, and modulating the growth of neural networks: An interdisciplinary approach

Negative Pressure Neurogenesis: A Novel Approach to Accelerate Nerve Regeneration after Complete Peripheral Nerve Transection

Histological, immunohistochemical, and morphometric analysis of negative pressure-assisted in-vivo nerve stretch-growth

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