Painful Terminal Neuroma Prevention by Capping PRGD/PDLLA Conduit in Rat Sciatic Nerves

Yi, Jing; Jiang, Nan; Li, Binbin; Yan, Qiongjiao; Qiu, Tong; Iyer, Kartik K.; Yin, Yi; Dai, Hongyue; Yetisen, Ali K.; Li, Shipu

doi:10.1002/advs.201700876

Cited by 30 publications

(33 citation statements)

References 61 publications

(90 reference statements)

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“…As technology improves, our understanding of the relationship between nerve regeneration and clinically symptomatic neuromas will guide treatment into the near future. The latest technologies include electrospun aligned nanofiber conduits modified with biocompatible peptides to provide a suitable microenvironment to prevent neuroma formation [15]. Our analysis of a bioresorbable polycaprolactone cap is the first in a human model.…”

Section: Resultsmentioning

confidence: 99%

Analysis of an End Neuroma 6 Months after Capping with a Bioresorbable Polycaprolactone Cap (NEUROCAP®) in a Human Model

Power¹,

George²,

Pohl³

2020

SCR

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Various methods have been described in the literature for the treatment of painful end neuromas. One technique involves capping the neuroma with a biological or synthetic material. However, failure of this technique may result from mechanical irritation of the capped nerve. In addition, the physical act of blocking the nerve end is insufficient to prevent further neuroma formation and additional measures need to be taken to halt the regenerative process of the nerve. A new technique of using a bioresorbable polycaprolactone cap (NEUROCAP®), leaving a chamber distal to the nerve ending, has been studied in animal models. The chamber results in a resultant thinner, cone shaped neuroma with a more organised fascicle structure. The chamber prevents mechanical tether or compression by scar. The cap resorbs, preventing mechanical irritation of the nerve ending. We present a case where a NEUROCAP® was excised 6 months after implantation and the nerve end was studied. This study is the first of its kind, analysed in a human model.

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Section: Resultsmentioning

confidence: 99%

Analysis of an End Neuroma 6 Months after Capping with a Bioresorbable Polycaprolactone Cap (NEUROCAP®) in a Human Model

Power¹,

George²,

Pohl³

2020

SCR

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“…Studies have shown that silicone tubes, collagen tubes, microcrystalline chitosan, and PRGD/PDLLA conduits can achieve satisfactory effects in preventing traumatic neuroma formation. [22][23][24][25][26][27][28] Hong et al 29 found that acellular nerve allografts (ANAs) attached to the proximal end of an injured nerve can limit axon growth in a controlled manner, indicating that the use of ANAs as a tool to control neuroma formation may be a viable clinical option. In addition, Zhou et al 11 found that the application of a nanofibrous scaffold consisting of aligned silk fibroin blended with poly(l-lactic acid-co-caprolactone) activated the RhoA/ROCK signaling pathway, which contributed to the prevention of traumatic painful neuroma formation because of its suppressive effect on axon regeneration.…”

Section: Discussionmentioning

confidence: 99%

Covering the proximal nerve stump with chondroitin sulfate proteoglycans prevents traumatic painful neuroma formation by blocking axon regeneration after neurotomy in Sprague Dawley rats

Qiu

Zou

et al. 2021

Journal of Neurosurgery

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OBJECTIVENeuropathic pain caused by traumatic neuromas is an extremely intractable clinical problem. Disorderly scar tissue accumulation and irregular and immature axon regeneration around the injury site mainly contribute to traumatic painful neuroma formation. Therefore, successfully preventing traumatic painful neuroma formation requires the effective inhibition of irregular axon regeneration and disorderly accumulation of scar tissue. Considering that chondroitin sulfate proteoglycans (CSPGs) can act on the growth cone and effectively inhibit axon regeneration, the authors designed and manufactured a CSPG-gelatin blocker to regulate the CSPGs’ spatial distribution artificially and applied it in a rat model after sciatic nerve neurectomy to evaluate its effects in preventing traumatic painful neuroma formation.METHODSSixty female Sprague Dawley rats were randomly divided into three groups (positive group: no covering; blank group: covering with gelatin blocker; and CSPG group: covering with the CSPG-gelatin blocker). Pain-related factors were evaluated 2 and 8 weeks postoperatively (n = 30). Neuroma growth, autotomy behavior, and histological features of the neuromas were assessed 8 weeks postoperatively (n = 30).RESULTSEight weeks postoperatively, typical bulb-shaped neuromas did not form in the CSPG group, and autotomy behavior was obviously better in the CSPG group (p < 0.01) than in the other two groups. Also, in the CSPG group the regenerated axons showed a lower density and more regular and improved myelination (p < 0.01). Additionally, the distribution and density of collagenous fibers and the expression of α–smooth muscle actin were significantly lower in the CSPG group than in the positive group (p < 0.01). Regarding pain-related factors, c-fos, substance P, interleukin (IL)–17, and IL-1β levels were significantly lower in the CSPG group than those in the positive and blank groups 2 weeks postoperatively (p < 0.05), while substance P and IL-17 remained lower in the CSPG group 8 weeks postoperatively (p < 0.05).CONCLUSIONSThe authors found that CSPGs loaded in a gelatin blocker can prevent traumatic neuroma formation and effectively relieve pain symptoms after sciatic nerve neurotomy by blocking irregular axon regeneration and disorderly collagenous fiber accumulation in the proximal nerve stump. These results indicate that covering the proximal nerve stump with CSPGs may be a new and promising strategy to prevent traumatic painful neuroma formation in the clinical setting.

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“…Neural tissue damages caused by either neurodegenerative diseases or high-energy trauma greatly affect the patients' quality of life worldwide. The mammalian neuronal cells show the limitation of regrowth performance and functional recovery, presenting a critical clinical challenge for surgeons (Yi et al, 2018;Zhang P.-X. et al, 2019).…”

Section: Applications In Neural Tissue Engineeringmentioning

confidence: 99%

Recent Advances on Magnetic Sensitive Hydrogels in Tissue Engineering

et al. 2020

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Tissue engineering is a promising strategy for the repair and regeneration of damaged tissues or organs. Biomaterials are one of the most important components in tissue engineering. Recently, magnetic hydrogels, which are fabricated using iron oxide-based particles and different types of hydrogel matrices, are becoming more and more attractive in biomedical applications by taking advantage of their biocompatibility, controlled architectures, and smart response to magnetic field remotely. In this literature review, the aim is to summarize the current development of magnetically sensitive smart hydrogels in tissue engineering, which is of great importance but has not yet been comprehensively viewed.

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Painful Terminal Neuroma Prevention by Capping PRGD/PDLLA Conduit in Rat Sciatic Nerves

Cited by 30 publications

References 61 publications

Analysis of an End Neuroma 6 Months after Capping with a Bioresorbable Polycaprolactone Cap (NEUROCAP®) in a Human Model

Analysis of an End Neuroma 6 Months after Capping with a Bioresorbable Polycaprolactone Cap (NEUROCAP®) in a Human Model

Covering the proximal nerve stump with chondroitin sulfate proteoglycans prevents traumatic painful neuroma formation by blocking axon regeneration after neurotomy in Sprague Dawley rats

Recent Advances on Magnetic Sensitive Hydrogels in Tissue Engineering

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