Nerve regeneration using decellularized tissues: challenges and opportunities

Novel genipin-crosslinked acellular biogenic conduits for tissue engineering applications

BACKGROUND

Collagen-based conduits have been generated in-vivo stimulating a fibrotic response through the implantation of a non-resorbable material in animal models, creating biogenic substitutes. However, they often exhibit clinical limitations due to prolonged generation times, exclusive autologous use and insufficient mechanical strength. Consequently, decellularization and cross-linking could solve the aforementioned drawbacks, providing a non-immunogenic and ready-to-use natural substitute with enhanced biomechanical properties. Nevertheless, these processes may alter microarchitecture and biocompatibility. Hence, this is the first study to characterize ex-vivo the biogenic conduits of 1-and 2-months maturation time which were subjected to decellularization and genipin (GP) cross-linking procedures performing histological, structural, biomechanical, biocompatibility, and immunological analyses to identify the most suitable option for peripheral nerve regeneration.

RESULTS

Histological examination indicated consistent uniformity of the biogenic conduits at both timepoints post-implantation, maintaining their overall structural integrity and collagen pattern following decellularization and GP crosslinking treatments. Furthermore, no evidence of nuclear debris was observed in the decellularized groups at either stage of maturation, confirming the decellularization protocol's efficiency. The substitutes with longer maturation time presented a generally higher preservation of ECM key components. In addition, the GP crosslinking significantly increased the resistance values of decellularized biogenic conduits, without drastically affecting the ex-vivo cell biocompatibility nor macrophage polarization rate phenotype.

CONCLUSIONS

These findings indicate the suitability of our decellularization protocol for biogenic conduits, and subsequent crosslinking with GP improves their biomechanical properties without altering their biocompatibility or immunological profile, suggesting their potential as a ready-to-use tubular substitute for nerve and other tissue engineering applications.

Hydrogel system with growth cone-targeted hydroxyapatite nanorods: Regulating calcium signals for peripheral nerve injury repair

Calcium (Ca²⁺) regulation assumes a critical role in the repair course of peripheral nerve injury (PNI). However, effective calcium sources capable of providing sustained Ca²⁺ signals to promote growth cone extension remain limited. Herein, the coupling of biotinylated dextran amine (BDA) to amine-functionalized hydroxyapatite nanorods (nHAP-NH2) remarkably promoted and maintained the extension of growth cones throughout nerve regeneration. Therefore, a newly developed therapeutic system for PNI was constructed based on a hydrogel (Gel) loaded with BDA-nHAP (nHAP-NH2 with surface modification of BDA) and vascular endothelial growth factor (VEGF). The sustained-release BDA-nHAP has the potential to continuously and targetedly increase the Ca2+ levels within the growth cone, and further boost neurite outgrowth by modulating the PI3K-PAK and MAPK signalling pathways. Moreover, VEGF can significantly promote angiogenesis in the early stage of nerve repair, which is critical for optimizing the functional efficacy of BDA-nHAP in enhancing neurogenesis. Thus, this innovative integrated therapeutic system with neurogenesis and angiogenesis capabilities may offer a new solution for achieving high-quality functional recovery from PNI. STATEMENT OF SIGNIFICANCE: For PNI, there remains a scarcity of effective calcium sources capable of providing sustained Ca²⁺ signals within the growth cone to enhance its extension. Herein, a newly developed therapeutic system for PNI was constructed based on a Gel loaded with BDA-nHAP and VEGF. The sustained-release BDA-nHAP has the potential to continuously and targetedly increase the Ca2+ levels within the growth cone, and further boost neurite outgrowth throughout the whole process of nerve regeneration. Moreover, VEGF can significantly promote angiogenesis in the early stage of nerve repair, which is critical for optimizing the functional efficacy of BDA-nHAP in enhancing neurogenesis. Thus, this innovative therapeutic system may offer a new solution for achieving high-quality functional recovery from PNI.

Development and characterization of bifunctional conductive and magnetic scaffold based on polyvinyl alcohol/polypyrrole/magnetite composite for neural tissue engineering

The incorporation of electroconductive and magnetic materials into scaffolds for tissue engineering has emerged as an innovative approach to enhance nerve tissue regeneration. In this study, the freeze-drying technique was used to fabricate a bifunctional 3D neural scaffold based on biodegradable polyvinyl alcohol (PVA), incorporating magnetite nanoparticles (Fe3O4NPs) and the conductive polymer polypyrrole (PPy). Microstructural and chemical analyses using field emission scanning electron microscopy/energy-dispersive spectrophotometer, x-ray diffraction, and Fourier transform infrared spectroscopy revealed scaffolds with a homogeneous structure, interconnected pores averaging 100 µm, and over 80% porosity, with magnetite evenly distributed in the PVA matrix. The incorporation of Fe3O4nanoparticles significantly enhanced the scaffold's compressive strength and elastic modulus, while PPy increased conductivity to levels comparable to those of native neural tissue. The scaffold also exhibited superparamagnetic properties due to Fe3O4NPs, as confirmed by vibrating-sample magnetometry analysis. PBS submersion demonstrated water absorption and a 30% weight loss over 24 d.In vitrocytotoxicity tests on SH-SY5Y human neuroblastoma cells cultured on composite scaffolds confirmed cell viability, both with and without pulsed electromagnetic field stimulation. Overall, these results suggest that this scaffold is a promising candidate for neural tissue regeneration.

Three-dimensional in vitro models in head and neck cancer: current trends and applications

Head and neck cancer (HNC) is the sixth most prevalent malignancy worldwide and includes a variety of upper gastrointestinal abnormalities. HNC includes oral, throat, voice box, nasal cavity, paranasal sinuses, and salivary gland cancers. Squamous cells in the mouth, nose, and throat cause HNC. Drugs, alcohol, poor diets, smoking, and genetics all contribute to this condition. Cancer research has focused on three-dimensional (3D) models in HNC biology in recent decades. An adequate microenvironmental system and cancer cell culture are the initial steps to understanding cancer cells' complicated interactions with their surroundings. New 3D models claim to bridge in vivo and in vitro investigations and erase the gap. Interdisciplinary cell biology and tissue engineering researchers are creating 3D cancer tissue models to better understand the illness and develop more accurate cancer medicines. Tissue engineering researchers, who are always exploring novel approaches to treat cancer, have been able to include the third dimension into laboratory settings and mimic cell-to-cell and cell-to-matrix interactions by recreating the tumor microenvironment using 3D models and so make research on cancer easier. This review addresses recent developments in tissue engineering with an emphasis on 3D models in HNC.

Application of decellularized tissues in ear regeneration

More than 5 % of people worldwide suffer from hearing disorders. Ototoxic drugs, aging, exposure to loud sounds, rupture, subperichondrial hematoma, perichondritis, burns and frostbite and infections are the main causes of hearing loss, some of which can destroy the cartilage and lead to deformation. On the other hand, disorders of the external ear are diverse and can range from dangerous neoplasms to defects that are not acceptable from a cosmetic standpoint. These issues include injuries, blockages, dermatoses, and infections, and any or all of them may be bothersome to the busy doctor. Using an implant or hearing aid is one of the treatment strategies for deafness. However, these medical devices are not useful for every eligible patient. With the right therapy, many of these issues are not life-threatening and can be treated with confidence in a positive outcome. As medical research and treatment have advanced dramatically in the past ten years, tissue engineering (TE) has emerged as a promising method to regenerate damaged tissue, raising the prospect of a permanent cure for deafness. Decellularization is now seen as a promising development for regenerative medicine, and an increasing number of applications are being found for acellular matrices. Studies on decellularization show that natural scaffolds made from decellularized tissues can serve as a suitable platform while preserving the main components, and the preparation of such scaffolds will be an important part of future bioscience research. It can have wide applications in regenerative medicine and TE. This review intends to give an overview of the status of research and alternative scaffolds in inner and outer ear regenerative medicine from both a preclinical and clinical perspective for ear disorders in order to show how ongoing TE research has the potential to advance and enhance novel disease treatments.

In vivo bioengineered tooth formation using decellularized tooth bud extracellular matrix scaffolds

The use of dental implants to replace lost or damaged teeth has become increasingly widespread due to their reported high survival and success rates. In reality, the long-term survival of dental implants remains a health concern, based on their short-term predicted survival of ~15 years, significant potential for jawbone resorption, and risk of peri-implantitis. The ability to create functional bioengineered teeth, composed of living tissues with properties similar to those of natural teeth, would be a significant improvement over currently used synthetic titanium implants. To address this possibility, our research has focused on creating biological tooth substitutes. The study presented here validates a potentially clinically relevant bioengineered tooth replacement therapy for eventual use in humans. We created bioengineered tooth buds by seeding decellularized tooth bud (dTB) extracellular matrix (ECM) scaffolds with human dental pulp cells, porcine tooth bud-derived dental epithelial cells, and human umbilical vein endothelial cells. The resulting bioengineered tooth bud constructs were implanted in the mandibles of adult Yucatan minipigs and grown for 2 or 4 months. We observed the formation of tooth-like tissues, including tooth-supporting periodontal ligament tissues, in cell-seeded dTB ECM constructs. This preclinical translational study validates this approach as a potential clinically relevant alternative to currently used dental implants.

Preliminary study on the preparation of lyophilized acellular nerve scaffold complexes from rabbit sciatic nerves with human umbilical cord mesenchymal stem cells

BACKGROUND

The gold standard of care for patients with severe peripheral nerve injury is autologous nerve grafting; however, autologous nerve grafts are usually limited for patients because of the limited number of autologous nerve sources and the loss of neurosensory sensation in the donor area, whereas allogeneic or xenografts are even more limited by immune rejection. Tissue-engineered peripheral nerve scaffolds, with the morphology and structure of natural nerves and complex biological signals, hold the most promise as ideal peripheral nerve "replacements".

AIM

To prepare allogenic peripheral nerve scaffolds using a low-toxicity decellularization method, and use human umbilical cord mesenchymal stem cells (hUC-MSCs) as seed cells to cultivate scaffold-cell complexes for the repair of injured peripheral nerves.

METHODS

After obtaining sciatic nerves from New Zealand rabbits, an optimal acellular scaffold preparation scheme was established by mechanical separation, varying lyophilization cycles, and trypsin and DNase digestion at different times. The scaffolds were evaluated by hematoxylin and eosin (HE) and luxol fast blue (LFB) staining. The maximum load, durability, and elastic modulus of the acellular scaffolds were assessed using a universal material testing machine. The acellular scaffolds were implanted into the dorsal erector spinae muscle of SD rats and the scaffold degradation and systemic inflammatory reactions were observed at 3 days, 1 week, 3 weeks, and 6 weeks following surgery to determine the histocompatibility between xenografts. The effect of acellular scaffold extracts on fibroblast proliferation was assessed using an MTT assay to measure the cytotoxicity of the scaffold residual reagents. In addition, the umbilical cord from cesarean section fetuses was collected, and the Wharton's jelly (WJ) was separated into culture cells and confirm the osteogenic and adipogenic differentiation of mesenchymal stem cells (MSCs) and hUC-MSCs. The cultured cells were induced to differentiate into Schwann cells by the antioxidant-growth factor induction method, and the differentiated cells and the myelinogenic properties were identified.

RESULTS

The experiments effectively decellularized the sciatic nerve of the New Zealand rabbits. After comparing the completed acellular scaffolds among the groups, the optimal decellularization preparation steps were established as follows: Mechanical separation of the epineurium, two cycles of lyophilization-rewarming, trypsin digestion for 5 hours, and DNase digestion for 10 hours. After HE staining, no residual nuclear components were evident on the scaffold, whereas the extracellular matrix remained intact. LFB staining showed a significant decrease in myelin sheath composition of the scaffold compared with that before preparation. Biomechanical testing revealed that the maximum tensile strength, elastic modulus, and durability of the acellular scaffold were reduced compared with normal peripheral nerves. Based on the histocompatibility test, the immune response of the recipient SD rats to the scaffold New Zealand rabbits began to decline3 weeks following surgery, and there was no significant rejection after 6 weeks. The MTT assay revealed that the acellular reagent extract had no obvious effects on cell proliferation. The cells were successfully isolated, cultured, and passaged from human umbilical cord WJ by MSC medium, and their ability to differentiate into Schwann-like cells was demonstrated by morphological and immunohistochemical identification. The differentiated cells could also myelinate in vitro.

CONCLUSION

The acellular peripheral nerve scaffold with complete cell removal and intact matrix may be prepared by combining lyophilization and enzyme digestion. The resulting scaffold exhibited good histocompatibility and low cytotoxicity. In addition, hUC-MSCs have the potential to differentiate into Schwann-like cells with myelinogenic ability following in vitro induction.

Decellularization of various tissues and organs through chemical methods

Due to the increase in demand for donor organs and tissues during the past 20 years, new approaches have been created. These methods include, for example, tissue engineering in vitro and the production of regenerative biomaterials for transplantation. Applying the natural extracellular matrix (ECM) as a bioactive biomaterial for clinical applications is a unique approach known as decellularization technology. Decellularization is the process of eliminating cells from an extracellular matrix while preserving its natural components including its structural and functional proteins and glycosaminoglycan. This can be achieved by physical, chemical, or biological processes. A naturally formed three-dimensional structure with a biocompatible and regenerative structure is the result of the decellularization process. Decreasing the biological factors and antigens at the transplant site reduces the risk of adverse effects including inflammatory responses and immunological rejection. Regenerative medicine and tissue engineering applications can benefit from the use of decellularization, a promising approach that provides a biomaterial that preserves its extracellular matrix.

Tissue engineering strategies for ocular regeneration; from bench to the bedside

Millions globally suffer from visual impairment, complicating the management of eye diseases due to various ocular barriers. The eye's complex structure and the limitations of existing treatments have spurred interest in tissue engineering (TE) as a solution. This approach offers new functionalities and improves therapeutic outcomes over traditional drug delivery methods, creating opportunities for treating various eye disorders, from corneal injuries to retinal degeneration. In our review of recent articles concerning the use of scaffolds for eye repair, we categorized scaffolds employed in eye TE from recent studies into four types based on tissue characteristics: natural, synthetic, biohybrid, and decellularized tissue. Additionally, we gathered data on the cell types and animal models associated with each scaffold. This allowed us to gather valuable insights into the benefits and drawbacks of each material. Our research elucidates that, in comparison to conventional treatment modalities, scaffolds in TE emulate the extracellular matrix (ECM) of the eye and facilitate cell proliferation and tissue regeneration. These scaffolds can be precisely tailored to incorporate growth factors that augment the healing process while also providing considerable advantages such as bacterial inhibition, biocompatibility, and enhanced durability. However, they also have drawbacks, such as potential immune responses, poor tissue integration, complex and costly manufacturing, and inconsistent degradation rates that can affect their effectiveness. In this review, we provide an overview of the present condition of eye regenerative treatments, assess notable preclinical and clinical research endeavors, contemplate the obstacles encountered, and speculate on potential advancements in the upcoming decade.

Use of Decellularized Bio-Scaffolds for the Generation of a Porcine Artificial Intestine

In recent years, great interest has been focused on the development of highly reproducible 3D in vitro models that are able to mimic the physiological architecture and functionality of native tissues. To date, a wide range of techniques have been proposed to recreate an intestinal barrier in vitro, including synthetic scaffolds and hydrogels, as well as complex on-a-chip systems and organoids. Here, we describe a novel protocol for the generation of an artificial intestine based on the creation of decellularized bio-scaffolds and their repopulation with intestinal stromal and epithelial cells. Organs collected at the local slaughterhouse are subjected to a decellularization protocol that includes a freezing/thawing step, followed by sequential incubation in 1% SDS for 12 h, 1% Triton X-100 for 12 h, and 2% deoxycholate for 12 h. At the end of the procedure, the generated bio-scaffolds are repopulated with intestinal fibroblasts and then with epithelial cells. The protocol described here represents a promising and novel strategy to generate an in vitro bioengineered intestine platform able to mimic some of the complex functions of the intestinal barrier, thus constituting a promising 3D strategy for nutritional, pharmaceutical, and toxicological studies.

Decellularized extracellular matrix-decorated 3D nanofiber scaffolds enhance cellular responses and tissue regeneration

The use of decellularized extracellular matrix products in tissue regeneration is quite alluring yet practically challenging due to the limitations of its availability, harsh processing techniques, and host rejection. Scaffolds obtained by either incorporating extracellular matrix (ECM) material or coating the surface can resolve these challenges to some extent. However, these scaffolds lack the complex 3D network formed by proteins and growth factors observed in natural ECM. This study introduces an approach utilizing 3D nanofiber scaffolds decorated with dECM to enhance cellular responses and promote tissue regeneration. Notably, the dECM can be customized according to specific cellular requirements, offering a tailored environment for enhanced therapeutic outcomes. Two types of 3D expanded scaffolds, namely radially aligned scaffolds (RAS) and laterally expanded scaffolds (LES) fabricated by the gas-foaming expansion were utilized. To demonstrate the proof-of-concept, human dermal fibroblasts (HDFs) seeded on these scaffolds for up to 8 weeks, resulted in uniform and highly aligned cells which deposited ECM on the scaffolds. These cellular components were then removed from the scaffolds through decellularization (e.g., SDS treatment and freeze-thaw cycles). The dECM-decorated 3D expanded nanofiber scaffolds can direct and support cell alignment and proliferation along the underlying fibers upon recellularization. An in vitro inflammation assay indicates that dECM-decorated LES induces a lower immune response than dECM-decorated RAS. Further, subcutaneous implantation of dECM-decorated RAS and LES shows higher cell infiltration and angiogenesis within 7 and 14 days than RAS and LES without dECM decoration. Taken together, dECM-decorated 3D expanded nanofiber scaffolds hold great potential in tissue regeneration and tissue modeling. STATEMENT OF SIGNIFICANCE: Decellularized ECM scaffolds have attained widespread attention in biomedical applications due to their intricate 3D framework of proteins and growth factors. Mimicking such a complicated architecture is a clinical challenge. In this study, we developed natural ECM-decorated 3D electrospun nanofiber scaffolds with controlled alignments to mimic human tissue. Fibroblasts were cultured on these scaffolds for 8 weeks to deposit natural ECM and decellularized by either freeze-thawing or detergent to obtain decellularized ECM scaffolds. These scaffolds were tested in both in-vitro and in-vivo conditions. They displayed higher cellular attributes with lower immune response making them a good grafting tool in tissue regeneration.

Engineering cell-derived extracellular matrix for peripheral nerve regeneration

Extracellular matrices (ECMs) play a key role in nerve repair and are recognized as the natural source of biomaterials. In parallel to extensively studied tissue-derived ECMs (ts-ECMs), cell-derived ECMs (cd-ECMs) also have the capability to partially recapitulate the complicated regenerative microenvironment of native nerve tissues. Notably, cd-ECMs can avoid the shortcomings of ts-ECMs. Cd-ECMs can be prepared by culturing various cells or even autologous cells in vitro under pathogen-free conditions. And mild decellularization can achieve efficient removal of immunogenic components in cd-ECMs. Moreover, cd-ECMs are more readily customizable to achieve the desired functional properties. These advantages have garnered significant attention for the potential of cd-ECMs in neuroregenerative medicine. As promising biomaterials, cd-ECMs bring new hope for the effective treatment of peripheral nerve injuries. Herein, this review comprehensively examines current knowledge about the functional characteristics of cd-ECMs and their mechanisms of interaction with cells in nerve regeneration, with a particular focus on the preparation, engineering optimization, and scalability of cd-ECMs. The applications of cd-ECMs from distinct cell sources reported in peripheral nerve tissue engineering are highlighted and summarized. Furthermore, current limitations that should be addressed and outlooks related to clinical translation are put forward as well.

Enhancing electrical conductivity and mechanical properties of decellularized umbilical cord arteries using graphene coatings

Traditional decellularized bioscaffolds possessing intact vascular networks and unique architecture have been extensively studied as conduits for repairing nerve damage. However, they are limited by the absence of electrical conductivity, which is crucial for proper functioning of nervous tissue. This study focuses on investigating decellularized umbilical cord arteries by applying coatings of graphene oxide (GO) and reduced graphene oxide (RGO) to their inner surfaces. This resulted in a homogeneous GO coating that fully covered the internal lumen of the arteries. The results of electrical measurements demonstrated that the conductivity of the scaffolds could be significantly enhanced by incorporating RGO and GO conductive sheets. At a low frequency of 0.1 Hz, the electrical resistance level of the coated scaffolds decreased by 99.8% with RGO and 98.21% with GO, compared with uncoated scaffolds. Additionally, the mechanical properties of the arteries improved by 24.69% with GO and 32.9% with RGO after the decellularization process. The GO and RGO coatings did not compromise the adhesion of endothelial cells and promoted cell growth. The cytotoxicity tests revealed that cell survival rate increased over time with RGO, while it decreased with GO, indicating the time-dependent effect on the cytotoxicity of GO and RGO. Blood compatibility evaluations showed that graphene nanomaterials did not induce hemolysis but exhibited some tendency toward blood coagulation.

Biomaterials targeting the microenvironment for spinal cord injury repair: progression and perspectives

Spinal cord injury (SCI) disrupts nerve pathways and affects sensory, motor, and autonomic function. There is currently no effective treatment for SCI. SCI occurs within three temporal periods: acute, subacute, and chronic. In each period there are different alterations in the cells, inflammatory factors, and signaling pathways within the spinal cord. Many biomaterials have been investigated in the treatment of SCI, including hydrogels and fiber scaffolds, and some progress has been made in the treatment of SCI using multiple materials. However, there are limitations when using individual biomaterials in SCI treatment, and these limitations can be significantly improved by combining treatments with stem cells. In order to better understand SCI and to investigate new strategies for its treatment, several combination therapies that include materials combined with cells, drugs, cytokines, etc. are summarized in the current review.

Exosome-loaded decellularized tissue: Opening a new window for regenerative medicine

Mesenchymal stem cell-derived exosomes (MSCs-EXO) have received a lot of interest recently as a potential therapeutic tool in regenerative medicine. Extracellular vesicles (EVs) known as exosomes (EXOs) are crucial for cell-cell communication throughout a variety of activities including stress response, aging, angiogenesis, and cell differentiation. Exploration of the potential use of EXOs as essential therapeutic effectors of MSCs to encourage tissue regeneration was motivated by success in the field of regenerative medicine. EXOs have been administered to target tissues using a variety of methods, including direct, intravenous, intraperitoneal injection, oral delivery, and hydrogel-based encapsulation, in various disease models. Despite the significant advances in EXO therapy, various methods are still being researched to optimize the therapeutic applications of these nanoparticles, and it is not completely clear which approach to EXO administration will have the greatest effects. Here, we will review emerging developments in the applications of EXOs loaded into decellularized tissues as therapeutic agents for use in regenerative medicine in various tissues.

Tissue engineering in otology: a review of achievements

Tissue engineering application in otology spans a distance from the pinna to auditory nerve covered with specialized tissues and functions such as sense of hearing and aesthetics. It holds the potential to address the barriers of lack of donor tissue, poor tissue match, and transplant rejection through provision of new and healthy tissues similar to the host and possesses the capacity to renew, to regenerate, and to repair in-vivo and was shown to be a bypasses for any need to immunosuppression. This review aims to investigate the application of tissue engineering in otology and to evaluate the achievements and challenges in external, middle and inner ear sections. Since gaining the recent knowledge and training on use of different scaffolds is essential for otology specialists and who look for the recovery of ear function and aesthetics of patients, it is shown in this review how utilizing tissue engineering and cell transplantation, regenerative medicine can provide advancements in hearing and ear aesthetics to fit different patients' needs.

Exploring the properties and potential of the neural extracellular matrix for next-generation regenerative therapies

The extracellular matrix (ECM) is a dynamic and complex network of proteins and molecules that surrounds cells and tissues in the nervous system and orchestrates a myriad of biological functions. This review carefully examines the diverse interactions between cells and the ECM, as well as the transformative chemical and physical changes that the ECM undergoes during neural development, aging, and disease. These transformations play a pivotal role in shaping tissue morphogenesis and neural activity, thereby influencing the functionality of the central nervous system (CNS). In our comprehensive review, we describe the diverse behaviors of the CNS ECM in different physiological and pathological scenarios and explore the unique properties that make ECM-based strategies attractive for CNS repair and regeneration. Addressing the challenges of scalability, variability, and integration with host tissues, we review how advanced natural, synthetic, and combinatorial matrix approaches enhance biocompatibility, mechanical properties, and functional recovery. Overall, this review highlights the potential of decellularized ECM as a powerful tool for CNS modeling and regenerative purposes and sets the stage for future research in this exciting field. This article is categorized under: Implantable Materials and Surgical Technologies > Nanotechnology in Tissue Repair and Replacement Therapeutic Approaches and Drug Discovery > Nanomedicine for Neurological Disease Implantable Materials and Surgical Technologies > Nanomaterials and Implants.

Exploring an innovative decellularization protocol for porcine nerve grafts: a translational approach to peripheral nerve repair

Introduction

Peripheral nerves are frequently affected by lesions caused by traumatic or iatrogenic damages, resulting in loss of motor and sensory function, crucial in orthopedic outcomes and with a significant impact on patients' quality of life. Many strategies have been proposed over years to repair nerve injuries with substance loss, to achieve musculoskeletal reinnervation and functional recovery. Allograft have been tested as an alternative to the gold standard, the autograft technique, but nerves from donors frequently cause immunogenic response. For this reason, several studies are focusing to find the best way to decellularize nerves preserving either the extracellular matrix, either the basal lamina, as the key elements used by Schwann cells and axons during the regenerative process.

Methods

This study focuses on a novel decellularization protocol for porcine nerves, aimed at reducing immunogenicity while preserving essential elements like the extracellular matrix and basal lamina, vital for nerve regeneration. To investigate the efficacy of the decellularization protocol to remove immunogenic cellular components of the nerve tissue and to preserve the basal lamina and extracellular matrix, morphological analysis was performed through Masson's Trichrome staining, immunofluorescence, high resolution light microscopy and transmission electron microscopy. Decellularized porcine nerve graft were then employed in vivo to repair a rat median nerve lesion. Morphological analysis was also used to study the ability of the porcine decellularized graft to support the nerve regeneration.

Results and Discussion

The decellularization method was effective in preparing porcine superficial peroneal nerves for grafting as evidenced by the removal of immunogenic components and preservation of the ECM. Morphological analysis demonstrated that four weeks after injury, regenerating fibers colonized the graft suggesting a promising use to repair severe nerve lesions. The idea of using a porcine nerve graft arises from a translational perspective. This approach offers a promising direction in the orthopedic field for nerve repair, especially in severe cases where conventional methods are limited.