Comprehensive ex vivo and in vivo preclinical evaluation of novel chemo enzymatic decellularized peripheral nerve allografts

García-García, Óscar Darío; Soury, Marwa El; Campos, Fernando; Sánchez-Porras, David; Geuna, Stefano; Alaminos, Miguel; Gambarotta, Giovanna; Chato‐Astrain, Jesús; Raimondo, Stefania; Carriel, Víctor

doi:10.3389/fbioe.2023.1162684

Cited by 8 publications

(4 citation statements)

References 77 publications

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“…Thus, it was possible to evaluate their ability to withstand stretch deriving from the formation of external fibrotic tissue, and if they are easy-to manipulate for clinicians [15,57]. Previous studies [37,58,59] have indicated that the Young's modulus of rat sciatic nerves varies between 10.19 and 18.66 MPa, which coincides with the Young's modulus values of FF scaffolds. The PLA and PCL scaffolds showed significant stiffness, which could potentially affect the nerve tissue structure and neuronal networks; however, this it could be addressed by blending these polymers with softer biomaterials to achieve more suitable viscoelastic properties [60].…”

Section: Discussionmentioning

confidence: 67%

Comparison of Printable Biomaterials for Use in Neural Tissue Engineering: An In Vitro Characterization and In Vivo Biocompatibility Assessment

Etayo-Escanilla,

Campillo,

Ávila-Fernández

et al. 2024

Polymers

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Nervous system traumatic injuries are prevalent in our society, with a significant socioeconomic impact. Due to the highly complex structure of the neural tissue, the treatment of these injuries is still a challenge. Recently, 3D printing has emerged as a promising alternative for producing biomimetic scaffolds, which can lead to the restoration of neural tissue function. The objective of this work was to compare different biomaterials for generating 3D-printed scaffolds for use in neural tissue engineering. For this purpose, four thermoplastic biomaterials, ((polylactic acid) (PLA), polycaprolactone (PCL), Filaflex (FF) (assessed here for the first time for biomedical purposes), and Flexdym (FD)) and gelatin methacrylate (GelMA) hydrogel were subjected to printability and mechanical tests, in vitro cell–biomaterial interaction analyses, and in vivo biocompatibility assessment. The thermoplastics showed superior printing results in terms of resolution and shape fidelity, whereas FD and GelMA revealed great viscoelastic properties. GelMA demonstrated a greater cell viability index after 7 days of in vitro cell culture. Moreover, all groups displayed connective tissue encapsulation, with some inflammatory cells around the scaffolds after 10 days of in vivo implantation. Future studies will determine the usefulness and in vivo therapeutic efficacy of novel neural substitutes based on the use of these 3D-printed scaffolds.

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Section: Discussionmentioning

confidence: 67%

Comparison of Printable Biomaterials for Use in Neural Tissue Engineering: An In Vitro Characterization and In Vivo Biocompatibility Assessment

Etayo-Escanilla,

Campillo,

Ávila-Fernández

et al. 2024

Polymers

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“…Studies involve assessing the regenerative potential of various decellularization protocols on animal models to understand their effectiveness in nerve regeneration. This research is crucial for advancing the treatment of severe nerve injuries where traditional methods may not be sufficient ( Garcia-Garcia et al, 2023 ). Decellularized nerve grafts should provide a suitable substrate for nerve regeneration in which the conservation of ECM components plays a crucial role for peripheral nerve regeneration and axonal guidance ( Hsu et al, 2023 ; Mahdian et al, 2023 ).…”

Section: Discussionmentioning

confidence: 99%

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

Muratori,

Crosio,

Ronchi

et al. 2024

Front. Neuroanat.

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IntroductionPeripheral 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.MethodsThis 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 DiscussionThe 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.

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“…Although dECM derived from tissues have biochemical and physical factors that support the growth of cells and tissues [ 32 ], the consistent provision of quality donor tissue constitutes a prominent constraint. Recognized challenges linked to tissue-derived dECM comprise pathogen transmission, uncontrolled degradation, and high manufacturing costs [ [33] , [34] , [35] ]. Nevertheless, the cell-based dECM with more advantages can be used to engineer scaffolds with different three-dimensional shapes and structures and other additional features to produce biomimetic tissue structures, and can be customized by selecting specific cells from a particular tissue or individual to overcome the limitations of homo- or xenotransplantation.…”

Section: Discussionmentioning

confidence: 99%

Mechanisms underlying the cell-matrixed nerve grafts repairing peripheral nerve defects

Wang,

et al. 2024

Bioactive Materials

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Comprehensive ex vivo and in vivo preclinical evaluation of novel chemo enzymatic decellularized peripheral nerve allografts

Cited by 8 publications

References 77 publications

Comparison of Printable Biomaterials for Use in Neural Tissue Engineering: An In Vitro Characterization and In Vivo Biocompatibility Assessment

Comparison of Printable Biomaterials for Use in Neural Tissue Engineering: An In Vitro Characterization and In Vivo Biocompatibility Assessment

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

Mechanisms underlying the cell-matrixed nerve grafts repairing peripheral nerve defects

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