INSPIRE Neuro-Spinal ScaffoldTM : An Implantable Alternative to Stem-Cell Therapy for Endogenous Repair in Spinal Cord Injury

Revisiting the Emerging Role of Light-Based Therapies in the Management of Spinal Cord Injuries

The surge in spinal cord injuries (SCI) attracted many neurobiologists to explore the underlying complex pathophysiology and to offer better therapeutic outcomes. The multimodal approaches to therapy in SCI have proven to be effective but to a limited extent. The clinical basics involve invasive procedures and limited therapeutic interventions, and most preclinical studies and formulations are yet to be translated due to numerous factors. In recent years, photobiomodulation therapy (PBMT) has found many applications in various medical fields. In most PBMT, studies on SCI have employed laser sources in experimental animal models as a non-invasive source. PBMT has been applied in numerous facets of SCI pathophysiology, especially attenuation of neuroinflammatory cascades, enhanced neuronal regeneration, reduced apoptosis and gliosis, and increased behavioral recovery within a short span. Although PBMT is specific in modulating mitochondrial bioenergetics, innumerous molecular pathways such as JAK-STAT, PI3K-AKT, NF-κB, MAPK, JNK/TLR/MYD88, ERK/CREB, TGF-β/SMAD, GSK3β-AKT-β-catenin, and AMPK/PGC-1α/TFAM signaling pathways have been or are yet to be exploited. PMBT has been effective not only in cell-specific actions in SCI such as astrocyte activation or microglial polarization or alterations in neuronal pathology but also modulated overall pathobiology in SCI animals such as rapid behavioral recovery. The goal of this review is to summarize research that has used PBMT for various models of SCI in different animals, including clarifying its mechanisms and prospective molecular pathways that may be utilized for better therapeutic outcomes.

Local drug delivery challenges and innovations in spinal neurosurgery

The development of novel therapeutics in the field of spinal neurosurgery faces a litany of translational challenges. Achieving precise drug targeting within the confined spaces associated with the spinal cord, canal and vertebra requires the development of next generation delivery systems and devices. These must be capable of overcoming inherent barriers related to drug diffusion, whilst concurrently ensuring optimal drug distribution and retention. In this review, we provide an overview of the most recent advances in the therapeutic management of diseases and disorders affecting the spine, including systems and devices capable of releasing small molecules and biopharmaceuticals that help eliminate pain and restore the mechanical function and stability of the spine. We highlight material-based approaches and minimally invasive techniques that can be employed to provide control over drug release kinetics and improve retention. We also seek to explore how the newest advancements in nanotechnology, biomaterials, additive manufacturing technologies and imaging modalities can be employed in this translational pursuit. Finally, we discuss the landscape of clinical trials and recently approved products aimed at overcoming the complexities associated with drug delivery to the spine.

Induced Neural Stem Cell Transplantation in Spinal Cord Injury: Present Status and Next Steps

Spinal cord injury (SCI) remains a significant clinical challenge, with no fully effective treatment available despite advancements in various therapeutic approaches. This review examines the emerging role of induced neural stem cells (iNSCs) as promising candidates for SCI treatment, highlighting their potential for direct neural regeneration and integration with host tissue. We explore the biology of iNSCs, their mechanisms of action, and their interactions with host tissue, including modulating inflammatory responses, promoting axonal growth, and reconstructing neural circuits. Additionally, the importance of administration route, optimal timing for transplantation, and potential adverse events are discussed to address key challenges in translating these therapies to clinical applications. The review also emphasizes recent innovations, such as combining iNSC transplantation with rehabilitative training and the integration of biomaterials and growth factors to enhance therapeutic efficacy. Although preclinical studies have demonstrated positive outcomes, larger, controlled trials and standardized protocols are essential for validating the safety and effectiveness of iNSC-based therapies for SCI patients.

How can clinical safety and efficacy concerns in stem cell therapy for spinal cord injury be overcome?

INTRODUCTION

Spinal cord injury (SCI) can lead to severe neurological dysfunction. Despite scientific and medical advances, clinically effective regenerative therapies including stem cells are lacking for SCI.

AREAS COVERED

This paper discusses translational challenges related to the safe, effective use of stem cells for SCI, with a focus on mesenchymal stem cells (MSCs), neural stem cells (NSCs), Schwann cells (SCs), olfactory ensheathing cells (OECs), oligodendrocyte precursor cells (OPCs), embryonic stem cells (ESCs), and induced pluripotent stem cells (iPSCs). We discuss approaches to enhance the efficacy of cell-based strategies by i) addressing patient heterogeneity and enhancing patient selection; ii) selecting cell type, cell source, cell developmental stage, and delivery technique; iii) enhancing graft integration and mitigating immune-mediated graft rejection; and iv) ensuring availability of cells. Additionally, we review strategies to optimize outcomes including combinatorial use of rehabilitation and discuss ways to mitigate potential risks of tumor formation associated with stem cell-based strategies.

EXPERT OPINION

Basic science research will drive translational advances to develop stem cell-based therapies for SCI. Genetic, serological, and imaging biomarkers may enable individualization of cell-based treatments. Moreover, combinatorial strategies will be required to enhance graft survival, migration and functional integration, to enable precision-based intervention.

Early Decompression in Acute Spinal Cord Injury : Review and Update

Spinal cord injury (SCI) has a significant negative effect on the quality of life due to permanent neurologic damage and economic burden by continuous treatment and rehabilitation. However, determining the correct approach to ensure optimal clinical outcomes can be challenging and remains highly controversial. In particular, with the introduction of the concept of early decompression in brain pathology, the discussion of the timing of decompression in SCI has emerged. In addition to that, the concept of "time is spine" has been added recently, and the mortality and complications caused by SCI have been reduced by providing timely and professional treatment to patients. However, there are many difficulties in establishing international clinical guidelines for the timing of early decompression in SCI because policies for each country and medical institution differ according to the circumstances of medical infrastructure and economic conditions in the surgical treatment of SCI. Therefore, we aim to provide a current review of timing of early decompression in patient with SCI.