Abstract
Traumatic brain injury (TBI) is the leading cause of disability and mortality in children and young adults and has a profound impact on the socio-economic wellbeing of patients and their families. Initially, brain damage is caused by mechanical stress-induced axonal injury and vascular dysfunction, which can include hemorrhage, blood-brain barrier disruption, and ischemia. Subsequent neuronal degeneration, chronic inflammation, demyelination, oxidative stress, and the spread of excitotoxicity can further aggravate disease pathology. Thus, TBI treatment requires prompt intervention to protect against neuronal and vascular degeneration. Rapid advances in the field of stem cells (SCs) have revolutionized the prospect of repairing brain function following TBI. However, more than that, SCs can contribute substantially to our knowledge of this multifaced pathology. Research, based on human induced pluripotent SCs (hiPSCs) can help decode the molecular pathways of degeneration and recovery of neuronal and glial function, which makes these cells valuable tools for drug screening. Additionally, experimental approaches that include hiPSC-derived engineered tissues (brain organoids and bio-printed constructs) and biomaterials represent a step forward for the field of regenerative medicine since they provide a more suitable microenvironment that enhances cell survival and grafting success. In this review, we highlight the important role of hiPSCs in better understanding the molecular pathways of TBI-related pathology and in developing novel therapeutic approaches, building on where we are at present. We summarize some of the most relevant findings for regenerative therapies using biomaterials and outline key challenges for TBI treatments that remain to be addressed.
Highlights
Traumatic brain injury (TBI) is defined as a disruption in the normal function of the brain caused by a sudden blow or jolt to the head, which is frequently suffered during unintentional falls, sporting activities, automotive accidents, or violent assaults (Peterson and Kegler, 2020)
We review the multifaced degenerative processes linked to TBI, focusing on how stem cell research, namely through the use of human induced pluripotent stem cells, can help decipher the molecular pathways suitable for pharmacotherapy and facilitate drug screening in the context of personalized medicine
Transplantation of endothelial cells (ECs) enhanced cell survival, increased the number of oligodendrocyte progenitor cell (OPC), suppressed inflammatory responses and astrocytosis, decreased the ischemic area, promoted remyelination, and recovered limb coordination. These results suggest that EC transplantation accelerates WM recovery after TBI
Summary
Traumatic brain injury (TBI) is defined as a disruption in the normal function of the brain caused by a sudden blow or jolt to the head, which is frequently suffered during unintentional falls, sporting activities, automotive accidents, or violent assaults (Peterson and Kegler, 2020). We describe how engineered tissues (i.e., brain organoids, bio-printed tissues, and biomaterials) can enhance the success of stem cell therapies in the treatment of TBI.
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