Peripheral nerve injuries (PNIs) constitute a significant concern as they predominantly affect young and productive age groups of the population, causing social and economic pressure on patients. PNIs are a global problem that can result in disability because of the disruption of nerve function. PNI leads to a reduction in nerve conduction velocity, which worsens or impairs the mobility of the innervated area. Managing PNI remains a major clinical challenge. Coenzyme Q10 (CoQ10) is a lipid-soluble antioxidant first identified in 1957. It is an important antioxidant necessary for the organs to maintain their normal function and the body’s chemical processes. It scavenges free radicals and reduces oxidative stress. Studies showed that antioxidants such as CoQ10 a potent antioxidant, help the regeneration of PNIs. It has been observed to increase the myelination process in nerve fibres and promote nerve regeneration in rats after injury. Therefore, this review handles the current positive effects of CoQ10 on peripheral nerve regeneration following injury.

Epilepsy, a complex neurological disorder, is influenced by intricate interactions within cortical, hippocampal, or thalamocortical neuronal networks, presenting a genetically complex condition with non-Mendelian inheritance patterns. This complexity is underscored by the involvement of numerous “susceptibilities” or “modifier” genes, complicating the assessment of risk and therapy outcomes. A critical inquiry in epilepsy treatment involves understanding how genetic diversity impacts treatment strategies and efficacy. Pharmacogenomic advancements have elaborated the connection between genetic variants and antiseizure medication (ASM) safety and response, marking a shift towards precision medicine in epilepsy care. Notably, genetic screening for variants such as HLA-B*1502 and HLA-A*3101 has demonstrated significant efficacy in preventing severe hypersensitivity reactions, including toxic epidermal necrolysis (TEN) and Stevens-Johnson syndrome (SJS), particularly among specific ethnic populations. However, putting pharmacogenomic discoveries into clinical practice faces numerous challenges, including educational, legal, and economic barriers, emphasizing the need for broader acceptance and integration of pharmacogenomic data. This review synthesizes recent studies on pharmacogenomics in epilepsy, highlighting the current advances and prospects for personalizing epilepsy treatment through genetic insights, aiming to enhance ASM safety, reduce adverse effects, and improve treatment outcomes. Through a comprehensive examination of the genetic basis of epilepsy and its influence on pharmacotherapy, this review endeavors to contribute to the evolving landscape of precision medicine in epilepsy care, advocating for a more individualized and effective treatment approach.

Transmethylation in the context of psychiatry has historically referred to the enzymatic transfer of a methyl group from one biochemical to another, whose resulting function can change so dramatically that a biochemical like tryptamine, for example, is converted into the hallucinogen dimethyltryptamine. Central to endogenous methylation activity is the folate cycle, which generates the primary transferable methyl groups in mammalian biochemistry. The relevance of this cycle to mental health becomes clear when the cycle is dysregulated, often leading to a buildup of both homocysteine and S-adenosylhomocysteine (SAH), while accompanied by a transient reduction in the intended physiologic target, S-adenosylmethionine (SAM). This paper includes an in-depth review of the causes of folate cycle perturbations associated with psychotic symptoms, expounding on alternative downstream pathways which are activated and pointing toward potential etiologic agents of the associated psychosis, the methylated tertiary amines N-methyl-salsolinol, N-methyl-norsalsolinol, and adrenochrome, which appear in scientific reports concerning their association with hallucinogenic and/or neurotoxic outcomes. Electrotopological state (E-state) data has been generated for these compounds, illustrating a strong similarity with hallucinogens, particularly in terms of the E-state of the nitrogen in their tertiary amine moieties. In light of the role the folate cycle plays in transmethylation, neuroprotective strategies to prevent the transition to psychosis are suggested, including the advisory that folate supplementation can be harmful depending on the status of other relevant biochemicals.