Current guidelines, challenges and future recommendations for regulation of stem cell research and therapy: a commentary.

In recent years, Malaysia has seen a surge in stem cell therapy for various medical conditions. However, the regulation of stem cell research and therapy in Malaysia faces several challenges such as the emergence of unregulated clinics and a lack of specific legislation. Some urgent measures, including enactment of specific laws, strengthened monitoring, as well as increased public awareness and education, are crucial. Therefore, stem cell therapy regulation requires concerted efforts by the policymakers, regulator bodies and healthcare professionals. This commentary discusses the current guidelines and challenges in Malaysian stem cell therapy regulation and proposes some future recommendations that could pave the way for responsible progress of stem cell research and therapy globally.

In-silico identification of deleterious non-synonymous SNPs of TBX1 gene: Functional and structural impact towards 22q11.2DS.

The TBX1 gene plays a critical role in the development of 22q11.2 deletion syndrome (22q11.2DS), a complex genetic disorder associated with various phenotypic manifestations. In this study, we performed in-silico analysis to identify potentially deleterious non-synonymous single nucleotide polymorphisms (nsSNPs) within the TBX1 gene and evaluate their functional and structural impact on 22q11.2DS. A comprehensive analysis pipeline involving multiple computational tools was employed to predict the pathogenicity of nsSNPs. This study assessed protein stability and explored potential alterations in protein-protein interactions. The results revealed the rs751339103(C>A), rs780800634(G>A), rs1936727304(T>C), rs1223320618(G>A), rs1248532217(T>C), rs1294927055 (C>T), rs1331240435 (A>G, rs1601289406 (A>C), rs1936726164 (G>A), and rs911796187(G>A) with a high-risk potential for affecting protein function and stability. These nsSNPs were further analyzed for their impact on post-translational modifications and structural characteristics, indicating their potential disruption of molecular pathways associated with TBX1 and its interacting partners. These findings provide a foundation for further experimental studies and elucidation of potential therapeutic targets and personalized treatment approaches for individuals affected by 22q11.2DS.