Novel artificial nerve transplantation of human iPSC-derived neurite bundles enhanced nerve regeneration after peripheral nerve injury.

BACKGROUND: Severe peripheral nerve damage always requires surgical treatment. Autologous nerve transplantation is a standard treatment, but it is not sufficient due to length limitations and extended surgical time. Even with the available artificial nerves, there is still large room for improvement in their therapeutic effects. Novel treatments for peripheral nerve injury are greatly expected. METHODS: Using a specialized microfluidic device, we generated artificial neurite bundles from human iPSC-derived motor and sensory nerve organoids. We developed a new technology to isolate cell-free neurite bundles from spheroids. Transplantation therapy was carried out for large nerve defects in rat sciatic nerve with novel artificial nerve conduit filled with lineally assembled sets of human neurite bundles. Quantitative comparisons were performed over time to search for the artificial nerve with the therapeutic effect, evaluating the recovery of motor and sensory functions and histological regeneration. In addition, a multidimensional unbiased gene expression profiling was carried out by using next-generation sequencing. RESULT: After transplantation, the neurite bundle-derived artificial nerves exerted significant therapeutic effects, both functionally and histologically. Remarkably, therapeutic efficacy was achieved without immunosuppression, even in xenotransplantation. Transplanted neurite bundles fully dissolved after several weeks, with no tumor formation or cell proliferation, confirming their biosafety. Posttransplant gene expression analysis highlighted the immune system's role in recovery. CONCLUSION: The combination of newly developed microfluidic devices and iPSC technology enables the preparation of artificial nerves from organoid-derived neurite bundles in advance for future treatment of peripheral nerve injury patients. A promising, safe, and effective peripheral nerve treatment is now ready for clinical application.

Sex difference in susceptibility to acetaminophen hepatotoxicity is reversed by buthionine sulfoximine.

Gender is a factor that influences susceptibility of individuals to drug-induced liver injury in experimental animals and humans. In this study, we investigated the mechanisms underlying resistance of female mice to acetaminophen (APAP)-induced hepatotoxicity. Overnight-fasted male and female CD-1 mice were administered APAP intraperitoneally. A minor increase in serum alanine aminotransferase levels was observed in female mice after APAP administration at a dose that causes severe hepatotoxicity in males. Hepatic glutathione (GSH) depleted rapidly in the both genders prior to development of hepatotoxicity, whereas its recovery was more rapid in female than in male mice. This was consistent with higher induction of hepatic glutamate-cysteine ligase (GCL) in females. Pretreatment of mice with L-buthionine sulfoximine (BSO), an inhibitor of GCL, exaggerated APAP hepatotoxicity only in female mice, resulting in much higher hepatotoxicity in female than in male mice. In addition, hepatic GSH was markedly depleted in BSO-pretreated female mice compared with male mice, which supports severe hepatotoxicity in BSO-pretreated females. APAP treatment highly induced multidrug resistance-associated protein 4 (Mrp4) only in female mice. The resulting high Mrp4 expression could thus contribute to decreased hepatic GSH levels via sinusoidal efflux when GCL is inhibited. In conclusion, resistance to APAP hepatotoxicity in female mice and its reversal by pretreatment with BSO could be attributed to sex differences in disposition of hepatic GSH, which may generally determine susceptibility to drug-induced liver injury.

Protective effects of exogenous glutathione and related thiol compounds against drug-induced liver injury.

An overdose of acetaminophen (APAP) causes liver injury both in experimental animals and humans. N-acetylcysteine (NAC) is clinically used as an antidote for APAP intoxication, and it is thought to act by providing cysteine as a precursor of glutathione, which traps a reactive metabolite of APAP. Other hepatoprotective mechanisms of NAC have also been suggested. Here, we examined the effects of thiol compounds with different abilities to restore hepatic glutathione, on hepatotoxicity of APAP and furosemide in mice. Overnight-fasted male CD-1 mice were given APAP or furosemide intraperitoneally. NAC, cysteine, glutathione, or glutathione-monoethyl ester was administered concomitantly with APAP or furosemide. All thiol compounds used in this study effectively protected mice against APAP-induced liver injury. Only glutathione-monoethyl ester completely prevented APAP-induced early hepatic glutathione depletion. Cysteine also significantly restored hepatic glutathione levels. NAC partially restored glutathione levels. Exogenous glutathione had no effect on hepatic glutathione loss. NAC and glutathione highly stimulated the hepatic expression of cytokines, particularly interleukin-6, which might be involved in the alleviation of APAP hepatotoxicity. Furosemide-induced liver injury, which does not accompany hepatic glutathione depletion, was also attenuated by NAC and exogenous glutathione, supporting their protective mechanisms other than replenishment of glutathione. In conclusion, exogenous thiols could alleviate drug-induced liver injury. NAC and glutathione might exert their effects, at least partially, via mechanisms that are independent of increasing hepatic glutathione, but probably act through cytokine-mediated and anti-inflammatory mechanisms.