Metal grafted graphene-based nanomaterials towards cancer theranostic efficacy

Cancer is one of the leading global causes of mortality and morbidity, so it needs early diagnosis and therapies. Traditional diagnostic and therapeutic strategies are inadequate due to several limitations, such as poor specificity, systemic toxicity, and delays, while metal-grafted Gr nanostructures have emerged as promising theranostic platforms due to their unique electronic, optical, and structural properties. Metals such as Fe3O4, Au, Ag, TiO2, Pd, Pt, Bi, ZnO, and Cu grafted onto the Gr surface impart electronic modulation, enhance surface area, flexibility, conductivity, reactivity, biomolecular interactions, and biosensing, thereby enabling precise biomarker detection, targeted drug delivery, imaging, and photothermal/photodynamic therapy (PTT/PDT). Eco-friendly synthesis using plant extracts and microbes offers a sustainable and biocompatible alternative to conventional chemical synthesis. However, challenges remain, such as homogenous doping, synthetic complexity, long-term safety, and clinical scalability. Innovations such as scalable, cost-effective, biocompatible nanofibers, nanopapers, microfluidic, and wearable biosensors are being explored by incorporating AI and advanced diagnostic tools for advanced biomedical devices. In vitro, half maximum inhibitory concentrations (IC50) studies show that size- and dose-dependent nanohybrids such as Fe3O4-Gr, γ-Fe2O3-Gr, Au-Gr, and Bi-Gr exhibited safer responses at lower concentrations 10–200 µg/mL across HBE, MCF-7, HeLa B, and LNCaP cell lines. Bi-Gr was tested on human liver cancer (HepG2) cell line, which exhibits higher reactivity despite a safer profile of Bi at ~53–88 µg/mL. Pd-Gr and Pt-Gr significantly reduced viability in prostate and ovarian cancer cells at 10–50 µg/mL, while ZnO-Gr, Ag-Gr, and Cu-Gr showed safer activity at lower concentrations on MCF-7. In vivo studies remain limited; median lethal dose (LD50) values for Fe3O4-Gr and γ-Fe2O3-Gr were determined to be associated with rapid lethal biodistribution observed in the liver, lungs, and spleen. Metal-grafted Gr nanohybrids demonstrate immense potential for multifunctional cancer theranostics, though systematic in vivo toxicity studies still need to be explored by the intravenously administered route to lower the LD50 of nanohybrids for their clinical translation

Genome-wide analysis of the class III peroxidase gene family in sesame and SiPRXs gene validation by expression analysis under drought stress

Sesame (Sesamum indicum) is an important indigenous oilseed crop but its growth and productivity are severely affected by abiotic stresses. Class III peroxidases are key stress related enzymes that exclusively occur in plant kingdom, however, their specific involvement in sesame remains largely unexplored. The present study aimed to identify the PRX gene family in sesame and elucidate their role in conferring drought stress tolerance in contrasting sesame accessions. Through genome-wide analysis of the PRX gene family, 45 non-redundant members (designated SiPRXs) were identified which were unequally distributed on 13 sesame chromosomes. Motif analysis revealed highly conserved peroxidase domains in all SiPRX proteins. To validate the function of identified SiPRX family members, sesame accessions were phenotyped under drought stress and irrigated conditions. The contrasting drought-tolerant and drought-sensitive accessions were used to study the relative transcript abundance of the selected 15 SiPRX genes by quantitative real-time PCR.Expression analysis revealed differential expression of SiPRX genes between drought-tolerant and drought-sensitive accessions, which was consistent with their physiological responses to drought stress. Our findings provide comprehensive insights into the genomic characterization of the SiPRX gene family in sesame with special reference to drought stress tolerance. These results emphasize the potential utility of SiPRX genes in enhancing drought resilience in sesame with implications for crop improvement strategies