M. Sheikh Mohamed

Type 1 ribotoxin-curcin conjugated biogenic gold nanoparticles for a multimodal therapeutic approach towards brain cancer

BACKGROUND Gliomas have been termed recurrent cancers due to their highly aggressive nature. Their tendency to infiltrate and metastasize has posed significant roadblocks to in attaining fool proof treatment solutions. An initiative to curb such a scenario was successfully demonstrated in vitro, utilizing a multi-conceptual gold nanoparticle based photo-thermal and drug combination therapy. METHODS Gold nanoparticles (Au NPs) were synthesized with a highly environmentally benign process. The Au NPs were PEGylated and conjugated with folate and transferrin antibody to achieve a dual targeted nano-formulation directed towards gliomas. Curcin, a type 1 ribosome inactivating protein, was attached to the Au NPs as the drug candidate, and its multifarious toxic aspects analyzed in vitro. NIR photo-thermal properties of the Au nano-conjugates were studied to selectively ablate the glioma cancer colonies. RESULTS Highly cyto-compatible, 10-15nm Au NP conjugates were synthesized with pronounced specificity towards gliomas. Curcin was successfully conjugated to the Au NPs with pH responsive drug release. Prominent toxic aspects of curcin, such as ROS generation, mitochondrial and cytoskeletal destabilization were witnessed. Excellent photo-thermal ablation properties of gold nanoparticles were utilized to completely disrupt the cancer colonies with significant precision. CONCLUSION The multifunctional nanoconjugate projects its competence in imparting complete arrest of the future proliferation or migration of the cancer mass. GENERAL SIGNIFICANCE With multifunctionality the essence of nanomedicine in recent years, the present nanoconjugate highlights itself as a viable option for a multimodal treatment option for brain cancers and the like.

Synthesis and application of luminescent single CdS quantum dot encapsulated silica nanoparticles directed for precision optical bioimaging

This paper presents the synthesis of aqueous cadmium sulfide (CdS) quantum dots (QDs) and silica-encapsulated CdS QDs by reverse microemulsion method and utilized as targeted bio-optical probes. We report the role of CdS as an efficient cell tag with fluorescence on par with previously documented cadmium telluride and cadmium selenide QDs, which have been considered to impart high levels of toxicity. In this study, the toxicity of bare QDs was efficiently quenched by encapsulating them in a biocompatible coat of silica. The toxicity profile and uptake of bare CdS QDs and silica-coated QDs, along with the CD31-labeled, silica-coated CdS QDs on human umbilical vein endothelial cells and glioma cells, were investigated. The effect of size, along with the time-dependent cellular uptake of the nanomaterials, has also been emphasized. Enhanced, high-specificity imaging toward endothelial cell lines in comparison with glioma cells was achieved with CD31 antibody-conjugated nanoparticles. The silica-coated nanomaterials exhibited excellent biocompatibility and greater photostability inside live cells, in addition to possessing an extended shelf life. In vivo biocompatibility and localization study of silica-coated CdS QDs in medaka fish embryos, following direct nanoparticle exposure for 24 hours, authenticated the nanomaterials’ high potential for in vivo imaging, augmented with superior biocompatibility. As expected, CdS QD-treated embryos showed 100% mortality, whereas the silica-coated QD-treated embryos stayed viable and healthy throughout and after the experiments, devoid of any deformities. We provide highly cogent and convincing evidence for such silica-coated QDs as a model nanoparticle in practice, to achieve in vitro and in vivo precision targeted imaging.

Synergistic Targeting of Cancer and Associated Angiogenesis Using Triple‐Targeted Dual‐Drug Silica Nanoformulations for Theragnostics

The targeting and therapeutic efficacy of dye- and dual-drug-loaded silica nanoparticles, functionalized with triple targeting ligands specific towards cancer and neoangiogenesis simultaneously, are discussed. This synergized, high-precision, multitarget concept culminates in an elevated uptake of nanoparticles by cancer and angiogenic cells with amplified proficiency, thereby imparting superior therapeutic efficacy against breast cancer cells and completely disabling the migration and angiogenic sprouting ability of activated endothelial cells. The exceptional multimodal efficiency achieved by this single therapeutic nanoformulation holds promise for the synergistic targeting and treatment of the yet elusive cancer and its related angiogenesis in a single, lethal shot.

PEG coated biocompatible cadmium chalcogenide quantum dots for targeted imaging of cancer cells.

Cancer stands as a leading cause of mortality worldwide and diagnostics of cancer still faces drawbacks. Optical imaging of cancer would allow early diagnosis, evaluation of disease progression and therapy efficiency. To that aim, we have developed highly biocompatible PEG functionalized cadmium chalcogenide based three differently luminescent quantum dots (QDs) (CdS, CdSe and CdTe). Folate targeting scheme was utilized for targeting cancer cell line, MCF-7. We demonstrate the biocompatibility, specificity and efficiency of our nanotool in detection of cancer cells sparing normal cell lines with retained fluorescence of functionalized QDs as parental counterpart. This is the first time report of utilizing three differently fluorescent QDs and we have detailed about the internalization of these materials and time dependent saturation of targeting schemes. We present here the success of utilizing our biocompatible imaging tool for early diagnosis of cancer.

Structurally Distinct Hybrid Polymer/Lipid Nanoconstructs Harboring a Type-I Ribotoxin as Cellular Imaging and Glioblastoma-Directed Therapeutic Vectors

A nanoformulation composed of a ribosome inactivating protein-curcin and a hybrid solid lipid nanovector has been devised against glioblastoma. The structurally distinct nanoparticles were highly compatible to human endothelial and neuronal cells. A sturdy drug release from the particles, recorded upto 72 h, was reflected in the time-dependent toxicity. Folate-targeted nanoparticles were specifically internalized by glioma, imparting superior toxicity and curbed an aggressively proliferating in vitro 3D cancer mass in addition to suppressing the anti-apoptotic survivin and cell matrix protein vinculin. Combined with the imaging potential of the encapsulated dye, the nanovector emanates as a multifunctional anti-cancer system.

Multifunctional Cu 2'x Te Nanocubes Mediated Combination Therapy for Multi-Drug Resistant MDA MB 453

Hypermethylated cancer populations are hard to treat due to their enhanced chemo-resistance, characterized by aberrant methylated DNA subunits. Herein, we report on invoking response from such a cancer lineage to chemotherapy utilizing multifunctional copper telluride (Cu2−XTe) nanocubes (NCs) as photothermal and photodynamic agents, leading to significant anticancer activity. The NCs additionally possessed photoacoustic and X-ray contrast imaging abilities that could serve in image-guided therapeutic studies.

Plasmonic fluorescent CdSe/Cu2S hybrid nanocrystals for multichannel imaging and cancer directed photo-thermal therapy

A simple, crude Jatropha curcas (JC) oil-based synthesis approach, devoid of any toxic phosphine and pyrophoric ligands, to produce size and shape tuned CdSe QDs and a further copper sulfide (Cu2S) encasing is presented. The QDs exhibited excellent photoluminescent properties with narrow band gap emission. Furthermore, the Cu2S shell rendered additional cytocompatibility and stability to the hybrid nanomaterial, which are major factors for translational and clinical applications of QDs. The nanocomposites were PEGylated and folate conjugated to augment their cytoamiability and enhance their specificity towards cancer cells. The nanohybrids possess potentials for visible, near infrared (NIR), photoacoustic (PA) and computed tomography (μCT) imaging. The diverse functionality of the composite was derived from the multi-channel imaging abilities and thermal competence on NIR laser irradiation to specifically actuate the photo-thermal ablation of brain cancer cells.

Anodically Grown Titania Nanotube Induced Cytotoxicity has Genotoxic Origins

Nanoarchitectures of titania (TiO2) have been widely investigated for a number of medical applications including implants and drug delivery. Although titania is extensively used in the food, drug and cosmetic industries, biocompatibility of nanoscale titania is still under careful scrutiny due to the conflicting reports on its interaction with cellular matter. For an accurate insight, we performed in vitro studies on the response of human dermal fibroblast cells toward pristine titania nanotubes fabricated by anodic oxidation. The nanotubes at low concentrations were seen to induce toxicity to the cells, whereas at higher concentrations the cell vitality remained on par with controls. Further investigations revealed an increase in the G0 phase cell population depicting that majority of cells were in the resting rather than active phase. Though the mitochondrial set-up did not exhibit any signs of stress, significantly enhanced reactive oxygen species production in the nuclear compartment was noted. The TiO2 nanotubes were believed to have gained access to the nuclear machinery and caused increased stress leading to genotoxicity. This interesting property of the nanotubes could be utilized to kill cancer cells, especially if the nanotubes are functionalized for a specific target, thus eliminating the need for any chemotherapeutic agents.

FITC/suramin harboring silica nanoformulations for cellular and embryonic imaging/anti-angiogenic theranostics

The in vitro and in vivo uptake, toxicological analysis and anti-angiogenic theranostic prospect of FITC loaded (FITC-Si) and suramin loaded (Sur-Si) silica nanoparticles are presented. FITC/suramin encapsulated silica nanoparticles (NPs) with an average size of <30 nm were synthesized. The uptake of FITC-Si by human umbilical vein endothelial cells (HuVECs) (in vitro) and by early stage medaka embryos (in vivo) was monitored by fluorescence microscopy. The nanoformulation was found to be biocompatible with both cells and embryos. The cytotoxicity analysis, tubulogenesis and migration assay confirmed the anti-angiogenic potential of Sur-Si NPs in HuVECs. The imaging of medaka embryos exposed to FITC-Si, their survival and hatching rate and biocompatibility post FITC-Si exposure were documented. The in vivo drug delivery mediated anti-angiogenic potential of Sur-Si NPs was assessed by survival and hatching rate analysis along with morphological indicators. At higher concentrations, Sur-Si proved lethal to embryos, whereas at lower concentrations it was rather an efficient anti-angiogenic formulation leading to malformed vasculogenesis and inhibited intersegmental vessel formation in an efficient dose dependent mode. The results indicate the potential application of such nanoformulation in future anti-angiogenic theranostics.

Effect of Nanoparticles on Plants with Regard to Physiological Attributes

The growth parameters of plants are influenced by various biotic and abiotic factors. The increased interference of humans with the environment has led to heightened concern over such activities on the living systems, including plants. With tremendous progress being made in the field of engineering, manufacturing, construction, etc., onus has shifted to the possible effects of such developments on the ecosystem. Nanotechnology has emerged as an indispensable tool for the future, with its reach spanning across diverse domains. Such a rapid advance has resulted in the exodus of various types of nanomaterials into the environment. Thus, it becomes essential to understand the imminent effects, either advantageous or deleterious, of these nanomaterials on the living subjects advertently or inadvertently exposed to them. Numerous studies have focused on the effects of such nanomaterials in the nanoparticulate form on the mammalian system, with increased studies on the plant system as well. Due to the complex nature of uptake and translocation mechanism present in plants, it has been relatively difficult to unanimously devise a general dataset of the effects that nanoparticles (NPs) have on them. Research over the past years has documented mostly toxic effects of the NPs, either during the germination stage or with respect to the shoot–root length, while few others have explored the possibilities of utilizing them as carriers for chemicals as herbicides, pesticides, fertilizers, or in some cases genes. There have been numerous contradictory findings with some reports suggesting growth enhancing effects and others observing retarding effects of similar NPs on similar or different plant species. Such contradictions and lack of conclusive observations has slowed down the impact of nanotechnology in the agriculture industry when compared with the medical scene. This scenario demands a comprehensive calibration of the analysis and interpretation of NP–plant interaction and effects thereof from the physiological, biochemical, and photosynthetic level to the molecular level to decisively devise a verdict on the actual effects of nanoparticles on the plant system. This chapter summarizes the research conducted so far in this field and attempts at providing an outlook for the future.