The effective delivery of target-specific siRNA to the brain by exploiting the exosomes derived from dendritic cells renders the paradigm shift for the prospective use of nanosized exosomes as a delivery system. Although the in vivo targeting strategies by other nanovesicles like liposomes exist, still this novel exosome-based delivery approach holds an inclusive dominance of in vivo security and reduced immunogenicity. Achieving promising exosome-based delivery strategies warrants more desirable exploration of their biology. Over the years, the invention of novel production, characterization, targeting strategies, and cargo loading techniques of exosome improved its ability to reach clinics. Essentially, exosomebased delivery of therapeutics assures to conquer the major hurdles, like delivery of cargos across impermeable biological barriers, like the blood−brain barrier, biocompatibility, increased solubility, metabolic stability, improved circulation time, target specific delivery, and pharmacokinetics, and thereby enhanced the efficacy of loaded therapeutic agents. In this article, we cover the current status of exosome as a delivery vehicle for therapeutics and the challenges that need to be overcome, and we also discuss future perspectives of this exciting field of research to transform it from bench to clinical reality.
There is a pressing need for a ubiquitously expressed antigen or receptor on the tumor surface for successful mitigation of the deleterious side effects of chemotherapy. Phosphatidylserine (PS), normally constrained to the intracellular surface, is exposed on the external surface of tumors and most tumorigenic cell lines. Here we report that a novel PS-targeting liposome, phosphatidylcholine-stearylamine (PC-SA), induced apoptosis and showed potent anticancer effects as a single agent against a majority of cancer cell lines. We experimentally proved that this was due to a strong affinity for and direct interaction of these liposomes with PS. Complexation of the chemotherapeutic drugs doxorubicin and camptothecin in these vesicles demonstrated a manyfold enhancement in the efficacies of the drugs both in vitro and across three advanced tumor models without any signs of toxicity. Both free and drug-loaded liposomes were maximally confined to the tumor site with low tissue concentration. These data indicate that PC-SA is a unique and promising liposome that, alone and as a combination therapy, has anticancer potential across a wide range of cancer types.
Radiolabeled somatostatin analogs have become powerful tools in the diagnosis and staging of neuroendocrine tumors, which express somatostatin receptors. The aim of this study was to evaluate a new somatostatin analog, 6-hydrazinopyridine-3-carboxylic acid-Ser3-octreotate (HYNIC-SATE) radiolabeled with 99mTc, using ethylenediamine-N,N'-diacetic acid and tricine as coligands, to be used as a radiopharmaceutical for the in vivo imaging of somatostatin receptor subtype 2 (SSTR2)-positive tumor. Synthesis of the peptide was carried out on a solid phase using a standard Fmoc strategy. Peptide conjugate affinities for SSTR2 were determined by receptor binding affinity on rat brain cortex and C6 cell membranes. Internalization rate of 99mTc-HYNIC-SATE was studied in SSTR2-expressing C6 cells that were used for intracranial tumor studies in rat brain. A reproducible in vivo C6 glioma model was developed in Sprague-Dawley rat and confirmed by histopathology and immunohistochemical analysis. Biodistribution and imaging properties of this new radiopeptide were also studied in C6 tumor-bearing rats. Radiolabeling was performed at high specific activities, with a radiochemical purity of >96%. Peptide conjugate showed high affinity binding for SSTR2 (HYNIC-SATE IC50=1.60±0.05 n m) and specific internalization into rat C6 cells. After administration of 99mTc-HYNIC-SATE in C6 glioma-bearing rats, a receptor specific uptake of radioactivity was observed in SSTR-positive organs and in the implanted intracranial tumor and rapid excretion from nontarget tissues via kidneys. 99mTc-HYNIC-SATE is a new receptor-specific radiopeptide for targeting SSTR2-positive brain tumor and might be of great promise in the scintigraphy of SSTR2-positive tumors.
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