Method: In this investigation, a hybrid nanoparticle that consisted of a DOX-loaded reduced graphene oxide that is stabilized with chitosan (rGOD-HNP) was developed.
Result: The newly developed rGOD-HNP demonstrated high biocompatibility and efficiency in entrapping DOX (~65%) and releasing it in a controlled manner (~50% release in 48 h). Furthermore, it was also demonstrated that rGOD-HNP can intracellularly deliver DOX and more specifically in PC-3 prostate cancer cells.
Conclusion: This delivery tool offers a feasible and viable method to deliver DOX photo-thermally in the treatment of prostate cancer.
METHODS: Dendrimer mediated cancer therapy is advantageous over conventional chemotherapy, radiotherapy and surgical resection due to reduced systemic toxicity, and molecular level cell injury to cancerous mass, for an appreciable survival of the subject. Recently used dendrimer mediated nanotechnology for oncology aims to conquer these challenges. Dendrimers based nano-constructs are having architectures comparable to that of biological vesicles present in the human body.
RESULTS: Operating with dendrimer technology, proffers the exclusive and novel strategies with numerous applications in cancer management involving diagnostics, therapeutics, imaging, and prognostics by sub-molecular interactions. Dendrimers are designed to acquire the benefits of the malignant tumor morphology and characteristics, i.e. leaky vasculature of tumor, expression of specific cell surface antigen, and rapid proliferation.
CONCLUSION: Dendrimers mediated targeted therapy recommends innovatory function equally in diagnostics (imaging, immune-detection) as well as chemotherapy. Currently, dendrimers as nanomedicine has offered a strong assurance and advancement in drastically varying approaches towards cancer imaging and treatment. The present review discusses different approaches for cancer diagnosis and treatment such as, targeted and control therapy, photodynamic therapy, photo-thermal therapy, gene therapy, antiangiogenics therapy, radiotherapy etc.
OBJECTIVE: To address the problem, we first prepared nifedipine loaded sustained releases microsponges and then formulated tablets for effective clinical application and patient compliance.
METHOD: Preparations of microsponges were carried out using different composition of nifedipine and polymer (1:1, 1:2 and 1:3 % molar ratio) using emulsion solvent diffusion technique.
RESULTS: The microsponges with molar ratio 1:3 (formulation code: MF-3) found optimized as revealed by analyzing surface morphology, better powder flow properties (angle of repose; 28.80 ± 0.9, Hausner ratio 1.15 ± 0.2, % compressibility 15.28 ± 0.5% and higher % drug content (80 ± 1.9 %). Different batches of tablets were then formulated incorporating MF-3 microsponges and different proportion (10-50 %) of microcrystalline cellulose and starch as additives. Among tablet formulations, batch composed of 48% of MF-3, 30% of MCC, 20 % of starch and 2 % of talc (TF-33), showed 92.73 ± 2.19 % drug release during 24 hr in vitro release study in comparison to other batches including commercial formulation which was found to be released completely in 20 hr. Further, stability analysis revealed good drug retention of loaded nifedipine as well as consistent in vitro release pattern over a period of 90 days at 40 ºC and 75% RH.
CONCLUSION: The microsponge tablet delivery system was found to be superior concerning the therapeutic advantage as well as manufacturing feasibility of nifedipine.