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4 results on '"Patravale, Vandana"'

1. Quality-by-design Enabled Chitosan Nanoparticles for Antitubercular Therapy: Formulation, Statistical Optimization, and In Vitro Characterization

Author

M. Chogale Manasi, B. Patravale Vandana, P. Kulkarni Savita, and S. Gaikwad Sujay

Subjects
Materials science, Pharmacology (medical), Nanotechnology, Chitosan nanoparticles, General Pharmacology, Toxicology and Pharmaceutics, Quality by Design, In vitro, Characterization (materials science)
Abstract

Background: Tuberculosis (TB) continues to be among the leading causes of high mortality among developing countries. Though a seemingly effective treatment regimen against TB is in place, there has been no significant improvement in the therapeutic rates. This is primarily owing to the high drug doses, their associated side-effects, and prolonged treatment regimen. Discontinuation of therapy due to the severe side effects of the drugs results in the progression of the infection to the more severe drug-resistant TB. Objectives: Reformulation of the current existing anti TB drugs into more efficient dosage forms could be an ideal way out. Nanoformulations have been known to mitigate the side effects of toxic, high-dose drugs. Hence, the current research work involves the formulation of Isoniazid (INH; a first-line anti TB molecule) loaded chitosan nanoparticles for pulmonary administration. Methods: INH loaded chitosan nanoparticles were prepared by ionic gelation method using an anionic crosslinker. Drug-excipient compatibility was evaluated using DSC and FT-IR. The formulation was optimized on the principles of Quality-by-Design using a full factorial design. Results: The obtained nanoparticles were spherical in shape having an average size of 620±10.97 nm and zeta potential +16.87±0.79 mV. Solid-state characterization revealed partial encapsulation and amorphization of INH into the nanoparticulate system. In vitro release study confirmed an extended release of INH from the system. In vitro cell line-based safety and efficacy studies revealed satisfactory results. Conclusion: The developed nanosystem is thus an efficient approach for antitubercular therapy.

Published
2021

2. The Current States, Challenges, Ongoing Efforts, and Future Perspectives of Pharmaceutical Excipients in Pediatric Patients in Each Country and Region

Author

Saito, Jumpei, Salunke, Smita, Agrawal, Anjali, Patravale, Vandana, Pandya, Anjali, Orubu, Samuel, Zhao, Min, Andrews, Gavin P., Petit-Turcotte, Caroline, Landry, Hannah, Mao, Helen, Croker, Alysha, Nakamura, Hidefumi, and Yamatani, Akimasa

Subjects
Pediatrics, Perinatology and Child Health
Abstract

A major hurdle in pediatric formulation development is the lack of safety and toxicity data on some of the commonly used excipients. While the maximum oral safe dose for several kinds of excipients is known in the adult population, the doses in pediatric patients, including preterm neonates, are not established yet due to the lack of evidence-based data. This paper consists of four parts: (1) country-specific perspectives in different parts of the world (current state, challenges in excipients, and ongoing efforts) for ensuring the use of safe excipients, (2) comparing and contrasting the country-specific perspectives, (3) past and ongoing collaborative efforts, and (4) future perspectives on excipients for pediatric formulation. The regulatory process for pharmaceutical excipients has been developed. However, there are gaps between each region where a lack of information and an insufficient regulation process was found. Ongoing efforts include raising issues on excipient exposure, building a region-specific database, and improving excipient regulation; however, there is a lack of evidence-based information on safety for the pediatric population. More progress on clear safety limits, quantitative information on excipients of concern in the pediatric population, and international harmonization of excipients’ regulatory processes for the pediatric population are required.

Published
2022

4. Curcumin Loaded pH-Sensitive Nanoparticles for the Treatment of Colon Cancer

Author

Dandekar Prajakta, Venkatesh Meera, Jain Ratnesh, Patravale Vandana, Kumar Chandan, Samuel Grace, and Subramanian Suresh

Subjects
Curcumin, Cell Survival, Surface Properties, Drug Compounding, Molecular Conformation, Biomedical Engineering, Pharmaceutical Science, Medicine (miscellaneous), Nanoparticle, Antineoplastic Agents, Bioengineering, chemistry.chemical_compound, Nanocapsules, Polymethacrylic Acids, In vivo, Materials Testing, Humans, General Materials Science, MTT assay, Surface charge, Particle Size, Chemistry, Hydrogen-Ion Concentration, Bioavailability, Solvent, Nanomedicine, Treatment Outcome, Colonic Neoplasms, Particle size, Crystallization, HT29 Cells, Nuclear chemistry
Abstract

The investigation was aimed at designing pH-sensitive, polymeric nanoparticles of curcumin, a natural anti-cancer agent, for the treatment of colon cancer. The objective was to enhance the bioavailability of curcumin, simultaneously reducing the required dose through selective targeting to colon. Eudragit S100 was chosen to aid targeting since the polymer dissolves at colonic pH to result in selective colonic release of the entrapped drug. Solvent emulsion-evaporation technique was employed to formulate the nanoparticles. Various process parameters were optimized and the optimized formulation was evaluated for particle size distribution and encapsulation efficiency before subjecting to freeze-drying. The freeze dried product was characterized for particle size, drug content, DSC studies, particle morphology. Anti-cancer potential of the formulation was demonstrated by MTT assay in HT-29 cell line. Nanometric, homogeneous, spherical particles were obtained with encapsulation efficiency of 72%. Freeze-dried nanoparticles exhibited a negative surface charge, drug content of > 99% and presence of drug in amorphous form which may result in possible enhanced absorption. MTT assay demonstrated almost double inhibition of the cancerous cells by nanoparticles, as compared to curcumin alone, at the concentrations tested. Enhanced action may be attributed to size influenced improved cellular uptake, and may result in reduction of overall dose requirement. Results indicate the potential for in vivo studies to establish the clinical application of the formulation.

Published
2009

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