Your search keyword '"Tarit Mukhopadhyay"' showing total 4 results

1. Vaccine Technology VI: Innovative and integrated approaches in vaccine development

Author

Yvonne Genzel, Tarit Mukhopadhyay, Linda H.L. Lua, Manon M.J. Cox, and Laura A. Palomares

Subjects

Vaccines, Engineering, General Veterinary, General Immunology and Microbiology, business.industry, Public Health, Environmental and Occupational Health, Congresses as Topic, Communicable Diseases, Engineering management, Infectious Diseases, Communicable Disease Control, Animals, Humans, Molecular Medicine, business

Published

2018

2. Vaccine Technology VII: Beyond the 'decade of vaccines'

Author

Linda H.L. Lua, Amine Kamen, and Tarit Mukhopadhyay

Subjects

medicine.medical_specialty, Vaccines, General Veterinary, General Immunology and Microbiology, business.industry, Public Health, Environmental and Occupational Health, MEDLINE, Infectious Diseases, Family medicine, Molecular Medicine, Medicine, Animals, Humans, Public Health, business, Biotechnology

Published

2019

3. High throughput quantification of capsular polysaccharides for multivalent vaccines using precipitation with a cationic surfactant

Author

Aaron Noyes, Austin W. Boesch, Tarit Mukhopadhyay, Nigel J. Titchener-Hooker, Ranga Godavarti, and Jonathan Coffman

Subjects

Anionic capsular polysaccharides, Polysaccharide, Absorbance, Surface-Active Agents, Pulmonary surfactant, Polysaccharides, Cations, Immunology and Microbiology(all), Chemical Precipitation, Monosaccharide, Sugar quantitation, High throughput process development, Vaccine Potency, chemistry.chemical_classification, General Veterinary, General Immunology and Microbiology, Cetrimonium, Hexadecyltrimethylammonium bromide, Cationic polymerization, Public Health, Environmental and Occupational Health, veterinary(all), High-Throughput Screening Assays, Titer, Infectious Diseases, chemistry, Biochemistry, Spectrophotometry, Ionic strength, Bacterial Vaccines, Phosphodiester bond, Cetrimonium Compounds, Molecular Medicine, Vaccine

Abstract

The increasing requirement for multivalent vaccines containing diverse capsular polysaccharides has created an unmet need for a fast and straightforward assay for polysaccharide titer. We describe a novel and robust assay for the quantitation of anionic capsular polysaccharides. The binding of hexadecyltrimethyammonium bromide (Hb) to anionic capsular polysaccharides results in a precipitation reaction wherein the suspension turbidity is proportional to polysaccharide titer. The turbidity can be quickly measured as absorbance across a range of wavelengths that resolve scattering light. Carbohydrates comprised of repeating units of one to seven monosaccharides with phosphodiester groups, uronic acids, and sialic acids all reacted strongly and there does not appear to be specificity with respect to the particular anionic moiety. The assay is compatible with an array of common buffers across a pH range of 3.0–8.75 and with NaCl concentration exceeding 400 mM. Interference from DNA can be eliminated with a short incubation step with DNase. With these treatments, the assay has been employed in samples as complex as fermentation broth. A two-log dynamic range has been established with a mean relative standard deviation less than 10% across this range although inferior performance has been observed in fermentation broth. The precipitation assay enables the rapid quantitation of anionic polysaccharides. The resulting procedure can robustly measure the titer of myriad anionic capsular polysaccharides (CPS) in 96 samples in less than 30 min using low toxicity reagents and routine laboratory equipment. This development will greatly reduce the effort required to measure polysaccharide titer and yield during process development of polysaccharide vaccines.

Published

2013

4. Quantitative high throughput analytics to support polysaccharide production process development

Author

Aaron Noyes, Nigel J. Titchener-Hooker, Tarit Mukhopadhyay, Jonathan Coffman, and Ranga Godavarti

Subjects

Process (engineering), Computer science, Carbohydrates, Quality by Design, Sample volume, Polysaccharides, Robustness (computer science), Immunology and Microbiology(all), Technology, Pharmaceutical, High throughput process development, Process engineering, Throughput (business), Vaccines, Downstream processing, General Veterinary, General Immunology and Microbiology, business.industry, Public Health, Environmental and Occupational Health, Usability, veterinary(all), Capsular polysaccharides, High-Throughput Screening Assays, Biotechnology, Infectious Diseases, Phenol sulphuric acid assay, Sugar quantification, Analytics, Endotoxin assays, Molecular Medicine, business

Abstract

The rapid development of purification processes for polysaccharide vaccines is constrained by a lack of analytical tools current technologies for the measurement of polysaccharide recovery and process-related impurity clearance are complex, time-consuming, and generally not amenable to high throughput process development (HTPD). HTPD is envisioned to be central to the improvement of existing polysaccharide manufacturing processes through the identification of critical process parameters that potentially impact the quality attributes of the vaccine and to the development of de novo processes for clinical candidates, across the spectrum of downstream processing. The availability of a fast and automated analytics platform will expand the scope, robustness, and evolution of Design of Experiment (DOE) studies.This paper details recent advances in improving the speed, throughput, and success of in-process analytics at the micro-scale. Two methods, based on modifications of existing procedures, are described for the rapid measurement of polysaccharide titre in microplates without the need for heating steps. A simplification of a commercial endotoxin assay is also described that features a single measurement at room temperature. These assays, along with existing assays for protein and nucleic acids are qualified for deployment in the high throughput screening of polysaccharide feedstreams. Assay accuracy, precision, robustness, interference, and ease of use are assessed and described. In combination, these assays are capable of measuring the product concentration and impurity profile of a microplate of 96 samples in less than one day. This body of work relies on the evaluation of a combination of commercially available and clinically relevant polysaccharides to ensure maximum versatility and reactivity of the final assay suite. Together, these advancements reduce overall process time by up to 30-fold and significantly reduce sample volume over current practices. The assays help build an analytical foundation to support the advent of HTPD technology for polysaccharide vaccines. It is envisaged that this will lead to an expanded use of Quality by Design (QbD) studies in vaccine process development.