Your search keyword '"Srabani Kar"' showing total 5 results

1. Microfluidic mechanoporation for cellular delivery and analysis

Author

Pulasta Chakrabarty, Pallavi Gupta, Kavitha Illath, Srabani Kar, Moeto Nagai, Fan-Gang Tseng, and Tuhin Subhra Santra

Subjects

Microfluidics, Mechanoporation, Cellular delivery, Transfection efficiency, Cell viability, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Highly efficient intracellular delivery strategies are essential for developing therapeutic, diagnostic, biological, and various biomedical applications. The recent advancement of micro/nanotechnology has focused numerous researches towards developing microfluidic device-based strategies due to the associated high throughput delivery, cost-effectiveness, robustness, and biocompatible nature. The delivery strategies can be carrier-mediated or membrane disruption-based, where membrane disruption methods find popularity due to reduced toxicity, enhanced delivery efficiency, and cell viability. Among all of the membrane disruption techniques, the mechanoporation strategies are advantageous because of no external energy source required for membrane deformation, thereby achieving high delivery efficiencies and increased cell viability into different cell types with negligible toxicity. The past two decades have consequently seen a tremendous boost in mechanoporation-based research for intracellular delivery and cellular analysis. This article provides a brief review of the most recent developments on microfluidic-based mechanoporation strategies such as microinjection, nanoneedle arrays, cell-squeezing, and hydroporation techniques with their working principle, device fabrication, cellular delivery, and analysis. Moreover, a brief discussion of the different mechanoporation strategies integrated with other delivery methods has also been provided. Finally, the advantages, limitations, and future prospects of this technique are discussed compared to other intracellular delivery techniques.

Published

2022

2. Microfluidic platforms for single neuron analysis

Author

Pallavi Gupta, Ashwini Shinde, Kavitha Illath, Srabani Kar, Moeto Nagai, Fan-Gang Tseng, and Tuhin Subhra Santra

Subjects

Single neuron analysis, Microfluidic devices, Microelectrode array, Single cell analysis, Single neuron dynamics, Omics, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Single-neuron actions are the basis of brain function, as clinical sequelae, neuronal dysfunction or failure for most of the central nervous system (CNS) diseases and injuries can be identified via tracing single-neurons. The bulk analysis methods tend to miscue critical information by assessing the population-averaged outcomes. However, its primary requisite in neuroscience to analyze single-neurons and to understand dynamic interplay of neurons and their environment. Microfluidic systems enable precise control over nano-to femto-liter volumes via adjusting device geometry, surface characteristics, and flow-dynamics, thus facilitating a well-defined micro-environment with spatio-temporal control for single-neuron analysis. The microfluidic platform not only offers a comprehensive landscape to study brain cell diversity at the level of transcriptome, genome, and/or epigenome of individual cells but also has a substantial role in deciphering complex dynamics of brain development and brain-related disorders. In this review, we highlight recent advances of microfluidic devices for single-neuron analysis, i.e., single-neuron trapping, single-neuron dynamics, single-neuron proteomics, single-neuron transcriptomics, drug delivery at the single-neuron level, single axon guidance, and single-neuron differentiation. Moreover, we also emphasize limitations and future challenges of single-neuron analysis by focusing on key performances of throughput and multiparametric activity analysis on microfluidic platforms.

Published

2022

3. Algal genomics tools: technological updates and progress

Author

Niwas Kumar, Srabani Kar, Amit Srivastava, Chiranjib Banerjee, and Pratyoosh Shukla

Published

2023

4. Contributors

Author

Tarun Kumar Barik, Abid Bhat, Ramesh Chandra, Vivekanand Chatap, Saravana Babu Chidambaram, Jørn B. Christensen, Rolf Daniels, Xavier Delgadillo, Koyel Dey, Namdev Dhas, Sunil Kumar Dubey, Sachin Dubey, Mysore Prakash Gowrav, Siddhanth Hejmady, Padamati Jagadeeswari, Paul Joyce, Srabani Kar, null Kavitha, Aljoscha Koenneke, Amogh Kumar, Arehally Marappa Mahalakshmi, Tahlia R. Meola, L. Mohan, Srinivas Mutalik, Francis Kamau Mwiiri, Moeto Nagai, Abhijeet Pandey, Kamla Pathak, Marcel Pourasghar, Clive A. Prestidge, Vamshi Krishna Rapalli, Kamal Singh Rathore, Bipul Ray, Meena Kishore Sakharkar, Tuhin Subhra Santra, Marc Schneider, Hayley B. Schultz, Javad Sharifi-Rad, Pallavi Shinde, Debjani Singh, Gautam Singhvi, Tuladhar Sunanda, Akhilesh Kumar Tewari, and Philippe Wuthrich

Published

2020

5. Physical approaches for drug delivery

Author

T. K. Barik, Javad Sharifi-Rad, Koyel Dey, Tuhin Subhra Santra, Moeto Nagai, Amogh Kumar, Pallavi Shinde, Kavitha, L. Mohan, and Srabani Kar

Subjects

Low toxicity, Hydrophilic membrane, Computer science, Electroporation, Genetic enhancement, Drug delivery, Computational biology, Gene gun, Viral vector

Abstract

Delivery of exogenous materials or cargo such as drugs, proteins, peptides, and nucleic acids into cells is a vital segment in molecular and cellular biology for potential cellular therapy and drug-discovery applications contributing toward personalization of medicine. Over the years, drug-delivery techniques have been developed in order to gain more control over the drug dosage, targeted delivery, and to minimize side effects. The major drug-delivery techniques can be classified as viral, chemical, and physical methods. Viral vectors are prominently used for gene therapy; however, they are cell-specific and have an immune response with high toxicity. Chemical methods are often limited by the low efficiency of plasmid delivery into different cell types due to plasmid degradation and toxicity. Considering these limitations, different physical methods such as photoporation, gene gun, hydrodynamic injection, electroporation, and mechanoporation, etc., are being widely developed for highly efficient cargo delivery with low toxicity. These methods are able to create transient hydrophilic membrane pores to deliver cargos into cells using different physical energies. Currently, ex vivo cargo delivery is widely studied while few in vivo applications have been developed. Concerning several obstacles to cargo delivery into cells, this chapter mainly focuses on different physical drug-delivery techniques such as electroporation, optoporation, mechanoporation, magnetoporation, and hybrid techniques along with their working mechanisms, advantages, disadvantages, and limitations. An insight into the future prospects and real-time applications of these techniques is also discussed.

Published

2020