3D quantitative phase imaging via the transport of intensity equation: applications for studying red blood cells

Anusha Pillai; Saritha Kamath U; Sushma Belurkar; Anand K. Asundi; Ajeetkumar Patil

doi:10.1039/d5ra01071c

3D quantitative phase imaging via the transport of intensity equation: applications for studying red blood cells

Anusha Pillai, Saritha Kamath U^*, Sushma Belurkar, Anand K. Asundi, Ajeetkumar Patil^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Quantitative phase imaging (QPI) is a versatile, label-free technique for investigating the morphological and biophysical properties of biological cells. Here, we used 3D QPI to study the behavior of human red blood cells (RBCs) across a saline gradient from 1% to 0%. RBCs are osmotic-sensitive, and their phase profiles provide important measures of membrane integrity, shape transitions, and lumen hemolysis. Deducing phase alterations across each concentration allowed us to quantify the osmotic impacts on RBC morphology and assess the corresponding biophysical changes. Other studies on osmotic shock contributed to understanding the behavior of RBCs in hypotonic environments and their applications in hematological and biomedical fields.

Original language	English
Pages (from-to)	11655-11661
Number of pages	7
Journal	RSC Advances
Volume	15
Issue number	15
DOIs	https://doi.org/10.1039/d5ra01071c
Publication status	Published - 14-04-2025

All Science Journal Classification (ASJC) codes

General Chemistry
General Chemical Engineering

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abstract = "Quantitative phase imaging (QPI) is a versatile, label-free technique for investigating the morphological and biophysical properties of biological cells. Here, we used 3D QPI to study the behavior of human red blood cells (RBCs) across a saline gradient from 1% to 0%. RBCs are osmotic-sensitive, and their phase profiles provide important measures of membrane integrity, shape transitions, and lumen hemolysis. Deducing phase alterations across each concentration allowed us to quantify the osmotic impacts on RBC morphology and assess the corresponding biophysical changes. Other studies on osmotic shock contributed to understanding the behavior of RBCs in hypotonic environments and their applications in hematological and biomedical fields.",

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3D quantitative phase imaging via the transport of intensity equation: applications for studying red blood cells

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