TY - GEN
T1 - Whole cell imaging based on wide-field interferometric phase microscopy and its application to cardiomyocytes
AU - Shaked, Natan T.
AU - Satterwhite, Lisa L.
AU - Bursac, Nenad
AU - Wax, Adam
PY - 2011/4/29
Y1 - 2011/4/29
N2 - Whole cell imaging is a novel technique using which the time-dependent quantitative phase profiles of live unstained biological cells are analyzed numerically to learn on the cell functionally. Dynamic phase profiles of the sample are first acquired by wide-field digital interferometry (WFDI), a quantitative holographic approach, without the need for scanning or using exogenous contrast agents. The resulting phase profiles are proportional to the multiplication between the cell thickness profile and its integral refractive index profile. However, many morphological parameters, including cell volume and cell force distribution, are based on the cell thickness profile, rather than on its WFDI phase profile. For cells with heterogeneous refractive index structure, more than a single exposure is typically needed to decouple thickness from integral refractive index using the phase profile, with the risk of losing transient acquisition. The presented whole-cell-imaging approach show that the WFDI phase profiles are useful for numerically analyzing cells even in cases where decoupling of thickness and integral refractive index is not possible or desired. We thus define new numerical parameters that directly utilize the WFDI phase profile and demonstrate their usefulness for characterizing contracting cardiomyocytes, cells with complex and highly-dynamic refractive-index structure.
AB - Whole cell imaging is a novel technique using which the time-dependent quantitative phase profiles of live unstained biological cells are analyzed numerically to learn on the cell functionally. Dynamic phase profiles of the sample are first acquired by wide-field digital interferometry (WFDI), a quantitative holographic approach, without the need for scanning or using exogenous contrast agents. The resulting phase profiles are proportional to the multiplication between the cell thickness profile and its integral refractive index profile. However, many morphological parameters, including cell volume and cell force distribution, are based on the cell thickness profile, rather than on its WFDI phase profile. For cells with heterogeneous refractive index structure, more than a single exposure is typically needed to decouple thickness from integral refractive index using the phase profile, with the risk of losing transient acquisition. The presented whole-cell-imaging approach show that the WFDI phase profiles are useful for numerically analyzing cells even in cases where decoupling of thickness and integral refractive index is not possible or desired. We thus define new numerical parameters that directly utilize the WFDI phase profile and demonstrate their usefulness for characterizing contracting cardiomyocytes, cells with complex and highly-dynamic refractive-index structure.
KW - Cardiomyocytes
KW - Cell analysis
KW - Interference microscopy
KW - Phase holography
UR - http://www.scopus.com/inward/record.url?scp=79955150054&partnerID=8YFLogxK
U2 - 10.1117/12.874224
DO - 10.1117/12.874224
M3 - Conference contribution
AN - SCOPUS:79955150054
SN - 9780819484413
T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE
BT - Three-Dimensional and Multidimensional Microscopy
T2 - Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XVIII
Y2 - 24 January 2011 through 27 January 2011
ER -