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Visualization of apoptotic cells using scanning acoustic microscopy and high frequency ultrasound

 
: Brand, S.; Czarnota, G.J.; Kolios, M.C.; Weiss, E.C.; Lemor, R.

:

IEEE Ultrasonics, Ferroelectrics, and Frequency Control Society:
IEEE Ultrasonics Symposium 2005. Vol.2 : 18 - 21 September 2005, Rotterdam, The Netherlands
Piscataway, NJ: IEEE Operations Center, 2005
ISBN: 0-7803-9382-1
S.882-885
Ultrasonics Symposium <2005, Rotterdam>
Englisch
Konferenzbeitrag
Fraunhofer IBMT ()

Abstract
The goal of this project is to investigate changes in the acoustical properties of cells undergoing cell death for the development of a method for tissue apoptosis detection using high frequency ultrasound (10-60 MHz). A scanning acoustic microscope (SAM) was used for visualization of individual cells undergoing apoptosis (SASAM, Fraunhofer IBMT, Germany). The use of the SAM offers high resolution (1 m spot size) and therefore enables the exploration of acoustical properties of the cell nucleus. Cells were labeled with H33342 and DIOC 3(5) for visualizing condensed chromatin and membranes in fluorescence microscopy. In addition the same cell lines interrogated microscopically were investigated using high frequency ultrasound Recorded radio frequency (rf) data were analyzed using ultrasound spectroscopy. Integrated backscatter coefficients and attenuation values were computed for two cell lines: HeLa and MDCK. Both cell lines responded to the applied chemotherapeutic age nt by apoptosis, assessed by fluorescence microscopy. Acoustical and optical microscopy using the SASAM system clearly enabled a differentiation between apoptotic cells and cells not responding to the treatment. Apoptotic cells displayed a higher contrast in the acoustic images and were less regular in shape. Optical images of the same cells showed nuclear condensation and membrane disruption. Spectral parameters estimated from rf ultrasound showed a 100% increase in the integrated backscatter coefficients for HeLa and MDCK. Attenuation values were increased by 50% to 70% for both cell lines as a function of treatment time. The results of this investigation provide a better understanding of changes in the acoustical properties of cells with cell death and thus to the development of a non-invasive method for measuring the treatment response of tumors using acoustic waves.

: http://publica.fraunhofer.de/dokumente/N-170221.html