Your search keyword '"Gabriel Popescu"' showing total 14 results

1. Quantifying myelin content in brain tissue using color Spatial Light Interference Microscopy (cSLIM).

Author

Michael Fanous, Megan P Caputo, Young Jae Lee, Laurie A Rund, Catherine Best-Popescu, Mikhail E Kandel, Rodney W Johnson, Tapas Das, Matthew J Kuchan, and Gabriel Popescu

Subjects

Medicine, Science

Abstract

Deficient myelination of the brain is associated with neurodevelopmental delays, particularly in high-risk infants, such as those born small in relation to their gestational age (SGA). New methods are needed to further study this condition. Here, we employ Color Spatial Light Interference Microscopy (cSLIM), which uses a brightfield objective and RGB camera to generate pathlength-maps with nanoscale sensitivity in conjunction with a regular brightfield image. Using tissue sections stained with Luxol Fast Blue, the myelin structures were segmented from a brightfield image. Using a binary mask, those portions were quantitatively analyzed in the corresponding phase maps. We first used the CLARITY method to remove tissue lipids and validate the sensitivity of cSLIM to lipid content. We then applied cSLIM to brain histology slices. These specimens are from a previous MRI study, which demonstrated that appropriate for gestational age (AGA) piglets have increased internal capsule myelination (ICM) compared to small for gestational age (SGA) piglets and that a hydrolyzed fat diet improved ICM in both. The identity of samples was blinded until after statistical analyses.

Published

2020

2. Disorder strength measured by quantitative phase imaging as intrinsic cancer marker in fixed tissue biopsies.

Author

Masanori Takabayashi, Hassaan Majeed, Andre Kajdacsy-Balla, and Gabriel Popescu

Subjects

Medicine, Science

Abstract

Tissue refractive index provides important information about morphology at the nanoscale. Since the malignant transformation involves both intra- and inter-cellular changes in the refractive index map, the tissue disorder measurement can be used to extract important diagnosis information. Quantitative phase imaging (QPI) provides a practical means of extracting this information as it maps the optical path-length difference (OPD) across a tissue sample with sub-wavelength sensitivity. In this work, we employ QPI to compare the tissue disorder strength between benign and malignant breast tissue histology samples. Our results show that disease progression is marked by a significant increase in the disorder strength. Since our imaging system can be added as an upgrading module to an existing microscope, we anticipate that it can be integrated easily in the pathology work flow.

Published

2018

3. Spatiotemporal characterization of a fibrin clot using quantitative phase imaging.

Author

Rajshekhar Gannavarpu, Basanta Bhaduri, Krishnarao Tangella, and Gabriel Popescu

Subjects

Medicine, Science

Abstract

Studying the dynamics of fibrin clot formation and its morphology is an important problem in biology and has significant impact for several scientific and clinical applications. We present a label-free technique based on quantitative phase imaging to address this problem. Using quantitative phase information, we characterized fibrin polymerization in real-time and present a mathematical model describing the transition from liquid to gel state. By exploiting the inherent optical sectioning capability of our instrument, we measured the three-dimensional structure of the fibrin clot. From this data, we evaluated the fractal nature of the fibrin network and extracted the fractal dimension. Our non-invasive and speckle-free approach analyzes the clotting process without the need for external contrast agents.

Published

2014

4. Highly sensitive quantitative imaging for monitoring single cancer cell growth kinetics and drug response.

Author

Mustafa Mir, Anna Bergamaschi, Benita S Katzenellenbogen, and Gabriel Popescu

Subjects

Medicine, Science

Abstract

The detection and treatment of cancer has advanced significantly in the past several decades, with important improvements in our understanding of the fundamental molecular and genetic basis of the disease. Despite these advancements, drug-screening methodologies have remained essentially unchanged since the introduction of the in vitro human cell line screen in 1990. Although the existing methods provide information on the overall effects of compounds on cell viability, they are restricted by bulk measurements, large sample sizes, and lack capability to measure proliferation kinetics at the individual cell level. To truly understand the nature of cancer cell proliferation and to develop personalized adjuvant therapies, there is a need for new methodologies that provide quantitative information to monitor the effect of drugs on cell growth as well as morphological and phenotypic changes at the single cell level. Here we show that a quantitative phase imaging modality known as spatial light interference microscopy (SLIM) addresses these needs and provides additional advantages over existing proliferation assays. We demonstrate these capabilities through measurements on the effects of the hormone estradiol and the antiestrogen ICI182,780 (Faslodex) on the growth of MCF-7 breast cancer cells. Along with providing information on changes in the overall growth, SLIM provides additional biologically relevant information. For example, we find that exposure to estradiol results in rapidly growing cells with lower dry mass than the control population. Subsequently blocking the estrogen receptor with ICI results in slower growing cells, with lower dry masses than the control. This ability to measure changes in growth kinetics in response to environmental conditions provides new insight on growth regulation mechanisms. Our results establish the capabilities of SLIM as an advanced drug screening technology that provides information on changes in proliferation kinetics at the cellular level with greater sensitivity than any existing method.

Published

2014

5. Cardiomyocyte imaging using real-time spatial light interference microscopy (SLIM).

Author

Basanta Bhaduri, David Wickland, Ru Wang, Vincent Chan, Rashid Bashir, and Gabriel Popescu

Subjects

Medicine, Science

Abstract

Spatial light interference microscopy (SLIM) is a highly sensitive quantitative phase imaging method, which is capable of unprecedented structure studies in biology and beyond. In addition to the π/2 shift introduced in phase contrast between the scattered and unscattered light from the sample, 4 phase shifts are generated in SLIM, by increments of π/2 using a reflective liquid crystal phase modulator (LCPM). As 4 phase shifted images are required to produce a quantitative phase image, the switching speed of the LCPM and the acquisition rate of the camera limit the acquisition rate and, thus, SLIM's applicability to highly dynamic samples. In this paper we present a fast SLIM setup which can image at a maximum rate of 50 frames per second and provide in real-time quantitative phase images at 50/4 = 12.5 frames per second. We use a fast LCPM for phase shifting and a fast scientific-grade complementary metal oxide semiconductor (sCMOS) camera (Andor) for imaging. We present the dispersion relation, i.e. decay rate vs. spatial mode, associated with dynamic beating cardiomyocyte cells from the quantitative phase images obtained with the real-time SLIM system.

Published

2013

6. Real time blood testing using quantitative phase imaging.

Author

Hoa V Pham, Basanta Bhaduri, Krishnarao Tangella, Catherine Best-Popescu, and Gabriel Popescu

Subjects

Medicine, Science

Abstract

We demonstrate a real-time blood testing system that can provide remote diagnosis with minimal human intervention in economically challenged areas. Our instrument combines novel advances in label-free optical imaging with parallel computing. Specifically, we use quantitative phase imaging for extracting red blood cell morphology with nanoscale sensitivity and NVIDIA's CUDA programming language to perform real time cellular-level analysis. While the blood smear is translated through focus, our system is able to segment and analyze all the cells in the one megapixel field of view, at a rate of 40 frames/s. The variety of diagnostic parameters measured from each cell (e.g., surface area, sphericity, and minimum cylindrical diameter) are currently not available with current state of the art clinical instruments. In addition, we show that our instrument correctly recovers the red blood cell volume distribution, as evidenced by the excellent agreement with the cell counter results obtained on normal patients and those with microcytic and macrocytic anemia. The final data outputted by our instrument represent arrays of numbers associated with these morphological parameters and not images. Thus, the memory necessary to store these data is of the order of kilobytes, which allows for their remote transmission via, for example, the cellular network. We envision that such a system will dramatically increase access for blood testing and furthermore, may pave the way to digital hematology.

Published

2013

7. Visualizing Escherichia coli sub-cellular structure using sparse deconvolution Spatial Light Interference Tomography.

Author

Mustafa Mir, S Derin Babacan, Michael Bednarz, Minh N Do, Ido Golding, and Gabriel Popescu

Subjects

Medicine, Science

Abstract

Studying the 3D sub-cellular structure of living cells is essential to our understanding of biological function. However, tomographic imaging of live cells is challenging mainly because they are transparent, i.e., weakly scattering structures. Therefore, this type of imaging has been implemented largely using fluorescence techniques. While confocal fluorescence imaging is a common approach to achieve sectioning, it requires fluorescence probes that are often harmful to the living specimen. On the other hand, by using the intrinsic contrast of the structures it is possible to study living cells in a non-invasive manner. One method that provides high-resolution quantitative information about nanoscale structures is a broadband interferometric technique known as Spatial Light Interference Microscopy (SLIM). In addition to rendering quantitative phase information, when combined with a high numerical aperture objective, SLIM also provides excellent depth sectioning capabilities. However, like in all linear optical systems, SLIM's resolution is limited by diffraction. Here we present a novel 3D field deconvolution algorithm that exploits the sparsity of phase images and renders images with resolution beyond the diffraction limit. We employ this label-free method, called deconvolution Spatial Light Interference Tomography (dSLIT), to visualize coiled sub-cellular structures in E. coli cells which are most likely the cytoskeletal MreB protein and the division site regulating MinCDE proteins. Previously these structures have only been observed using specialized strains and plasmids and fluorescence techniques. Our results indicate that dSLIT can be employed to study such structures in a practical and non-invasive manner.

Published

2012

8. Quantifying myelin content in brain tissue using color Spatial Light Interference Microscopy (cSLIM)

Author

Gabriel Popescu, Matthew J. Kuchan, Mikhail E. Kandel, Young Jae Lee, Catherine Best-Popescu, Laurie A. Rund, Megan P. Caputo, Rodney W. Johnson, Michael J. Fanous, and Tapas Das

Subjects

Male, Internal capsule, Swine, Physiology, Biochemistry, Quantitative Biology - Quantitative Methods, 01 natural sciences, Luxol fast blue stain, Diagnostic Radiology, Bright Field Microscopy, Myelin, Nerve Fibers, 0302 clinical medicine, Animal Cells, Microscopy, Medicine and Health Sciences, Quantitative Methods (q-bio.QM), Myelin Sheath, Mammals, Neurons, 0303 health sciences, Multidisciplinary, Radiology and Imaging, Eukaryota, Light Microscopy, Brain, Gestational age, Cameras, Magnetic Resonance Imaging, Lipids, medicine.anatomical_structure, Physiological Parameters, Optical Equipment, Vertebrates, Engineering and Technology, Medicine, Female, Cellular Types, Research Article, Imaging Techniques, Science, Equipment, Gestational Age, Biology, Research and Analysis Methods, 010309 optics, 03 medical and health sciences, Diagnostic Medicine, 0103 physical sciences, medicine, Animals, Microscopy, Interference, Nutrition, 030304 developmental biology, Body Weight, Bright-field microscopy, Organisms, Biology and Life Sciences, Histology, Cell Biology, medicine.disease, Axons, Diet, Animals, Newborn, FOS: Biological sciences, Cellular Neuroscience, Amniotes, Small for gestational age, RGB color model, Zoology, 030217 neurology & neurosurgery, Neuroscience, Biomedical engineering

Abstract

Deficient myelination of the brain is associated with neurodevelopmental delays, particularly in high-risk infants, such as those born small in relation to their gestational age (SGA). New methods are needed to further study this condition. Here, we employ Color Spatial Light Interference Microscopy (cSLIM), which uses a brightfield objective and RGB camera to generate pathlength-maps with nanoscale sensitivity in conjunction with a regular brightfield image. Using tissue sections stained with Luxol Fast Blue, the myelin structures were segmented from a brightfield image. Using a binary mask, those portions were quantitatively analyzed in the corresponding phase maps. We first used the CLARITY method to remove tissue lipids and validate the sensitivity of cSLIM to lipid content. We then applied cSLIM to brain histology slices. These specimens are from a previous MRI study, which demonstrated that appropriate for gestational age (AGA) piglets have increased internal capsule myelination (ICM) compared to small for gestational age (SGA) piglets and that a hydrolyzed fat diet improved ICM in both. The identity of samples was blinded until after statistical analyses.

Published

2020

9. Disorder strength measured by quantitative phase imaging as intrinsic cancer marker in fixed tissue biopsies

Author

Hassaan Majeed, Andre Kajdacsy-Balla, Gabriel Popescu, and Masanori Takabayashi

Subjects

0301 basic medicine, Tissue Fixation, Microscope, Light, Biopsy, lcsh:Medicine, Optical Analysis, 01 natural sciences, law.invention, Malignant transformation, Scattering, law, Geoinformatics, Medicine and Health Sciences, lcsh:Science, Cancer marker, Microscopy, Multidisciplinary, Breast tissue, Geography, medicine.diagnostic_test, Refractive Index, Physics, Electromagnetic Radiation, Spatial Autocorrelation, Optical Lenses, Oncology, Optical Equipment, Physical Sciences, Phase imaging, Engineering and Technology, Work flow, Female, Anatomy, Research Article, Computer and Information Sciences, Histology, Materials science, Equipment, Breast Neoplasms, Surgical and Invasive Medical Procedures, Research and Analysis Methods, 010309 optics, 03 medical and health sciences, Diagnostic Medicine, Image Interpretation, Computer-Assisted, 0103 physical sciences, Cancer Detection and Diagnosis, medicine, Humans, Chemical Characterization, lcsh:R, Light Scattering, Reproductive System, Biology and Life Sciences, 030104 developmental biology, Earth Sciences, lcsh:Q, Breast Tissue, Biomarkers, Biomedical engineering

Abstract

Tissue refractive index provides important information about morphology at the nanoscale. Since the malignant transformation involves both intra- and inter-cellular changes in the refractive index map, the tissue disorder measurement can be used to extract important diagnosis information. Quantitative phase imaging (QPI) provides a practical means of extracting this information as it maps the optical path-length difference (OPD) across a tissue sample with sub-wavelength sensitivity. In this work, we employ QPI to compare the tissue disorder strength between benign and malignant breast tissue histology samples. Our results show that disease progression is marked by a significant increase in the disorder strength. Since our imaging system can be added as an upgrading module to an existing microscope, we anticipate that it can be integrated easily in the pathology work flow.

Published

2018

10. Cardiomyocyte Imaging Using Real-Time Spatial Light Interference Microscopy (SLIM)

Author

Ru Wang, Basanta Bhaduri, David Wickland, Vincent Chan, Gabriel Popescu, and Rashid Bashir

Subjects

Anatomy and Physiology, Time Factors, Light, Image Processing, lcsh:Medicine, Transportation, 02 engineering and technology, 01 natural sciences, Biochemistry, Light scattering, Switching time, Rats, Sprague-Dawley, Engineering, Dispersion relation, Microscopy, Molecular Cell Biology, Cell Mechanics, Biomechanics, Myocytes, Cardiac, lcsh:Science, Physics, Multidisciplinary, Animal Models, 021001 nanoscience & nanotechnology, Interference microscopy, Molecular Imaging, Cellular Types, 0210 nano-technology, Phase modulation, Research Article, Phase (waves), Biophysics, 010309 optics, Optics, Model Organisms, 0103 physical sciences, Animals, Biology, business.industry, Mechanical Engineering, lcsh:R, Biological Transport, Frame rate, Rats, Metabolism, Animals, Newborn, Signal Processing, Rat, lcsh:Q, business

Abstract

Spatial light interference microscopy (SLIM) is a highly sensitive quantitative phase imaging method, which is capable of unprecedented structure studies in biology and beyond. In addition to the π/2 shift introduced in phase contrast between the scattered and unscattered light from the sample, 4 phase shifts are generated in SLIM, by increments of π/2 using a reflective liquid crystal phase modulator (LCPM). As 4 phase shifted images are required to produce a quantitative phase image, the switching speed of the LCPM and the acquisition rate of the camera limit the acquisition rate and, thus, SLIM's applicability to highly dynamic samples. In this paper we present a fast SLIM setup which can image at a maximum rate of 50 frames per second and provide in real-time quantitative phase images at 50/4 = 12.5 frames per second. We use a fast LCPM for phase shifting and a fast scientific-grade complementary metal oxide semiconductor (sCMOS) camera (Andor) for imaging. We present the dispersion relation, i.e. decay rate vs. spatial mode, associated with dynamic beating cardiomyocyte cells from the quantitative phase images obtained with the real-time SLIM system.

Published

2013

11. Visualizing Escherichia coli sub-cellular structure using sparse deconvolution Spatial Light Interference Tomography

Author

Ido Golding, Minh N. Do, S. Derin Babacan, Mustafa Mir, Gabriel Popescu, and Michael Bednarz

Subjects

Fluorescence-lifetime imaging microscopy, Visible Light, Light, Applied Microbiology, Image Processing, lcsh:Medicine, Bioinformatics, 01 natural sciences, Microbiology, Light scattering, 010309 optics, 03 medical and health sciences, Model Organisms, Engineering, Microbial Physiology, 0103 physical sciences, Microscopy, Fluorescence microscope, Bacterial Physiology, lcsh:Science, Tomography, Biology, Condensed-Matter Physics, 030304 developmental biology, Fluorescent Dyes, Physics, 0303 health sciences, Escherichia Coli, Multidisciplinary, Tomographic reconstruction, Electromagnetic Radiation, lcsh:R, Bacteriology, Optics, Numerical aperture, Bacterial Pathogens, Signal Processing, Prokaryotic Models, lcsh:Q, Deconvolution, Biological system, Subcellular Fractions, Research Article, Biotechnology

Abstract

Studying the 3D sub-cellular structure of living cells is essential to our understanding of biological function. However, tomographic imaging of live cells is challenging mainly because they are transparent, i.e., weakly scattering structures. Therefore, this type of imaging has been implemented largely using fluorescence techniques. While confocal fluorescence imaging is a common approach to achieve sectioning, it requires fluorescence probes that are often harmful to the living specimen. On the other hand, by using the intrinsic contrast of the structures it is possible to study living cells in a non-invasive manner. One method that provides high-resolution quantitative information about nanoscale structures is a broadband interferometric technique known as Spatial Light Interference Microscopy (SLIM). In addition to rendering quantitative phase information, when combined with a high numerical aperture objective, SLIM also provides excellent depth sectioning capabilities. However, like in all linear optical systems, SLIM's resolution is limited by diffraction. Here we present a novel 3D field deconvolution algorithm that exploits the sparsity of phase images and renders images with resolution beyond the diffraction limit. We employ this label-free method, called deconvolution Spatial Light Interference Tomography (dSLIT), to visualize coiled sub-cellular structures in E. coli cells which are most likely the cytoskeletal MreB protein and the division site regulating MinCDE proteins. Previously these structures have only been observed using specialized strains and plasmids and fluorescence techniques. Our results indicate that dSLIT can be employed to study such structures in a practical and non-invasive manner.

Published

2012

12. Spatiotemporal Characterization of a Fibrin Clot Using Quantitative Phase Imaging

Author

Krishnarao Tangella, Gabriel Popescu, Rajshekhar Gannavarpu, and Basanta Bhaduri

Subjects

Blood Platelets, Diagnostic Imaging, Optical sectioning, Imaging Techniques, lcsh:Medicine, Research and Analysis Methods, Bioinformatics, Fractal dimension, Phase Transition, Fibrin, Polymerization, Interference Microscopy, Fractal, Medicine and Health Sciences, Humans, lcsh:Science, Blood Coagulation, Optical Microscopy, Microscopy, Multidisciplinary, biology, Chemistry, lcsh:R, Light Microscopy, Hematology, Models, Theoretical, Clot formation, Blood Coagulation Factors, Characterization (materials science), Phase imaging, biology.protein, lcsh:Q, Gel state, Research Article, circulatory and respiratory physiology, Biomedical engineering

Abstract

Studying the dynamics of fibrin clot formation and its morphology is an important problem in biology and has significant impact for several scientific and clinical applications. We present a label-free technique based on quantitative phase imaging to address this problem. Using quantitative phase information, we characterized fibrin polymerization in real-time and present a mathematical model describing the transition from liquid to gel state. By exploiting the inherent optical sectioning capability of our instrument, we measured the three-dimensional structure of the fibrin clot. From this data, we evaluated the fractal nature of the fibrin network and extracted the fractal dimension. Our non-invasive and speckle-free approach analyzes the clotting process without the need for external contrast agents.

Published

2014

13. Highly Sensitive Quantitative Imaging for Monitoring Single Cancer Cell Growth Kinetics and Drug Response

Author

Gabriel Popescu, Mustafa Mir, Benita S. Katzenellenbogen, and Anna Bergamaschi

Subjects

lcsh:Medicine, Estrogen receptor, Engineering, Single-cell analysis, Neoplasms, Molecular Cell Biology, Breast Tumors, Basic Cancer Research, Cluster Analysis, Precision Medicine, lcsh:Science, Fulvestrant, Image Cytometry, Multidisciplinary, Estradiol, Obstetrics and Gynecology, 3. Good health, Receptors, Estrogen, Oncology, MCF-7 Cells, Medicine, Colorimetry, Single-Cell Analysis, Research Article, Biotechnology, Biomedical Engineering, Bioengineering, Computational biology, Biology, Cell Growth, Medical Devices, Breast Cancer, medicine, Humans, Microscopy, Interference, Viability assay, Cell Proliferation, Cell growth, lcsh:R, Cancers and Neoplasms, Cancer, Precision medicine, medicine.disease, Antiestrogen, Kinetics, Cancer cell, Immunology, lcsh:Q, Drug Screening Assays, Antitumor, Cytometry

Abstract

The detection and treatment of cancer has advanced significantly in the past several decades, with important improvements in our understanding of the fundamental molecular and genetic basis of the disease. Despite these advancements, drug-screening methodologies have remained essentially unchanged since the introduction of the in vitro human cell line screen in 1990. Although the existing methods provide information on the overall effects of compounds on cell viability, they are restricted by bulk measurements, large sample sizes, and lack capability to measure proliferation kinetics at the individual cell level. To truly understand the nature of cancer cell proliferation and to develop personalized adjuvant therapies, there is a need for new methodologies that provide quantitative information to monitor the effect of drugs on cell growth as well as morphological and phenotypic changes at the single cell level. Here we show that a quantitative phase imaging modality known as spatial light interference microscopy (SLIM) addresses these needs and provides additional advantages over existing proliferation assays. We demonstrate these capabilities through measurements on the effects of the hormone estradiol and the antiestrogen ICI182,780 (Faslodex) on the growth of MCF-7 breast cancer cells. Along with providing information on changes in the overall growth, SLIM provides additional biologically relevant information. For example, we find that exposure to estradiol results in rapidly growing cells with lower dry mass than the control population. Subsequently blocking the estrogen receptor with ICI results in slower growing cells, with lower dry masses than the control. This ability to measure changes in growth kinetics in response to environmental conditions provides new insight on growth regulation mechanisms. Our results establish the capabilities of SLIM as an advanced drug screening technology that provides information on changes in proliferation kinetics at the cellular level with greater sensitivity than any existing method.

Published

2014

14. Real Time Blood Testing Using Quantitative Phase Imaging

Author

Catherine Best-Popescu, Krishnarao Tangella, Hoa V. Pham, Gabriel Popescu, and Basanta Bhaduri

Subjects

Engineering, Pathology, Erythrocytes, Image Processing, Red Cells, lcsh:Medicine, Cell analysis, Field of view, 02 engineering and technology, 01 natural sciences, Hemoglobins, Software Design, Digital image processing, Molecular Cell Biology, Image Processing, Computer-Assisted, Microscopy, Phase-Contrast, Computer vision, Anemia, Macrocytic, lcsh:Science, Blood testing, Condensed-Matter Physics, Multidisciplinary, Anemia, Iron-Deficiency, Physics, Electrical engineering, Software Engineering, Hematology, 021001 nanoscience & nanotechnology, Phase imaging, Cellular network, Medicine, Cellular Types, 0210 nano-technology, Algorithms, Research Article, Drugs and Devices, medicine.medical_specialty, Image processing, Bioengineering, Biology, Sphericity, Medical Devices, 010309 optics, Optical imaging, Microscopy, Electron, Transmission, 0103 physical sciences, White light, medicine, Humans, Sensitivity (control systems), Blood Cells, Software Tools, business.industry, lcsh:R, Optics, Refractometry, Transmission (telecommunications), Case-Control Studies, Computer Science, Signal Processing, lcsh:Q, Artificial intelligence, State (computer science), business, Focus (optics)

Abstract

We demonstrate a real-time blood testing system that can provide remote diagnosis with minimal human intervention in economically challenged areas. Our instrument combines novel advances in label-free optical imaging with parallel computing. Specifically, we use quantitative phase imaging for extracting red blood cell morphology with nanoscale sensitivity and NVIDIA's CUDA programming language to perform real time cellular-level analysis. While the blood smear is translated through focus, our system is able to segment and analyze all the cells in the one megapixel field of view, at a rate of 40 frames/s. The variety of diagnostic parameters measured from each cell (e.g., surface area, sphericity, and minimum cylindrical diameter) are currently not available with current state of the art clinical instruments. In addition, we show that our instrument correctly recovers the red blood cell volume distribution, as evidenced by the excellent agreement with the cell counter results obtained on normal patients and those with microcytic and macrocytic anemia. The final data outputted by our instrument represent arrays of numbers associated with these morphological parameters and not images. Thus, the memory necessary to store these data is of the order of kilobytes, which allows for their remote transmission via, for example, the cellular network. We envision that such a system will dramatically increase access for blood testing and furthermore, may pave the way to digital hematology.

Published

2013