Ushenko / Duo / Dubolazov | Polarization-Based Optical Imaging for Clinical Diagnostics | Buch | 978-3-527-41469-7 | www.sack.de

Buch, Englisch, 432 Seiten, Format (B × H): 216 mm x 276 mm

Ushenko / Duo / Dubolazov

Polarization-Based Optical Imaging for Clinical Diagnostics


1. Auflage 2026
ISBN: 978-3-527-41469-7
Verlag: Wiley-VCH GmbH

Buch, Englisch, 432 Seiten, Format (B × H): 216 mm x 276 mm

ISBN: 978-3-527-41469-7
Verlag: Wiley-VCH GmbH

"Polarization-Based Optical Imaging for Clinical Diagnostics" presents a comprehensive methodology for optical mapping of biological tissues and fluids using 3D Jones-Mueller digital holography. It covers physical principles, experimental systems, and data analysis algorithms, offering a unified theory for polarization-based diagnostics. The book includes applications in oncology, cardiology, gynecology, and forensic medicine, demonstrating its clinical relevance. What sets this book apart is its integration of statistical, fractal, and wavelet analyses with advanced imaging techniques, enabling precise differentiation of pathological states. It also features software tools and image libraries, making it both a reference and a practical guide for modern biomedical diagnostics.

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Autoren/Hrsg.

Ushenko, Yurii
Duo, Weidong
Ushenko, Oleksandr
Dubolazov, Oleksandr
Soltys, Iryna

Fachgebiete

Weitere Infos & Material

PART I: METHODS AND SYSTEMS OF OPTICAL MAPPING IN BIOMEDICAL RESEARCH
1. Overview of modern optical mapping techniques
1.1 Diffuse, fluorescence molecular, bioluminescence, photoacoustic, laser coherent, andlaser polarization-sensitive systems
1.2 Unsolved problems and proposed solutions via 3D Jones-Mueller digital holographic mapping

PART II: PHYSICAL PRINCIPLES, ALGORITHMS AND METHODS OF 3D JONES-MUELLER DIGITAL HOLOGRAPHIC MAPPING
 
2. Physical principles of 3D Jones-Mueller digital holographic mapping
2.1 Phenomenological models of optically anisotropic tissue and fluid samples
2.2 Reconstruction of optical anisotropy parameters (linear and circular birefringence and
dichroism)
3. Algorithms and methods of 3D Jones-Mueller digital holographic mapping
3.1 Digital holographic reconstruction and phase scanning
3.2 Multichannel polarization-interference measurement and reconstruction of anisotropy
maps
4. Basic algorithms for processing 3D Jones-Mueller digital holographic mapping data
4.1 Statistical analysis
4.2 Correlation analysis
4.3 Wavelet analysis
4.4 Multifractal analysis
4.5 Singular analysis
 
PART III: BIOMEDICAL AND CLINICAL APPLICATIONS OF 3D JONES-MUELLER DIGITAL HOLOGRAPHIC MAPPING
 
5. Diagnostic efficiency of 3D Jones-Mueller digital holographic mapping
5.1 Phase waves of local depolarization in biological tissues
5.2 Differential Mueller-matrix mapping of polycrystalline tissue components
5.3 Optical interference approach for tumor differentiation
5.4 Wavelet-enhanced polarimetry for cancer analysis
5.5 Holographic scanning of myocardial layers
5.6 Holographic histology for necrotic tissue differentiation (forensics)
5.7 Imaging of blood film microstructure
6. Diagnostic efficiency of 3D Jones-digital holographic mapping
6.1 Mapping of biological fluid facies
6.2. Jones matrix tomography
6.2 Multifractal scanning for COVID-19 diagnostics
6.3 Scanning of blood plasma films for organ pathology
6.4 Polarimetry of blood films for thyroid pathology
 
Appendices
A1. Programs for 3D Jones-Mueller holographic reconstruction
A2. Programs for layer-by-layer reconstruction of polycrystalline structures
A3. Programs for statistical and correlation data analysis
A4. Album of Mueller matrix images
A5. Album of optical anisotropy maps
 
Conclusion

Yurii Ushenko, PhD, is a physicist and computer scientist affiliated with Shaoxing University in China and Yuriy Fedkovych Chernivtsi National University in Ukraine. His research focuses on biophotonics, optical imaging, and digital holography for biomedical diagnostics.
 
Weidong Dou, PhD, is a physicist at Shaoxing University, China. His expertise lies in laser optics and biomedical imaging systems, with a focus on developing advanced diagnostic technologies using polarization-sensitive methods.
 
Oleksandr Ushenko, PhD, is a researcher in multimedia and optical technologies at Yuriy Fedkovych Chernivtsi National University. His work centers on digital holography and optical mapping techniques for clinical applications.
 
Oleksandr Dubolazov, PhD, is a specialist in printing and optical technologies at Yuriy Fedkovych Chernivtsi National University. He contributes to algorithm development for biomedical image analysis and optical diagnostics.
 
Iryna Soltys, PhD, is a researcher in optical technologies at Yuriy Fedkovych Chernivtsi National University. Her interests include polarization imaging and the application of digital holography in medical diagnostics.
 

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