Concept

Medical optical imaging

Related lectures (19)

Explores fluorescence lifetime in photomedicine, covering health effects of artificial light, fluorescence guided surgery, and applications of optical spectroscopy.

Light Dosimetry in Tissues

Explores light dosimetry in tissues for photomedicine applications, covering mechanisms of light therapy, laser classification, and the influence of laser parameters on treatment outcomes.

Fluorescence: Applications in Photomedicine

Explores the principles of fluorescence lifetime and quenching in photomedicine.

Applications of Optical Spectroscopy in Photomedicine

Explores optical spectroscopy in photomedicine, emphasizing fluorescence principles, biological fluorophores, and fluorescence lifetime measurements.

Fluorescence Spectroscopy: Principles and Applications

Explores fluorescence spectroscopy principles, applications in photomedicine, and biological fluorophores.

Tissue Optics

Explores Tissue Optics, focusing on Optical Coherence Tomography and light scattering in photomedicine, with applications in ophthalmology, dermatology, cardiology, and gastroenterology.

Molecular Energy Levels

Delves into molecular energy levels, electronic transitions, and applications in photomedicine.

Photomedicine: Introduction

Introduces the field of photomedicine, focusing on the study and treatment of diseases using light.

Image Processing II: Reconstruction from Projections

Explores image reconstruction in computer tomography from projections and absorption laws.

Optical Detection: Position-Sensitive Detectors and Applications

Covers optical detection methods, focusing on position-sensitive detectors and their applications in various fields.

Application of Scattering in OCT

Explores the application of light scattering in Optical Coherence Tomography for high-resolution tissue imaging in various medical fields.

Optical Detection: Synchronous and Direct Methods

Discusses optical detection methods, focusing on synchronous and direct detection techniques and their applications in imaging and measurement.

Optical Methods in Chemistry

Introduces optical methods in chemistry, covering ray optics, lasers, spectroscopy, and X-ray physics, emphasizing light-matter interactions and Nobel Prize-winning advancements.

Ultrafast Semiconductor Lasers

Explores the Mixel project, showcasing the importance of ultrafast semiconductor lasers and their diverse applications.

Optical Spectroscopy: Detectors and Quantum Efficiency

Explores optical spectroscopy, emphasizing photodetectors' efficiency and performance metrics.

Magnetic Resonance: Spin Qubits and Their Applications

Covers magnetic resonance principles and their application to spin qubits in quantum science.

Fourier Transforms in Tomography: Inversion Techniques

Covers the application of Fourier transforms in tomography, focusing on the Radon transform and its inversion techniques.

Optical Spectroscopy: Fundamentals and Applications

Covers the fundamentals of optical spectroscopy and its applications in various fields, exploring the design and operation of spectrometers.

Synchrotrons and X-ray Free-Electron Lasers: Techniques and Applications

Explores lensless imaging and coherent X-ray diffractive imaging techniques and applications, including high-resolution 3-D imaging of nanocrystal strain.