Course

CH-448: Photomedicine

Lectures in this course (23)

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

Photomedicine: Introduction

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

Photomedicine: History

Covers the history of photomedicine, including the development of PDT and its application in treating age-related macular degeneration.

Radiometry/Photometry

Explores radiometry and photometry concepts, including the history of photomedicine and the measurement of electromagnetic radiation and light.

Ray Optics: EM Wave Optics

Explores radiometry, photometry, laser power distribution, and light behavior in different media.

Quantum Description of Light: Tissue Optical Parameters

Explores the quantum description of light and tissue optical parameters, including the historical perspective, wave-particle duality, and the interaction between light and tissues.

Tissue Optics

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

Tissue Optics

Explores tissue optics, covering refractive index, absorption, and scattering mechanisms in biological tissues.

Application of Absorption

Explores the application of light absorption in photomedicine, particularly in pulse oximetry.

Application of Scattering in OCT

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

Radiative Transport Equation

Explores the Radiative Transport Equation in tissue optics, covering radiance, photon distribution, and numerical solutions like Monte Carlo simulations.

Radiative Transport Equation

Explores the Radiative Transport Equation in tissue optics, covering radiance, photon distribution, fluence rate, and solution methods.

Approximations of the RTE

Explores the Kubelka-Munk theory and diffusion approximation in tissue optics.

Diffusion Approximation: RTE

Explores the Diffusion Approximation method for solving the RTE in tissue optics, emphasizing its limitations and applications, along with the practical aspects of Monte Carlo simulations.

Tissue Optics

Explores tissue optics, including Kubelka-Munk theory, radiance, and light dosimetry in tissues for photomedicine applications.

Tissue Optics: Measurement Methods

Explores direct and indirect measurement methods in tissue optics, highlighting challenges and techniques used for in vivo measurements.

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.

Light Dosimetry in Tissues

Explores light dosimetry in tissues for medical laser treatments, covering parameters and mechanisms of interaction.

Applications of Optical Spectroscopy in Photomedicine

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

Molecular Energy Levels

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