Göran Salerud: Biomedical Optics

Recorded at Tallinn University of Technology, Summer 2007.

(Flash, 360x270 pix + 720x540 pix)
How to view the video files is found from: "Technical Requirements".

1	I	Introduction      Course Content      Why Use Optical Methods?      Why Should You Learn Biomedical Optics?      Fundamentals of Optics      Overview of Spectroscopy      Classical Description of Light      Light-Tissue Interaction
2	II	Basic Optics      What is Light      Short Wavelengths      Radiation Power      Radiation Energy      Radiation Intensity      Collection of Light      Integrating Spheres      Detector
	III	Tissue Optical Properties      Optical Properties vs Optical Measurements
3		Absorption      Scattering      Anisotropy      Isotropic Scattering      Anisotropic Values      Summary
4		Scattering Cases      Rayleight Scattering      Mie Theory Model      Summary Optical Properties
5	IV	Optical Transport in Tissues      Primary Unscattered Light      Demonstration      Optical Fiber in Scattering Medium      Irradiance      1D Model      Fluence Rate      Time-Resolved and Steady-State Fluence Rate      Light Diffusion      Internal Source and Virtual Source
6	V	Transport Equation      The Dualism of Light      Light Propagation in Random Medium      Transport Equation      Monte Carlo Simulations      Radiance L      The Transport Equation      Energy Conservation      The Total Attenuation Coefficient and Albedo
7	VI	Diffusion Equation      Approximations      Spherical Harmonics      Diffusion      Photon Density Function      Photon current Density      Mathematical Simplifications      The Diffusion Coefficient      The Diffusion Equation      Point Source Solution
8		Light Scattering in Tissue by Monte Carlo Simulation      What is Monte Carlo Modeling?      Program Menu and Steps      End of Monte Carlo Model
9	VII	Optical Properties Measurements      Attenuation of Collimated Beam      Collimated Transmission Calculations      Total Diffuse Reflectance      Optical Penetration Depth      Total Diffuse Reflectance      Calculations
10		Integrating Sphere      Reflection Calculations      Goniometer Principle      Scattering Pattern      CCD Camera with Tilted Source
11	VIII	Devices and Protocols      Optical Fiber Bundle      Measurement Situation      Multifiber Probe      Oxygenation and Blood Content      Fluorescence      PDT
12		Polarization      Amplitude Scattering Matrix      Degree of Polarization      Scattering Matrix      System Setup      Polarization Image      Prerequisites      Degree of Polarization
13		QUELS      Evolution      Theory Principle      Anisotropy      Scattering Function      Detection Model      Coherence Area      Photocurrent      16 Terms of E-Fields      Light Beat Detection      The Doppler Component      Wiener –Khintchine Theorem      Perfusion Value      Sampling Volume      LDPM
14		Optical Coherence Tomography      Imaging Methods in Tissue      Optical Coherence Tomography      Temporal Coherence      Coherence Properties      Correlation Functions      Photon Sources      Coherence      Coherence Length      Optical Coherence Tomography      Lightsource Parameters      Optical Coherence Tomography