2010 GUI Interaction A - Absorption and Scattering Spectra

GOAL: Gain familiarity with wavelength dependent optical properties for tissue as well as with the relevant length and time scales

Select "Spectral Panel". Note that "Tissue Types" lists various tissues. Each tissue is modeled consisting of individual chromophores (e.g. water, blood, fat, etc.), each of which has a certain concentration pertinent to a particular tissue. In this exercise we will study how absorption and scattering properties of tissues (as well as their constituting chromophores) vary with the wavelength of illuminating radiation.

I. Pure Spectra

Goal: This portion of the GUI Interaction is to provide an introduction to the functionality of the Spectral Panel.
  1. Select "Custom" in Tissue Types.
  2. In Absorber Concentrations set concentrations to 1 μM for Hb and 0 μM for the other optical absorbers.
  3. Enter "Hb" in "Plot Label" box.
  4. Click the "Plot μa Spectrum" button at the bottom of the panel.
  5. Plot provides μa as a function of wavelength, λ, for Hb ("pure" Hb spectrum).
  6. Confirm that the output is consistent with results shown in lecture 1 for 600<λ<1000.
  7. Confirm the "Hold On" checkbox is checked (under the graphing area on the left).
  8. Repeat the steps I.1-I.6 for HbO2.
  9. Click the "Clear All" button under the graphing area.

II. Tissue spectra

Goal: It is known that the liver is a highly cellular and blood filled tissue, while skin, by contrast, has less cellular content and more extracellular matrix proteins. As you do this excercise examine whether the μa and μs' spectra are consistent with the known composition and morphological properties of these tissues. Comment on the similarities / differences in their spectra.
  1. Select "Skin" in Tissue Types.
  2. Notice the defaults in Absorber Concentrations.
  3. Enter "Skin" in "Plot Label" box.
  4. Plot μa of skin versus wavelength.
  5. Confirm that the "Hold On" checkbox is checked.
  6. Repeat the steps II.1-II.4 for tissue type "Liver".
  7. Click the "Clear All" button.
  8. Plot μs' spectra on the same axis for these tissue types.
  9. Record the minimum and the maximum values of μa and μs' for these two tissues (Hover the mouse over the nodes on the plots to see the corresponding numeric value).
  10. Estimate minimum and maximum of the ratio μs' / μa within the spectral range λ = 600-1000nm.
  11. Spatial and temporal scales.

Using the data collected in II.9-II.10 and the definitions given in lecture 1, estimate minimum/maximum values of ls,labs,l * within the spectral range of λ = 650-1000nm. Assume g = 0.8.

Additional Question:
  1. You have designed a device that can detect changes in μa as small as 0.01 mm-1 at λ = 600nm. Assuming that changes in your system are limited to changes in Hb concentration, what is the smallest Hb concentration change that you detect? Similarly for HbO2?