ChhangMak: Difference between revisions
imported>Student221 No edit summary |
imported>Student221 |
||
| Line 1: | Line 1: | ||
== Introduction == | == Introduction == | ||
Doctors often need to screen for oral cancer. When certain wavelengths of light are emitted into the mouth, cancerous and pre-cancerous tissues will have different fluorescent properties than healthy tissue. We can use this property to identify cancerous and pre-cancerous tissue in the mouth. However, in the mouth, emitted fluorescent light is often much weaker in magnitude than the reflected light we get from the light we put into the mouth in the first place. | Doctors often need to screen for oral cancer. When certain wavelengths of light are emitted into the mouth, cancerous and pre-cancerous tissues will have different fluorescent properties than healthy tissue. We can use this property to identify cancerous and pre-cancerous tissue in the mouth. However, in the mouth, emitted fluorescent light is often much weaker in magnitude than the reflected light we get from the light we put into the mouth in the first place. | ||
Thus, we want to be able to create a light that excites the fluorescent areas of the mouth. We want to be able to detect this fluorescence, however weak the fluorescence may be relative to the reflected light, so that we can identify cancerous and pre-cancerous tissue in the mouth. | |||
That the fluorescence is much weaker than the reflected light presents a challenge to us. We create a system where we pass a narrow bandwidth light (within the excitation spectrum of the fluorophore (a.k.a. fluorescent object) we want to measure) through a shortpass filter. The resultant light would ideally be one that does not have any light with wavelength outside of the excitation spectrum, so that we see as little of the reflected light as possible. This light is to hit the fluorophore and return to us via the camera. We pass the light heading into the camera through a longpass filter, again to allow fluorescent light through and block any reflected light. | |||
== Background == | == Background == | ||
Revision as of 02:25, 11 December 2019
Introduction
Doctors often need to screen for oral cancer. When certain wavelengths of light are emitted into the mouth, cancerous and pre-cancerous tissues will have different fluorescent properties than healthy tissue. We can use this property to identify cancerous and pre-cancerous tissue in the mouth. However, in the mouth, emitted fluorescent light is often much weaker in magnitude than the reflected light we get from the light we put into the mouth in the first place.
Thus, we want to be able to create a light that excites the fluorescent areas of the mouth. We want to be able to detect this fluorescence, however weak the fluorescence may be relative to the reflected light, so that we can identify cancerous and pre-cancerous tissue in the mouth.
That the fluorescence is much weaker than the reflected light presents a challenge to us. We create a system where we pass a narrow bandwidth light (within the excitation spectrum of the fluorophore (a.k.a. fluorescent object) we want to measure) through a shortpass filter. The resultant light would ideally be one that does not have any light with wavelength outside of the excitation spectrum, so that we see as little of the reflected light as possible. This light is to hit the fluorophore and return to us via the camera. We pass the light heading into the camera through a longpass filter, again to allow fluorescent light through and block any reflected light.
Background
Methods
Results
Conclusions
Appendix
You can write math equations as follows:
You can include images as follows (you will need to upload the image first using the toolbox on the left bar, using the "Upload file" link).