(Created page with "= <u> '''Signals, Systems, and Biomedical Engineering''' </u> = == == == Background Information == Biomedical signal processing aims at extracting significant information...") |
|||
| Line 17: | Line 17: | ||
As technology is improving, engineers are discovering new ways to provide information to clinicians upon which they can make decisions. One of these improvements is through real-time monitoring, which can lead to the better management of chronic diseases, earlier diagnosis of disease, and earlier detection of both heart attacks and strokes. Biomedical signal processing is most useful in the critical care setting due to patient data needing to be analyzed in real-time. By doing complex analyses of the body's signals and having real-time monitoring, we can discover early indicators for how conditions manifest. | As technology is improving, engineers are discovering new ways to provide information to clinicians upon which they can make decisions. One of these improvements is through real-time monitoring, which can lead to the better management of chronic diseases, earlier diagnosis of disease, and earlier detection of both heart attacks and strokes. Biomedical signal processing is most useful in the critical care setting due to patient data needing to be analyzed in real-time. By doing complex analyses of the body's signals and having real-time monitoring, we can discover early indicators for how conditions manifest. | ||
| + | |||
| + | For more information about signals, systems, and biomedical engineering, follow these links: | ||
| + | *[http://paramedfac.tbzmed.ac.ir/uploads/User/28/pira/%DA%A9%D8%AA%D8%A8%20%D9%81%DB%8C%D8%B2%DB%8C%DA%A9%20%D9%BE%D8%B2%D8%B4%DA%A9%DB%8C/Biomedical%20Signal%20and%20Image%20Processing%20by%20Kayvan%20Najarian,%20Robert%20Splinter%202nd%20Edition%202012.pdf Biomedical Signal and Image Processing] | ||
| + | * [https://onlinelibrary.wiley.com/doi/book/10.1002/9781118007747 Advanced Methods of Biomedical Signal Processing] | ||
| + | * [https://users.ece.cmu.edu/~moura/papers/hsunhsien-chang-moura-biomedicalsp-2010.pdf Biomedical Signal Processing] | ||
| + | * [http://www.meo.etc.upt.ro/materii/cursuri/PSB/5.pdf Introduction to Biomedical Signals] | ||
| + | * [http://home.ee.ntu.edu.tw/classnotes/bme2/2007/6_11_07.pdf Biosignal Processing] | ||
==Examples of Biomedical Signal Processing== | ==Examples of Biomedical Signal Processing== | ||
| − | ''' | + | '''Biosensors:''' A biosensor is defined as a piece of hardware that can interact with either a biological or physiological system to acquire a signal for diagnostic or therapeutic purposes. They are analytical devices that convert a biological response into an electric signal. Biosensor technology incorporates a wide range of devices, which includes: |
* Stethoscope | * Stethoscope | ||
* Thermometer | * Thermometer | ||
| Line 27: | Line 34: | ||
* Pregnancy Test | * Pregnancy Test | ||
* Pulse Oximetry | * Pulse Oximetry | ||
| + | |||
| + | To learn more about biosensors, click [http://depts.washington.edu/mictech/optics/sensors/week8.pdf here] | ||
'''Imaging:''' Biomedical imaging concentrates on the capture of images for both diagnostic and therapeutic purposes. Snapshots of in-vivo physiology and physiologic processes can be collected through advances sensors and computer technology. Biomedical imaging technologies include: | '''Imaging:''' Biomedical imaging concentrates on the capture of images for both diagnostic and therapeutic purposes. Snapshots of in-vivo physiology and physiologic processes can be collected through advances sensors and computer technology. Biomedical imaging technologies include: | ||
| Line 37: | Line 46: | ||
* Computed Tomography (CT) | * Computed Tomography (CT) | ||
Biomedical imaging processing is very similar in concept to biomedical signal processing due to them both including enhancement, analysis, and display of results. | Biomedical imaging processing is very similar in concept to biomedical signal processing due to them both including enhancement, analysis, and display of results. | ||
| + | |||
| + | To learn more about imaging, click [http://cw.tandf.co.uk/imagingforstudents/sample-material/Chapter-1-Introduction-to-Medical-Imaging.pdf here] | ||
'''Wearable and Implantable Technologies:''' Both wearable and implantable technologies sense parameters of various conditions (diseases, disorders, etc.) and can either transfer the data to a remote center (hospital, physicians office, etc.), direct the patient to take specific action, or automatically perform a function based on what the sensors are reading. Examples of these include: | '''Wearable and Implantable Technologies:''' Both wearable and implantable technologies sense parameters of various conditions (diseases, disorders, etc.) and can either transfer the data to a remote center (hospital, physicians office, etc.), direct the patient to take specific action, or automatically perform a function based on what the sensors are reading. Examples of these include: | ||
| Line 44: | Line 55: | ||
* Smart Tattoos: Flat, flexible, stretchable electronic sensor placed on the skin to measure various electric signals produced by the heart, brain, and muscles | * Smart Tattoos: Flat, flexible, stretchable electronic sensor placed on the skin to measure various electric signals produced by the heart, brain, and muscles | ||
| − | + | To learn more about wearable and implantable technologies, click [https://pdfs.semanticscholar.org/ae69/1ea25f5256e66f4ed4ca41641e1758376b8f.pdf here] | |
| − | + | ||
| − | + | ||
| − | + | ||
| − | + | ||
| − | + | ||
Revision as of 14:58, 9 April 2018
Contents
Signals, Systems, and Biomedical Engineering
Background Information
Biomedical signal processing aims at extracting significant information from physiological signals, which includes:
- heart rate
- blood pressure
- oxygen saturation levels
- blood glucose
- nerve conduction
- brain activity
These signals can then be analyzed in order to provide information to physicians about what is going on in the body and allows them to make a diagnosis if any sort of abnormality is detected. This ultimately allows one to determine the state of a patient's health through non-invasive measures.
As technology is improving, engineers are discovering new ways to provide information to clinicians upon which they can make decisions. One of these improvements is through real-time monitoring, which can lead to the better management of chronic diseases, earlier diagnosis of disease, and earlier detection of both heart attacks and strokes. Biomedical signal processing is most useful in the critical care setting due to patient data needing to be analyzed in real-time. By doing complex analyses of the body's signals and having real-time monitoring, we can discover early indicators for how conditions manifest.
For more information about signals, systems, and biomedical engineering, follow these links:
- Biomedical Signal and Image Processing
- Advanced Methods of Biomedical Signal Processing
- Biomedical Signal Processing
- Introduction to Biomedical Signals
- Biosignal Processing
Examples of Biomedical Signal Processing
Biosensors: A biosensor is defined as a piece of hardware that can interact with either a biological or physiological system to acquire a signal for diagnostic or therapeutic purposes. They are analytical devices that convert a biological response into an electric signal. Biosensor technology incorporates a wide range of devices, which includes:
- Stethoscope
- Thermometer
- Blood Pressure Cuff
- Blood Glucose Device
- Pregnancy Test
- Pulse Oximetry
To learn more about biosensors, click here
Imaging: Biomedical imaging concentrates on the capture of images for both diagnostic and therapeutic purposes. Snapshots of in-vivo physiology and physiologic processes can be collected through advances sensors and computer technology. Biomedical imaging technologies include:
- X-ray
- Magnetic Resonance Imaging (MRI)
- Ultrasonography
- Positron Emission Tomography (PET)
- Single Photon Emission Computed Tomography (SPECT)
- Optical Coherence Tomography (OCT)
- Computed Tomography (CT)
Biomedical imaging processing is very similar in concept to biomedical signal processing due to them both including enhancement, analysis, and display of results.
To learn more about imaging, click here
Wearable and Implantable Technologies: Both wearable and implantable technologies sense parameters of various conditions (diseases, disorders, etc.) and can either transfer the data to a remote center (hospital, physicians office, etc.), direct the patient to take specific action, or automatically perform a function based on what the sensors are reading. Examples of these include:
- Blood glucose: If blood glucose is running high, insulin could be automatically administered from the device
- Cardiac Monitoring: Pacemaker is placed just under the skin to help control abnormal heart rhythms
- Parkinson's: Deep brain simulation sends electrical signals to brain areas responsible for body movement
- Smart Tattoos: Flat, flexible, stretchable electronic sensor placed on the skin to measure various electric signals produced by the heart, brain, and muscles
To learn more about wearable and implantable technologies, click here
