Body Adapted Wearable Bio Sensor
- 1. BODY ADAPTED WEARABLE BIOSENSORS (THE EMERGING TECHNOLOGY) by Kavindra krishna Research Scholar AMU 13LECM030 Department of Electronics Engineering AMU 1
- 2. Contents Introduction Need for a wearable biosensor What is Wearable Biosensor Components of a Biosensor Ring Sensor Smart Shirt Applications Future trends Conclusion References 2
- 3. Introduction Actually this topic is the part of Body Adapted Electronics, it’s a current emerging technology and some how break the boundaries between human and technology. These wearable are typically-tiny , packed with wide range of sensors and feedback systems, to make their use less intrusive but more socially acceptable. From the past few years(after Google glass), these technology, pull the focus of peoples and peoples are also take interest in these technology,because, devices are constructed with Wearable 3
- 4. Introduction Electronics are very helping in nature such as- a) It can tell about your personal health & fitness by monitoring exercise , heart rate,sleep pattern and so on. 4
- 5. Introduction b) Google glass worn by oncologist/doctors,to assist in surgery via medical records and other visual information accessed by voice commands. 5
- 6. Introduction c) Haptic Shoe sole that communicates GPS direction through vibration alerts felt by the feet and this application is specially helpful to blind people to navigate. 6
- 7. Introduction Quick look of our previous discussion 7
- 8. Need for a wearable biosensor Remote monitoring of patients. Training support for athletes. Monitoring of individuals who work with hazardous elements. Tracking of professional truck driver’s vital signs to alert them of fatigue. 8
- 9. What is wearable biosensor ? Wearable Biosensor = Wearable + Biosensor Biosensor is an analytical device used for detection of analyte. e.g. Blood Glucose Detector Biosensor Object that can be worn on body. e.g. wrist watches, ring, shirts etc. Wearable 9
- 10. Wearable Biosensor Wearable monitoring devices that allow continuous monitoring of physiological signals. They rely on wireless sensors enclosed in items that can be worn, such as ring or shirt. The data sets recorded using these systems are then processed to detect patient’s clinical situations. Biosensor is an analytical device, which converts a biological response into electrical signal. 10
- 11. Components Of Wearable Biosensor Three main components of wearable biosensors are: Biological element: For sensing the presence and concentration of a substance. Transducer: The product of interaction of biological component and sample may be a suitable chemical, charge etc., which can be converted by transducer into an electrical signal. Associated Electronic Devices: The electrical signal may be further amplified and can be read on digital panels. 11
- 12. Types Of Wearable Biosensor Ring Sensor: It allows one to continuously monitor heart rate and oxygen saturation. The device is shaped like a ring. Smart Shirt: This technology has been used to integrate sensors for monitoring the vital signs like temperature, heart rate and respiration rate. 12
- 13. About Ring Sensor It is a pulse oximetry, i.e. it monitors the oxygen saturation. It is based on the concept of photoconductor. Principles :- Blood pressure pulse causes vessel wall displacement. Detection pulsatile blood volume changes by photoelectric method by photo resistor. Connected as a part of voltage divider circuit and produces a voltage that varies with the amount of blood in the finger. 13
- 14. Components: • LED’s and Photodiodes • Optical sensor unit • PIC microcontroller • RF transmitter • Tiny cell battery • Use of double ring structure. • First stage amplifier • Signal Conditioner • Sample and hold circuit Less distance between LED & PD. Waveforms sampled at 100 Hz transmitted to a PDA or a cellular phone carried by the patient. 14
- 15. Working Of Ring Sensor Blood volume in the finger changes with the heart muscle expansion and contraction. This blood volume changes can be easily detected by photoelectric methods. Light is emitted by LED and transmitted through the artery and the resistance of photo resistor is determined by the amount of light reaching it. Optical density of blood depends on the blood volume. Oxygenated blood absorb more light than deoxygenated blood. If the blood volume increases, optical density increases, light transmission through finger reduces & the resistance of photo resistor increases. Thus the voltage generated by photo resistor varies with the amount of blood in the finger. 15
- 16. Working Of Ring Sensor A noise cancellation filter is used to cancel the noise due to motion of the finger. Block diagram of ring sensor is presented here. 16
- 17. Applications Wireless supervision of people during hazardous operations. In an overcrowded emergency department. Chronic surveillance of abnormal heart failure. In cardio-vascular disease for monitoring the hyper tension. Advantages Continuous monitoring. Easy to use. Reducing hospitalization fee Disadvantages Initial cost is high. Limited number of physiological parameters can be monitored. 17
- 18. About Smart Shirts Also known as GTWM i.e. Georgia Tech Wearable Motherboard. This GTWM (smart shirt) provides an extremely versatile framework for the incorporation of sensing, monitoring and information processing devices. • It uses optical fibers to detect bullet wounds and special sensors and interconnects to monitor the body vital signs during combat conditions. • It is used to integrate sensors for monitoring the vital signs like temperature, heart rate and respiration rate. 18
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- 20. Working of Smart Shirt A combat soldier sensor to his body, pulls the smart shirt on, and attaches the sensors to the smart shirt. A “signal” is sent from one end of the plastic optical fiber to a receiver at the other end. The emitter and the receiver are connected to a Personal Status Monitor (psm) worn at the hip level by the soldier. If the light from the emitter does not reach the receiver inside the PSM, it signifies that the smart shirt has been penetrated (i.e.; the soldier has been shot). The signal bounces back to the PSM forum the point of penetration, helping the medical personnel pinpoint the exact location the solider wounds. 20
- 21. Information on the soldiers wound and the condition is immediately transmitted electronically from the PSM to a medical unit. 21
- 22. Applications Of Smart Shirt Combat casualty care. Medical monitoring. Sports/ Performance monitoring. Space experiments. Mission critical/ hazardous application. Fire- fighting. Wearable mobile information infrastructure. Advantages Continuous monitoring. Right Treatment at the right time Easy to wear and takeoff. Disadvantages Initial cost is high Battery life is less 22
- 23. Conclusion Applied to restricted area of potential market. Limitations: Sensitivity And battery life. Advanced technologies such as the smart shirt have at partial to dramatically alter its landscape of healthcare delivery and at practice of medicine as we know them today. It is leading to the realization of “Affordable Healthcare, Any place, Anytime, Anyone”. 23
- 24. H.Harry Asada, “Mobile monitoring with wearable ppg sensors”,IEEE engineering in medicine and biology magazine, vol 22, pp- 28-39 may/june 2003. Park and Jayaraman,”Enhancing the quality of life through wearable technology”, IEEE engineering in medicine and biology magazine,vol 22, pp- 41-48 may/june 2003. Handbook of biomedical instrumentation ,Khandpur ,pp-138,233,238 R.Neuman,”Biomedical sensors”, handbook of biomedical instrumentation,pp-725-755. World Health Organization (2009) Visual impairment and blindness - Fact Sheet N°282. Available online at: http://www.who.int/mediacentre/factsheets/fs282/en/ Phd thesis on Wearable Assistive Devices for the Blind by Ramiro Velázquez Universidad Panamericana, Aguascalientes, Mexico. http://www.smartshirt.gatech.edu http://www.wearables.gatech.edu THANK YOU References 24