2020-2021 Medical Electronics Projects in Bangalore
Medical Engineering is the application of engineering principles to both the human body and to a broad range of instrumentation used in modern medicine. The engineering degree courses at Swansea University draw on the exciting medical research that is taking place within the College of Engineering and the College of Medicine. The research success in the two colleges led to the creation of the £22 million Centre for NanoHealth (CNH), a unique facility linking engineering and medicine.
2020-2021 Medical Electronics Projects for ECEOur Medical Engineering degrees schemes make extensive use of our dedicated Metallography Laboratory, Fluids Laboratory and Dynamics Laboratory Mechanics.Within the College of Engineering there are key resources that are used by medical engineering students and researchers.
Electrical engineering instruments for the building and testing of medical devices Biomechanical modelling for optimisation of implant technologies Process engineering equipment for pharmaceutical production
2020-2021 Medical Electronics Projects PDF free DownloadMedical engineering students at all levels use facilities of the Electronic Systems Design Centre within the Systems and Process Engineering Centre. It has a variety of state-of-the art equipment. Facilities include: Design and modelling laboratory equipped with Sun UNIX machines and TCAD (TSUPREM, MEDICI) softwares, as well as IC-CAP parameter extraction tool, SABER simulator and Synopsys IC design software suit. Fully equipped state-of-the-art power electronics laboratory consisting of oscilloscopes, function generators, power analyzers, micro-processor development systems, spectrum analyzers, high voltage test equipment, thermal device characterisation equipment, and device characterisation equipment (including an HP4124 parameter analyzer, a probe station and CV characterisation equipment).
|MED001||Advances in Medical Devices and Medical Electronics||2020|
|MED002||Predicting Ventilator Modes To maintain Blood Oxygen Saturation of Post Surgical Patients
Within Desired Limit Using Weighted KNN Classification Algorithm
|MED003||COVID-19: Deep Learning Approaches for Diagnosis and Treatment||2020|
|MED004||Early Prediction of the 2019 Novel Coronavirus Outbreak in the Mainland China Based on Simple Mathematical Model||2019|
|MED005||Artificial Intelligence (ANN Based )in the Battle against Coronavirus (COVID-19): A Survey and Future Research Directions||2020|
2020-2021 Medical Electronics Projects
1.Instrumentation Problems in a High-Frequency Heart Sound Analyzer
2.An Electronic Device for the Measurement of Sweat Rates
3.Electrical Properties of Body Tissues and Impedance Plethysmography
4.Measurement of Bioelectric Potentials With Microelectrodes and Neutralized Input Capacity Amplifiers
5.A Method of Measuring Eye Movemnent Using a Scieral Search Coil in a Magnetic Field
6. The magnetocardiogram-A new approach to the fields surrounding the heart
7.Design of a Mechanical Cardiovascular Sinulator
8.Electronically Controlled Stage for Systematic Scanning of Microscopic Areas
9.Improved Transducer for External Recording of Arterial Pulse Waves
10. Measurement of the Human Prostate Gland in Vivo with Magnetic Fields
2020-2021 Medical Electronics Projects IdeasTo the authors’ knowledge, the implanted electronics are the smallest in reported literature, which reduces bio-burden. Calibration was performed across realistic physiological flow ranges using a syringe pump. The device’s sensors connected directly to the bilateral femoral veins of swine. For one minute each, Blood flow was monitored, then an occlusion was introduced, and then the occlusion was removed to resume flow. Each vein of four pigs was monitored four times, totaling 32 data collections. The implant measured 1.70 cm3 without battery/encapsulation.
1.Medical Electronics Device-The magnetic resonance imager
Since its introduction in 1977 by Raymond Damadian in the US, magnetic resonance imaging (MRI) has revolutionised the field of medical imaging. Based on magnetic fields and radio-wave technology, MRI scanning can produce images of either hard or soft tissue across large portions of the body without pain for the patient or the need for invasive procedures or radiation. MRI scanners are currently used worldwide to facilitate investigations and diagnoses in patients with a variety of conditions that include: tumours, cardiovascular disease, haemorrhages, cysts, brain trauma, or infections. MRI’s high-resolution, high-quality pictures far surpass those of other imaging techniques in terms of both the usefulness of the images and minimal impact on the patient.
2.Medical impulse Device The pacemaker
In the 1800s, it was discovered that heart rhythm is controlled by electrical impulses and, by the 1940s, pacemakers were designed with the aim of artificially controlling the patient’s heartbeat to help it contract with a regular rhythm. However, various practical issues dogged initial attempts to develop pacemakers. Their bulk made them impractical to implant in the human body, and they had a short and unpredictable battery life. In addition, bodily water affected the devices’ electronics, limiting their use. But in 1958, Wilson Greatbatch’s version, which was just two cubic inches in size, could take control of a dog’s heartbeat. Modern pacemakers are now the size of a coin and can be implanted near the patient’s heart. It is estimated that three million patients worldwide currently have a pacemaker, with 600,000 pacemakers implanted each year.
3. The X-ray machine
Before X-rays were discovered in 1895 by German physicist WC Röntgen, it was impossible to know what was happening inside patients’ bodies without cutting through their flesh. By 1896, the world’s first X-ray department had been set up in Glasgow Royal Infirmary, with diagnoses ranging from kidney stones to a penny stuck in a child’s throat. But it was soon realised that X-rays can have harmful effects on the body, and measures are now taken to protect patients and doctors from excessive exposure.
4. Laparoscopic surgery
Hans Christian Jacobaeus performed the first clinical laparoscopic surgery on a human in Stockholm in 1910. Also known as minimally invasive or keyhole surgery, laparoscopic surgery has many advantages over traditional open procedures. Smaller incisions mean that pain and haemorrhaging are reduced, and recovery times are shorter. Laparoscopy is used throughout the body – now even being used for the most difficult organ of all to operate on – the brain.
2020-2021 IEEE Medical Electronics ProjectsCurrent totally implantable wireless blood flow monitors are large and cannot operate alongside nearby monitors. To alleviate the problems with the current monitors, we developed a system to monitor blood flow wirelessly, with a simple and easily interpretable realtime output.
Electronics for Medicine, commonly known as "E for M," was a pioneering company in medical electronics.Medical Electronics Engineering that advances knowledge in Engineering and Medicine is one of the most extensively growing fields of this era where people prefer the best and precise health service. Medical Science examines treats and cures almost all the disease meeting the need of accuracy by the people by using sophisticated and precise equipments.
A medical electronics engineer can be called as the doctor of the equipments without which a doctor, a surgeon or a multi specialty hospital is helpless. He/She is the person, who knows the mechanism, operation and maintenance of these equipments.
Biomedical engineering is one of the recognized professional career options made by students in India. Biomedical engineers and technologists can seek employment in various industries such as hospitals, medical institutions, manufacturing units, medical equipment, government agencies and pharmaceuticals.
Medical Electronics Projects in Bangalore