FORCE Biomedical, New Delhi Videos

Video Laryngoscope Tracheal intubation by video laryngoscope is the most innovative advancement and a completely different experience as compared with conventional Macintosh laryngoscope, and skills needed for the former method of indirect laryngoscopy are very different from those needed for direct laryngoscopy by Macintosh or Miller blade laryngoscopes. The latter method definitely requires training to be an experienced laryngoscopist and tracheal intubator, while in case of video laryngoscopy (VL), even the novices can successfully do laryngoscopy and intubate the trachea. ➖➖➖➖➖➖➖➖➖➖ Lear Everything About Biomedical Engineering at https://t.me/FORCE_BIOMEDICAL

Working principle of transform

Biomedical engineering (BME) is the application of engineering principles and design concepts to medicine and biology for healthcare purposes (e.g. diagnostic or therapeutic). It combines the design and problem solving skills of engineering with medical and biological sciences to advance health care treatment, including diagnosis, monitoring, and therapy. Biomedical engineering has only recently emerged as its own study, compared to many other engineering fields. Such an evolution is common as a new field transitions from being an interdisciplinary specialization among already-established fields, to being considered a field in itself.

Vein Visualization Technology Vein visualization allows the clinician to map the vasculature making it easier to assess and find a suitable vein for IV access or blood draw. Though vein visualization technology can be very helpful in reducing the number of sticks needed to access a vein, the technology had been new and its adoption as part of the standard of care had not been widespread. Recently large-scale adoption of vein visualization is becoming much more common as facilities are experiencing the benefits of vein visualization technology. Credit: Medical Videos FB Page

BME Student Interview
BME Student Interview Name: Diondra Peck Class: 2017 Hometown: New Orleans Concentration: Applied math Applied math concentrator sums up SEAS experiences, from medical research to mentorship Why did you decide to concentrate in applied math at SEAS? Actually, I didn’t like math in high school. During my senior year, I had a really great Calculus teacher who helped me realize that I want to pursue math. I was already interested in biology, so I came to Harvard thinking about ways to infuse math into that area. As an applied math concentrator with a focus in biomedical engineering, I get to develop a lot of cool math and computer science skills, and then choose which parts of the body I want to apply those skills to. It has been a really good fit. How do math and biomedical engineering combine in your research at Boston Children’s Hospital? I work in the lab of Gabriel Kreiman, Assistant Professor of Ophthalmology at Harvard Medical School, who studies biological and computational mechanisms of computer vision. My role is to build computer vision models that have better object recognition. An assistive algorithm running in the background during a procedure could tell a radiologist what they are seeing is probably a tumor, as opposed to a cyst or something else entirely. There are many complicated problems in radiology that could be helped by having better computer vision models. How has that work informed your senior thesis project? For my thesis, I built contextually aware computer vision models, which are very similar to the work I’ve done at Children’s. Computer vision models are good at basic object recognition—the computer recognizes an apple in the grocery store because it has seen apples before. But a human also understands context, so he or she would know it is an apple because it is sitting next to oranges in the fruit aisle. My hope is that we can find a way to quantify that context mathematically and incorporate it into an algorithm that can help c

Great move towards Rural Healthcare

Varian Launches Game-Changing Treatment Platform to Answer the Global Cancer Challenge PALO ALTO, California and VIENNA, May 6, 2017 /PRNewswire/ -- Varian Medical Systems (NYSE: VAR) today is introducing the Halcyon™ system, an entirely new device for cancer treatment. Engineered to revolutionize clinical workflow, Halcyon simplifies and enhances virtually every aspect of image-guided volumetric intensity modulated radiotherapy (IMRT). This new treatment system is designed to expand the availability of high quality cancer care globally and help save the lives of millions more cancer patients. Experience the interactive Multimedia News Release here: https://www.multivu.com/players/English/8065951-varian-medical-systems-halcyon-cancer-treatment

CT vs MRI

Event: Farewell Party Department: Biomedical Engineering Batch: 2013 - 2017 College: PSNA College of Engineering Location: Dindigul, Tamil Nadu

We are Biomedical Engineer We bring happiness to every one Proud to be Biomedical Engineer Behind Every Happy Life There is a Biomedical Engineer

Biomedical engineers from Newcastle University have developed a computer vision system for prosthetic hands, allowing users to grasp and interact with common objects. Current upper limb prosthetics that can grip are controlled by myoelectric signals from the muscles in the stump, but it’s a skill that takes patience and time to master. Funded by the EPSRC, the Newcastle team created a computer vision system that enables prosthetics to ‘see’ with the assistance of an off-the-shelf camera. The work appears in the Journal of Neural Engineering. “Responsiveness has been one of the main barriers to artificial limbs,” said Dr Kianoush Nazarpour, senior lecturer in Biomedical Engineering at Newcastle University. “For many amputees the reference point is their healthy arm or leg, so prosthetics seem slow and cumbersome in comparison.” “Using computer vision, we have developed a bionic hand which can respond automatically – in fact, just like a real hand, the user can reach out and pick up a cup or a biscuit with nothing more than a quick glance in the right direction.” The researchers trained the system using neural networks, showing it numerous pictures of various objects from multiple angles and in different light conditions. Over time, the AI learned which grasp pattern to use for different objects according to their shape, but without measuring specific dimensions or explicitly identifying them. Objects were categorised into four grasp classes: pinch, tripod, palmar wrist neutral and palmar wrist pronated. “The computer isn’t just matching an image, it’s learning to recognise objects and group them according to the grasp type the hand has to perform to successfully pick it up,” said lead author Ghazal Ghazaei, who carried out the work as part of her PhD at Newcastle’s School of Electrical and Electronic Engineering. “It is this which enables it to accurately assess and pick up an object which it has never seen before – a huge step forward in the development of bio

UI College of Engineering students go above and beyond to help 8-year-old ride his bicycle Credit: University of Lowa

The next evolution in office working could be employees getting implanted with a microchip Credit: Recode https://www.recode.net/2017/4/8/15225040/microchip-implant-cyborg-computer-under-skin-sweden

Medical devices enable quadriplegic to move again Credits: Cleveland Medical Center (UH).

Hello all Stay in touch with Force Biomedical for updates. FB page FB group WhatsApp groups Telegram Channel Google Groups By Avinash Vemula Good day all Share and Spread the word.

Parata Robotic System (Automatic Pharmacy Dispenser) The machine is full automation labeling, counting and capping. Simple in checking the drug as each cell having electronic ship to save the information of the drug. Credit: International BME WhatsApp Group More information see this video https://youtu.be/4GTEupD3Wu0

Watch this video and know about X-Rays Angiography C-Arm CTScan Mammography Dental X-Ray Nuclear Medicine Share this video and spread knowledge

Medical Devices And In Vitro Diagnostic Medical Devices Credit: European Parliamentary Research Service Blog

Demonstration of Human Body using Latest Technology

Scientists convert spinach leaves into human heart tissue — that beats Source: National post

FDA approves new diabetes implant

The low cost medical Devices that are making a difference

Tele ECG product by Indian Scientist from Baba Atomic Research Centre. Mumbai, India

Interview with ETHealthworld, Jonathan Chen, Senior Vice-president of International operations, MicroPort, USA, talks about their plans to expand their reach in India and globally. India is within the top 3 to 4 markets and within 10 years time there is a very good chance that the number 1 and number 2 markets will be china and India in terms of volume. So we always think about long terms prospects for MicroPort and we think that having our home market in China and a thriving business in India will be great for a long term potential for MicroPort.

Biomedical Engineering: Is it Right for me? Is it a Good Major? Credit: Engineering Worth

Video lecture on ECG Measurement
Video lecture on ECG Measurement by Dr Atul Luthra, Senior Consultant Physician, Additional Director, Fortis Memorial Research Institute, Gurgaon, New Delhi, India. Thanks

Worthy watching Importance of Safety Testing of Medical Equipments Need Licence / Certification to BMEs Talk on Importance of preventive maintenance and calibration - Safetycon 2014 By Niranjan D. Khambete BE (Instrumentation), MTech (Biomed. Engg.), PhD (Engg.) Manager – Clinical Engineering, Deenanath Mangeshkar Hospital and Research Centre, Pune Conference 1st National Conference on Hospital Safety and Occupational Health - CMC Vellore. Location: Vellore, India

13 Recent Medical Innovations Credit: Talltanic Forwarded by Arulmani 2 Year BME Student Mahendra College of Engineering, Salem, Tamil Nadu, India

💊 CAPSULE ENDOSCOPY 💊 🖲 It is a procedure that uses a tiny wireless camera to take pictures of gastrointestinal tract. 🎯 It helps doctors to examine esophagus, stomach and small intestine(duodenum, jejunum and ileum) , in which part of bowel cannot be reached by traditional colonoscopy. 🎯 Its main aim is to know the cause of bleeding in intestine. HISTORY 🌹 GAVRIEL IDDAN is an Israeli electro optical engineer and inventor of wireless capsule endoscopy. PROCEDURE 💊 Capsule is swallowed by the patient like pill only after atleast 3hrs of fasting and positioned with right lateral. 🔘 During procedure patient will sip 15 ml of water every 30 sec. Then it takes images as it is propelled forward by peristalsis. 💊 Capsule contains lights to illuminate digestive system, a camera to take images and an antenna that sends those images to recorder which worn on patient waist as a belt. 🔘 A computer workstation processes data and produces a continous images. 🔘 After 24 hrs the capsule is passed out through patient and no need to retrieve. INDICATIONS ⭕ Obscure gastrointestinal bleeding ⭕ Crohn's disease ⭕ Celiac disease ⭕ Polyps ⭕ Colon cancer CONTRA INDICATIONS 🔵 History of or suspected small bowel obstruction 🔵 Swallowing disorders 🔵 Pregnancy INSIDE CAPSULE 💊 Capsule contains different parts such as 1⃣ OPTICAL DOME : This shape results in easy orientation axis along central axis of small intestine and also propel the capsule forward easily. 2⃣ LENS HOLDER : It is part of it which accomodates lens to fix tightly so that it doesnt get dislocated anytime. 3⃣ LENS : These are arranged behind light receiving window. 4⃣ ILLUMINATING LED'S: Placed around lens and CMOS image sensor, there are 4 LED 's are present arranged in donut shape. 5⃣ CMOS IMAGE SENSOR: It is highly sensitive and produces high quality images also detects object as small as 0.1mm. 6⃣ BATTERY : It is button shaped and in 2 numbers. Silver oxide as primary batteries. Such battery has