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It’s no secret that medical technology has come a long way in recent years. From 3D-printed organs to robotic surgery, the possibilities are endless. And while these advancements are incredible, they’re also widely unknown by the general public.
5 Medical Technologies You Didn’t Know Existed
3D Printing has been used extensively in medical and healthcare applications. One of the most common uses of 3D Printing in medicine is the creation of prosthetic limbs and other body parts. In recent years, significant advancements in 3D printing technology have made it possible to create more lifelike and functional prosthetics.
Another everyday use of 3D Printing in healthcare is the creation of models for surgical planning. By creating a three-dimensional model of a patient’s anatomy, surgeons can plan complex procedures with greater precision and accuracy. This can result in shorter surgical times, less tissue damage, and fewer complications.
3D Printing is also used to create custom patient implants and devices. Traditional manufacturing methods often cannot make the highly customized shapes and sizes required for certain implants or appliances. However, 3D Printing makes it possible to create these custom items quickly and easily.
Wireless EEG is a medical technology that allows the recording of electrical activity in the brain without requiring invasive surgery. This technology has many potential applications, including diagnosing and treating neurological disorders.
EEG (electroencephalography) is a technique for measuring electrical activity in the brain. Traditional EEG systems require the placement of electrodes on the scalp, which can be uncomfortable for patients and lead to hair loss. Wireless EEG systems solve this problem using wearable sensors that allow for comfortable, long-term recordings.
This system has been used to study various neurological conditions, such as epilepsy, Alzheimer’s disease, and sleep disorders. This technology is also being used to explore potential treatments for depression and anxiety.
The Intraoperative MRI
Intraoperative MRI (iMRI) is a relatively new technology that allows surgeons to obtain real-time information about the anatomy and physiology of the brain during surgery. You can use this information to guide surgical decision-making and improve surgical outcomes.
MRI systems typically have two main components: a magnetic resonance imaging (MRI) scanner and an operating room table compatible with the scanner’s magnetic field. The surgeon operates on the patient while lying on the table, which is then moved into the MRI scanner.
MRI offers many potential benefits over traditional preoperative imaging modalities, such as computed tomography (CT) and magnetic resonance imaging (MRI):
MRI provides real-time information about the brain during surgery, which can be used to guide decision-making. This can help surgeons avoid complications by allowing them to visualize critical structures in the brain before they are damaged or removed. In addition, MRI may improve surgical outcomes by providing more accurate information about the location of tumors and other lesions.
CyberKnife is a medical device that uses radiation to treat cancer. It is a non-invasive alternative to surgery and can be used to treat tumors in the brain, spine, lungs, liver, pancreas, and prostate. The CyberKnife delivers high doses of radiation directly to cancer while sparing the surrounding healthy tissue.
CyberKnife was FDA-approved in 2001 and has been used to treat over 750,000 patients worldwide. In most cases, the treatment takes place over 5-10 days. In addition, CyberKnife is cost-effective and has fewer side effects than traditional cancer treatments.
Printed bones are one of the many medical technologies that are available today. This technology creates implants and prosthetics made from a patient’s cells. The process begins by taking a 3D scan of the area that needs to be replaced. Then, using a particular printer, living cells are printed onto a biodegradable scaffold. Once the cells have been published, they are incubated until they form new tissue. This tissue is then implanted into the patient, which will continue to grow and develop like natural tissue.
Printed bones offer several advantages over traditional implants and prosthetics:
- Because they are made from the patient’s cells, there is no risk of rejection.
- You can customize printed bones to fit each patient perfectly.
- You can use this technology to repair or replace any bone in the body, regardless of its size or shape.
- You can create printed bones much faster than traditional implants or prosthetics, so patients will not have to wait as long to receive treatment.
These are just a few of the incredible medical technologies currently available. Each one has the potential to change lives for the better and make a real difference in people’s health and well-being.