Medicine and Health
That’s not easy to do, but this cutting-edge bionic ankle can do it
A new robotic ankle that is controlled by electrical signals in muscles below the knee is showing promise for making it easier to move and lessening pain. Seven people in a clinical trial testing the new device were able to walk as fast as people who weren’t amputees after just two practice sessions that lasted a total of six hours. Their bionic joints moved in ways that were similar to how their natural ankles moved.
It is simple to walk when you don’t believe it. Controlling something that seems so simple, like walking, is more complicated than just tightening the right muscles. It’s a complicated dance of feedback and control.
When you decide to take a step, your brain tells your spinal cord and legs to contract the muscles in those legs. This bends your joints. Two types of muscles—agonists and antagonists—work in opposite ways to control how each joint moves and where it is located.
Consider your arm. Whenever you bend your elbow, your biceps contracts, pulling your forearm closer to your upper arm. Your triceps, which are on the other side of your arm and are the enemy of this movement, are relaxing and letting it happen at the same time. In the opposite direction, when you stretch your arm, your triceps pull the forearm away, and your biceps relax their pull.
Your brain can figure out how bent your elbow is by reading the tension in both the biceps and the triceps. Proprioception, which means “the perception of yourself” in Latin, is the ability to feel this tension. This then tells your motor system what to do.
When you walk, your hip, knee, and ankle joints bend because your leg muscles work. You walk on uneven ground, slopes, and sticky mud, and each of these joints is in a different place at the beginning and end of each step. You may also face different amounts of resistance during each movement. This means that the brain can’t just send a “walk” command that works for everyone.
There’s a lot to think about when you walk
Leg amputees have lost a lot of muscle and nerves that control muscle contraction and proprioceptive nerves that let the body know how the movement is going. Walking is a lot to think about. New developments in prosthetic limbs are trying to bring back all of the commands and feedback.
Early prosthetic users could move their limbs by using a harness that they powered with their bodies. For example, to move their prosthetic hand, they would learn to move their shoulder. Then, better prostheses came out that controlled ankle joint movement by sending electrical signals to muscles in the upper leg.
Up until now, feedback signals weren’t being used, which made movements less flexible and less able to adapt to a changing environment.
Now there is a new kind of leg prosthesis called the agonist-antagonist myoneural interface (AMI) that promises to make walking smoother. That’s a lot to say. The AMI fixes proprioceptive signaling by linking the agonist and antagonist muscles back together. That way, the brain and the device can figure out how tight the two muscles are in a way that works like our biceps and triceps.
For people who have lost limbs below the knee, the first prosthetic of this type is a bionic ankle that lets the muscles of the shin and calf grow back together. Because the agonist and antagonist are linked again, the tension in the two muscles can be used to figure out how the joints are bending. This tension can be changed to fit different situations, such as stairs and sloped ground.
A decoder in the prosthesis can change the ankle’s flexion in real time, just like a real limb would. It was amazing how much the prosthesis’s ankle moved like a normal person’s when they walked.
What’s next for the legs that don’t work? The sense of smell. The authors talk about studies that show prosthetics work better when they are attached to the bone, or ossum in Latin. Bionic limbs are getting farther away from just moving like real limbs and toward also feeling like real limbs.
Nature Medicine has written about the study.
Medicine and Health
A recently identified strain of deadly fungus poses a significant risk to public health
Researchers have recently discovered a new group of Candida auris, a potentially dangerous pathogen. The finding increases the total number of identified clades of the fungus, which is a newly emerging superbug resistant to multiple drugs, to six.
Candida auris is a strain of yeast that has the potential to cause serious illness and is frequently impervious to antifungal drugs. While individuals who are in good health generally do not fall ill, the transmission of the disease is highly prevalent within medical institutions and poses a significant risk to individuals with compromised immune systems. The yeast can induce a variety of conditions ranging from superficial infections of the skin to more severe and life-threatening illnesses, such as bloodstream infections. Due to its high level of resistance to multiple drugs, treating it can be challenging, and in some cases, even impossible.
The authors state that the pathogen is a significant global public health threat due to its widespread distribution, resistance to multiple drugs, high ability to spread, tendency to cause outbreaks, and high mortality rate. Although infections are still relatively uncommon, there has been a significant increase in cases in recent years.
Previously, the fungus had been categorized into five distinct clades, each located in different geographic regions: South Asia, East Asia, Africa, South America, and Iran.
In April 2023, doctors from the Singapore General Hospital identified a patient carrying a unique strain of C. auris as part of a routine screening program, adding it as the most recent clade to be discovered. Typically, these cases arise from individuals who have recently traveled, but this particular patient had not traveled outside the country for a period of two years, which raised some concerns.
Upon conducting a genetic analysis of the strain, the researchers determined that it did not align with any of the five known clades of the fungus. Therefore, it can be concluded that the strain belongs to a previously unidentified, sixth clade. Subsequently, they conducted tests on strains obtained from previous patients and identified two additional isolates of this particular group of C. auris in Singapore, as well as another isolate in Bangladesh.
The extent of the new clade’s prevalence and its potential to cause invasive infections and outbreaks remains uncertain at present. However, the researchers emphasize the importance of promptly identifying and controlling it in order to safeguard patient well-being.
“The ramifications of this breakthrough transcend the confines of the laboratory.” “Given the recent discovery of the sixth Candida auris clade, it is imperative to enhance surveillance capability or create new methods to strengthen existing surveillance strategies. This will enable health care facilities to closely monitor its emergence and effectively control its spread,” stated Dr. Karrie Ko, co-first author of the study.
Fortunately, the cases described in the study remained vulnerable to all antifungals that were tested. This should alleviate concerns about a pandemic similar to the one depicted in The Last Of Us. However, it is evident that the threat of C. auris is persistent. Therefore, additional efforts are required to identify new strains, monitor their spread, and control any negative clinical consequences.
The research is published in The Lancet Microbe journal.
Medicine and Health
What makes your chest hurt when something makes you jump?
Have you ever been scared so badly that you grabbed your chest? You feel like someone or something just zapped you behind the sternum. As you rest, you lean against the wall and think about why your friend is such a jerk and why you can feel it in your chest whenever you get scared.
People often use words like “heart-stopping” when they write fiction about fear, but the science of fear tells us that this isn’t what’s happening because it wouldn’t make sense. Our bodies are getting ready to deal with an impending threat when we’re scared, and going into cardiac arrest wouldn’t help us get very far if a lion was after us.
What do we do when we’re scared?
The sympathetic nervous system is what gets you excited when something makes you jump. It’s a tool inside our bodies that releases hormones and changes the way our bodies work to get us ready for the fight-or-flight response.
One important part is adrenaline, which is also known as epinephrine. The adrenal glands squeeze it out into the blood. The heart starts beating faster, sending more blood to your muscles and organs right away. Because they need all the oxygen they can get if they want to get away from a dangerous animal.
How do you feel when you go for a run?
Anyone who has ever used an EpiPen knows how bad it is to feel a sudden rush of adrenaline. It’s a stress hormone that makes you feel nervous and anxious, like you would before doing a bungee jump. Getting a rush when you think about a traumatic event from the past can be a sign of PTSD.
A medicine called adrenaline is used because it can help people who are having a medical emergency. If you have anaphylaxis from an allergen like peanuts, this can help because it can open your airway. Because it changes the strength and speed of heartbeats, it is also sometimes used to help people who are having a cardiac arrest.
When your adrenaline level goes up quickly, you may feel shaky, your heart beat quickly, and your chest get tight. When you add in the fact that you’re more alert, you become very aware of the changes in your body. This is especially clear when you’re not in danger, like when your partner surprised you at home when you thought you were alone.
When you’re scared, your sympathetic nervous system usually kicks in, which is normal. But, some heart conditions can get worse when you’re scared. Should anyone be having chest pain or ongoing discomfort, they should see a doctor. In the end, it is possible to be so scared that you die.
This article is not meant to be a replacement for medical advice, diagnosis, or treatment from a trained professional. If you have questions about a medical condition, you should always talk to a qualified health professional.
Medicine and Health
The Lacks family is suing again over her “stolen” cells
The family of Henrietta Lacks has filed a new lawsuit against two sizable drug companies for using her genetic material without her consent.
In the US District Court for the District of Maryland, Lacks’ living relatives are suing Novartis Pharmaceuticals Corporation, Novartis Gene Therapies, Inc., Viatris, Inc., and its subsidiary, Mylan Pharmaceuticals. They say the companies have used the “stolen” HeLa cell line to make hundreds of patents and have made a lot of money from it.
The suit wants the money made from using these cells to be “rightfully transferred” to Henrietta Lacks’s estate.
Novartis and Viatris chose to sell Henrietta Lacks’ living genetic material. Lacks was a black grandmother, community leader, and woman whose doctors took her tissue without her knowledge or permission, according to Chris Ayers, an attorney at Seeger Weiss LLP who is representing the Lacks family.
Ayers added, “We will keep looking for justice for Mrs. Lacks and her family.”
Henrietta Lacks died on October 4, 1951, from cervical cancer. She was 31 years old. Some of her cells are still alive today. A doctor at Johns Hopkins Hospital took a sample of her cervical cells without her knowledge just before she died. They were doing a cancer check. It was seen that her cells kept multiplying quickly, even after most of the cells in other samples would have died without their host.
Because scientists saw the potential, they found that these cells could be a cheap and easy way to help researchers do more research. The “HeLa immortal cell line” is what scientists call these cells, and they are very useful for biomedical research.
Over 75,000 scientific studies around the world have used these cells, which amount to about 55 million tons. They have been very important in making progress in areas like polio vaccines, cancer treatments, HIV/AIDS treatments, and much more.
All of this was done, though, without Lacks’ knowledge or permission. For many years, her family also didn’t know that the cells were being used for business.
Selling HeLa cells for money brings up important issues in medical ethics and genetics. As a black woman living in America in the 1950s, Lacks’ case shows how medical racism still affects minorities who aren’t getting enough help.
Even though a lot of people know about these problems, HeLa cells are still used in medical research for profit, which makes some companies a lot of money.
“Now that everyone knows Henrietta Lacks’ story, it’s shocking, but not surprising, that drug companies like Novartis and Viatris are still making money off of the deeply unethical origins of HeLa cells and the disturbing history of medical racism,” said Chris Seeger, another lawyer for the family.
A historic deal was made by Lacks’ family in 2023 after they sued Thermo Fisher Scientific, Inc., another biotech company, in the US District Court for the District of Baltimore. During that time, the lawyers said that the settlement was only the beginning and that there could be many more lawsuits about the use of HeLa cells.
- Gadgets10 years ago
Why the Nexus 7 is still a good tablet in 2015
- Mobile Devices10 years ago
Samsung Galaxy Note 4 vs Galaxy Note 5: is there room for improvement?
- Editorials10 years ago
Samsung Galaxy Note 4 – How bad updates prevent people from enjoying their phones
- Mobile Devices9 years ago
Nexus 5 2015 and Android M born to be together
- Gaming10 years ago
New Teaser For Five Nights At Freddy’s 4
- Mobile Devices9 years ago
Google not releasing Android M to Nexus 7
- Gadgets10 years ago
Moto G Android 5.0.2 Lollipop still has a memory leak bug
- Mobile Devices9 years ago
Nexus 7 2015: Huawei and Google changing the game