It’s that time of the year when we call on technological visionaries, medical futurists, and creative people of all kinds to submit medical science fiction stories to our annual Medgadget Sci-Fi Writing Contest. At Medgadget, we keep a record of the progress of medical technologies and hope to inspire you to imagine a future where medicine is able to do things that are currently deemed impossible or, even better, have not yet been imagined.

Medicine, and the people that work within this field, can be influenced by new ideas and technologies, and we hope participants in our writing contest will investigate how that happens and what it can lead to, both in good or not so good ways. Science fiction can entertain, certainly, but it can also help us face important issues and prepare for changes before they suddenly arrive. We hope our contest can help do that.

Many science fiction writers of the past have focused on space travel, surveillance, robotization, artificial intelligence, and how societies will change in the distant future. We encourage our contest’s participants to look into the future of medicine with the same excitement, skepticism, and hope as sci-fi writers did.

Here are the rules:

• Your original fictional essay has to be 250-2500 words of English language emailed to scifi@medgadget.com and marked as “Sci-Fi Writing Contest” entry.
• Top entries will be printed here and, therefore, must be safe for work and families. Please keep the language clean.
• Judges will be blinded. Blinded by your dazzling prose, yes, but also to your identity. We are assembling an all-star judging panel, including Medgadget editors, so you can be assured your work will be reviewed by accomplished writers, physicians, and a few fans of the Blade Runner.
• Submissions from anonymous writers are accepted, but we will need an address or PO Box to send you your prize!
• This year’s top winner will receive from us a gift, the very impressive Eko digital stethoscope that we recently reviewed.
• Second and third place winners will each receive a $50 Amazon gift card.
• Entries are due on November 19th. Winners will be announced, and stories reprinted here on Medgadget, on December 3rd. Send in your submissions to: scifi@medgadget.com.

That’s it! Get your thinking and imagination caps on and start typing! Feel free to browse our archives … for inspiration.

Flashback: Medgadget Sci-Fi Contest 2017: Meet The Winning Stories

Product page: Eko CORE Digital Stethoscope…

Mental illness can be notoriously difficult to diagnose in many cases, since symptoms may be invisible to physicians and those that are can be misleading. Objective methods that don’t rely on a direct observation would help to improve diagnosis.

Researchers at Draper, the famous engineering firm in Cambridge, Massachusetts, have developed a system consisting of a number of different sensors that work together to analyze various vital signs and physical parameters to help with screening, diagnosing, and monitoring mental health conditions. The sensors include headset, wrist bands, and an ankle bracelet.

The system keeps track of a person’s heart rate, levels of sweating, respiration rate, and diameter of pupils. These data are brought together and crunched by computer algorithms, which will still probably need more work, to give a clinician some basic guidance.

Called SysteMD (System with Sensors to Evaluate Mental Disorders), the prototype product has already been tried in pilot studies with people suffering from PTSD and depression. It was able to accurately diagnose between 82% and 94% of PTSD casses correctly, a pretty impressive achievement. “With that level of accuracy, SysteMD shows promise for making a lasting impact on patients with mental illness—by enabling accurate diagnosis, supporting efficient treatment and ensuring effective monitoring over time,” said Andrea Webb, PhD, a principal scientist at Draper. “We believe technology can augment current clinical practice by enabling psychophysiological measurement as a diagnostic aid and evaluation tool in the treatment of mental health disorders.”

Via: Draper…

Canon Medical won FDA clearance to bring to the U.S. market its brand new Vantage Orian 1.5 Tesla MRI scanner. It features a wide 71 centimeter bore and quiet operation thanks to its Pianissimo and Pianissimo Zen technologies. Pianissimo makes all scanning sequences quieter, while Pianissimo Zen allows certain scans to be performed at near ambient noise levels. To help young patients and those uncomfortable inside a scanner, Canon offers an immersive virtual experience called MR theater that combines audio and video to keep the person’s attention on something other than the scan.

The scanner was developed to maximize productivity and lower operating costs. Rapid Scan, an offering built into the scanner, allows many scans to be performed faster than before. The ForeSee View planning tool helps to prepare for scans to make sure rescans are not necessary. Additional technologies allow for cardiac and perfusion scans without the patient having to hold the breath.

“We are committed to offering our customers the premium diagnostic imaging tools they need to deliver accurate, confident and effective patient care,” said Dominic Smith, senior director, CT, PET/CT and MR Business Units, Canon Medical Systems USA, Inc. “The Vantage Orian was designed to increase productivity while ensuring patient comfort and delivering uncompromised clinical confidence.”

Here’s a Canon video of the new device when it was unveiled at the European Society of Radiology annual gathering earlier this year:

Product page: Vantage Orian…

Via: Canon Medical…

At the just concluded American Heart Association’s Scientific Sessions 2018 in Chicago, Eko, the makers of popular digital stethoscopes, showed off a neural network AI algorithm that is able to detect murmurs better than a group of cardiologists. The study, titled “Artificial Intelligence Detects Pediatric Heart Murmurs With Cardiologist-Level Accuracy,” involved teaching a computer to spot suspicious murmurs by first giving it thousands of previously diagnosed sound recordings. The computer analyzed these for unique audio signatures and found enough nuances to be able to identify murmurs in a sample auscultation.

This important, as general practice and internal family physicians routinely misdiagnose murmurs at an incredible rate. Access to cardiologists is limited, so an automated system that can help during regular screenings can go a long way. Moreover, this is an excellent sign that machine learning and other AI techniques can really help with daily medical care by bringing virtual experts in different fields to the doctor’s office.

The software can be coupled with Eko’s Core and Duo digital stethoscopes, so it only takes a regulatory approval to introduce the technology into clinical practice.

Via: Eko…

Diabetic foot ulcers are common maladies that are difficult to heal. In many cases, a total-contact cast is put on the leg with the ulcer to take the pressure off of the bottom of the foot, helping it to heal. While this is effective, supplying oxygen to the ulcer also helps it to heal. This is difficult to do when a patient wears a cast, but researchers at Purdue University have come up with a solution that just might work.

The research team has developed special insoles that contain pockets of oxygen near the site of the ulcer. These reservoirs slowly release the oxygen gas onto the insole, and are designed to be used along with a cast.

In order to personalize each insole and to control the release of the oxygen, the silicone-based rubber material of which they’re made of can laser machined individually. This allows the oxygen pockets to be placed exactly where they’ll come in contact with an ulcer, and the permeability of the silicone can also be adjusted to control the flow of oxygen.

Here’s a video that gives a glance at how the new insoles are created:

Study in Materials Research Society Communications: A laser-customizable insole for selective topical oxygen delivery to diabetic foot ulcers…

Via: Purdue…

Researchers at Washington University in St. Louis have developed a diagnostic method involving photoacoustic imaging, a technique that combines ultrasound and laser light. The development may allow clinicians to diagnose ovarian cancer earlier, helping to save lives.

“When ovarian cancer is detected at an early, localized stage – stage 1 or 2 – the five-year survival rate after surgery and chemotherapy is 70 to 90 percent, compared with 20 percent or less when it is diagnosed at later stages, 3 or 4,” said Quing Zhu, a researcher involved in the study. “Clearly, early detection is critical, yet due the lack of effective screening tools only 20–25 percent of ovarian cancers are diagnosed early.”

Transvaginal ultrasound allows clinicians to see ovarian masses, but doesn’t allow them to tell if what they are viewing is a neoplastic tissue. The new technique, however, combines ultrasound with photoacoustic imaging, where laser light penetrates the vaginal wall to illuminate the vascular bed in the ovaries.

This allows clinicians to investigate the vasculature of the structures, and assess clinically relevant parameters such as tumor angiogenesis and blood oxygen saturation. Typically, ovaries bearing tumors will have extensive blood vessels and lower blood oxygen saturation compared with healthy ovaries. Aside from helping clinicians to identify a tumor, these parameters also relate to tumor metabolism, growth, and the potential of a tumor to respond to treatment.

The Washington University research team designed a specialized vaginal probe with a sheath containing laser-connected optical fibers that wrap around an ultrasound probe. Using the probe in a pilot study involving 16 patients, the researchers found hallmark increases in angiogenic markers and reductions in blood oxygen saturation in a common type of ovarian tumor, including early stage tumors.

“Physicians are very excited about this because it might bring significant change into current clinical practice,” said Zhu. “It is very valuable to detect and diagnose ovarian cancers at early stages. This technology can also be valuable to monitor high-risk patients who have increased risk of ovarian and breast cancers due to their genetic mutations.”

Based on these initial promising results, the researchers are applying for funding to conduct a large clinical trial, and hope to validate the technology in a larger group of patients.

See a video about the project below.

Study in Radiology: Evaluation of Ovarian Cancer: Initial Application of Coregistered Photoacoustic Tomography and US…

Via: Washington University in St. Louis…

Birds and many other animals are able to perceive the Earth’s magnetic field, an ability that allows them to navigate around the world with magical ease. Scientists at Helmholtz-Zentrum Dresden-Rossendorf (HZDR), a research center in Dresden, Germany, have developed an electronic skin that can give humans the same capability. The new technology may end up being used to help blind people move around their environment, and to assist those with vertigo and other orientation issues. Moreover, it may prove useful as a basis for an intuitive way to interact with computers, virtual and augmented environments, and to control robotic equipment.

The e-skin consists of a a polymer foil with magnetic field sensors sensitive enough to detect the Earth’s magnetic field. This is an impressive achievement, since a typical fridge magnet generates a magnetic field roughly 1,000 times stronger in its vicinity. The e-skin is very flexible, and so can be attached to the hand or other parts of the body. It was tried as a joystick, of sorts, to control the movements of an avatar within a virtual world, and it worked remarkably well.

Next steps will involve integrating the new sensing capability with other technologies in order to make practical use of the new sensor. Thanks to this and other technologies, we may soon see blind people walking around on their own with remarkable ease and independence that is still not fully possible.

More from Helmholtz-Zentrum Dresden-Rossendorf:

The sensors, which are ultrathin strips of the magnetic material permalloy, work on the principle of the so-called anisotropic magneto-resistive effect, as Cañón Bermúdez explains: “It means that the electric resistance of these layers changes depending on their orientation in relation to an outer magnetic field. In order to align them specifically with the Earth’s magnetic field, we decorated these ferromagnetic strips with slabs of conductive material, in this case gold, arranged at a 45-degree angle. Thus, the electric current can only flow at this angle, which changes the response of the sensor to render it most sensitive around very small fields. The voltage is strongest when the sensors point north and weakest when they point south.” The researchers conducted outdoor experiments to demonstrate that their idea works in practical settings.

Study in Nature Electronics: Electronic-skin compasses for geomagnetic field-driven artificial magnetoreception and interactive electronics…

Via: HZDR…

L’Oréal, the big skin care company, has just released a tiny device for monitoring skin’s exposure to the sun. Offered through Apple’s online shop and at some of its physical stores, the La Roche-Posay My Skin Track UV device doesn’t use any batteries while being able to upload its readings to a paired smartphone.

The energy of the sun is used to store the data within the device, while near-field communication (NFC) is used to download the readings to the smartphone. Downloads are activated by simply tapping the device against the paired smartphone and the user can then use the app to review how much time was spent exposed to dangerous UV light. In addition to this personalized data, the app includes pollen, humidity, and pollution levels that it gathers from online sources.

“Our research has long indicated the need for better consumer understanding of personal UV exposure,” in a statement said Guive Balooch, Global Vice President and Head of L’Oréal’s Technology Incubator. “We created this battery-free sensor to seamlessly integrate into the lives, and daily routines, of those using it. We hope the launch of this problem-solving technology makes it easier for people to make smart, sun-safe choices.”

The device is only 12 mm X 6 mm, is waterproof, and has a clip so that it can be attached to hats, shirts, and bracelets.

Here’s a promo video for the La Roche-Posay My Skin Track UV:

Product page: La Roche-Posay My Skin Track Sensor…

Via: L’Oréal…

EyeQue, a company based in Newark, California, is releasing a vision testing system that you can use at home to test your eyes with the help of a smartphone.

The EyeQue VisionCheck personal vision tracker snaps onto the screen of a smartphone and the user simply places it against the eye to perform the testing. The accompanying app displays various images on the screen and while the user looks at those, an internal motor rotates a series of lenses that work together to measure the eye’s focus and astigmatism, and so the refractive error. A special tool built into the app also helps to measure the distance between the pupils. Using the results, the patient can obtain prescription glasses as the system is as accurate as necessary for that application. It provides the spherical, cylindrical, and axis figures that are needed to make the glasses.

The VisionCheck device relies on the Inverse Shack Hartmann optical method and the eye measurement technology was patented originally at MIT.

EyeQue hopes that its device, which is currently available for preorder for $60, will help people to save on prescription glasses, particularly those whose eyesight keeps changing on a regular basis.

Product page: EyeQue VisionCheck…

Via: EyeQue…

Researchers at the National Eye Institute in the U.S. have developed a retinal imaging technique that reveals live neurons, blood vessels, and epithelial cells within the retina. The method involves combining adaptive optics and angiography, and allows the researchers to view complex units of cells that interact in the outer edge of the retina. As this retinal region is involved in a range of diseases, including atherosclerosis, age-related macular degeneration (AMD), and Alzheimer’s disease, the researchers hope that the technique could help with diagnosis and disease monitoring.

“For studying diseases, there’s no substitute for watching live cells interact,” said Johnny Tam, a researcher involved in the study. “However, conventional technologies are limited in their ability to show such detail.”

Post-mortem tissue samples and tissue biopsies are frequently used to study cellular characteristics in disease. However, such samples provide only a rough approximation of living tissue and make it difficult to monitor disease progression over time. A non-invasive method to accurately monitor living cells in the retina has not been available, partly because light becomes distorted as it passes through the eye.

To help overcome this issue, the researchers employed adaptive optics, a technique which is used in space telescopes, and which involves deformable mirrors and computer algorithms to correct for light distortion. The researchers combined this optical technique with angiography, which involves injecting a dye into the blood, and then using a camera to image the blood vessels within the retina.

The new technique resulted in high-resolution images of the retina that allowed the researchers to observe features in real time that had never been seen before in living retinal tissue, including complex units of epithelial cells, photoreceptors, and capillaries.

The approach has potential in helping to diagnose and understand a variety of diseases. The research team tested the imaging technique in a patient with retinitis pigmentosa, and discovered that the photoreceptors had died in specific regions of the retina, but that retinal pigment epithelial cells (RPE cells) and capillaries were still intact in these regions.

“In the past, we have not been able to reliably assess the status of photoreceptors alongside RPE cells and choriocapillaris in the eye,” said Tam. “Revealing which tissue layers are affected in different stages of diseases – neurons, epithelial cells, or blood vessels – is a critical first step for developing and evaluating targeted treatments for disease.”

Top image: Photoreceptors (left), retinal pigment epithelial cells (center), and choriocapillaris in the living human eye.

Study in Communications Biology: Combining multimodal adaptive optics imaging and angiography improves visualization of human eyes with cellular-level resolution…

Via: National Eye Institute…

Losing one’s memories, and therefore one’s identity, must be a terrifying experience. With a global estimate of almost 50 million people living with dementia, predicted to rise to more than 130 million by 2050, the burden of Alzheimer’s and dementia are indisputable. While there are still no approved drugs for the treatment of Alzheimer’s, there is an urgency for developing diagnostic tests and the identification of biomarkers that enable the early detection of the disease. In light of this need, diagnostic technology company IQuity (pronounced I-Q-witty) has recently received a grant from the National Institutes of Health (NIH) to build a platform around the early detection of Alzheimer’s. We sat down with IQuity’s Founder and CEO, Dr. Chase Spurlock, to talk about this effort and the company’s progress with other diseases they have tackled.

Mohammad Saleh, Medgadget: Tell us about yourself and how you came to be a part of this work.

Chase Spurlock, IQuity:  I’m the CEO of IQuity, a tech company based in Nashville using data science to detect and monitor disease. At IQuity, we can use a variety of data sources – ranging from blood samples to large, population-level healthcare datasets including insurance claims or electronic health records to identify disease and help optimize patient journeys. A large portion of my work has focused on autoimmune diseases through research initiated at IQuity and through my faculty position at Vanderbilt. Autoimmune diseases affect you and someone you know – these are conditions like multiple sclerosis, rheumatoid arthritis, Crohn’s disease and others where the immune system harms the body’s tissues and organs. We can’t cure these diseases, but we can treat them. If we can detect the disease early, we have the best chance for optimal long-term outcomes including reduced disability and longer life expectancy.

The first demonstration of our use of data science to build tools to help providers diagnose and treat these illnesses was to create blood-based tools that doctors can use to make fast, accurate diagnoses. We created a platform that looks at RNA data, a real-time snapshot of what’s taking place inside the patient’s blood cells, and then builds computer models to allow us to examine new patient samples and ask if they look like patients with specific diseases we may have seen before. To date, we have commercialized three tests leveraging our technology for multiple sclerosis, IBS (irritable bowel syndrome) and IBD (Crohn’s disease and ulcerative colitis), and fibromyalgia syndrome.

Apart from our blood-based studies, we began using our disease knowledge and data science expertise to look at large, population-level datasets to see if we could craft similar insights that enable early disease detection and patient monitoring. Layering claims data with datasets that help us understand the social determinants of health, we have been able to mirror our blood testing work and create a technology that enables faster disease detection, correction of misdiagnosis and the ability to monitor patient disease at scale. Monitoring is critical to ensure that treatment plans remain effective and prevent adverse events. Our approach makes it possible to alert care teams so that interventions can occur faster than is conventionally possible today.

As we look to the future and the broad applicability of our technology, we began exploring whether we could use our blood-based approach or population analytics platform to tackle new disease indications. Alzheimer’s disease quickly rose to the top of the list because this fatal neurodegenerative disease affects over five million Americans and often goes unnoticed until symptoms manifest 15-20 years after the damage to the brain starts. We feel that our approach using blood-based technology for population-level analytics holds extraordinary potential to make an indelible mark on how clinicians can approach Alzheimer’s care in the years ahead.

Medgadget: Can you give our readers a quick overview of what the current status of Alzheimer’s early detection and drug research is?

Spurlock: We need tools that can accelerate the diagnosis of Alzheimer’s disease – whether these innovations come in the form of biomarker development, digital technologies, or a combination of the two. Both approaches will allow us to understand how the disease develops and progresses, the patient populations affected by Alzheimer’s and provide opportunities to refine future clinical trials by enhancing patient recruitment efforts. There are no approved treatments that can slow the progression of Alzheimer’s disease – they are primarily used to treat symptoms and are useful for only a short window of time. In the future, approved drugs for Alzheimer’s will be most effective when administered early. The diagnostic tools we have proposed to develop through our NIH-funded studies seek to identify patients at the earliest stages of the disease and could potentially be used in clinical trials to assess treatment responses. If we can identify patients early and include them in clinical trials, we will have a better chance of finding therapeutics that can alter the trajectory for this devastating condition.

Medgadget: What makes IQuity uniquely adept at​ tackling this problem?

Spurlock: At IQuity, we have successfully commercialized tools that can be used to identify disease. Using multiple sclerosis (MS) as an example, we have shown that we can identify patterns in blood at the time of a clinically isolated syndrome, which is the major clinical precursor to MS. In MS and fibromyalgia, have shown us that these long non-coding RNAs (lncRNAs) exhibit high levels of disease-type specificity meaning that lncRNA patterns measured in blood are often specific for one disease and can be used to differentiate among similar conditions and healthy individuals. The preliminary studies that we outlined in our recent Alzheimer’s grant highlight the utility of these biomarkers to distinguish Alzheimer’s disease from other neurological illnesses.

As an expansion of our work in genomics, we are eager to explore the use of the longitudinal health records in our population datasets (insurance claims data or electronic health records) to assess whether our existing data science approaches could be applied to identify early patterns for Alzheimer’s. These efforts will help us understand environmental, racial or other social factors that can explain how this disease may arise and could lead to opportunities for early intervention.

Across both areas of our business, I believe IQuity is uniquely poised to make discoveries that can improve diagnostic tools, inform pharmaceutical development and enhance the quality of life for patients living with many diseases. While autoimmune conditions have traditionally been our focus, the opportunities to help patients with a variety of medical conditions, including Alzheimer’s, are possible with the infrastructure we have put in place.

Medgadget: Can you tell us about​ the technology driving the Alzheimer’s detection efforts? How does it work and where does machine learning factor in?

Spurlock: The funding we recently received will support our work to identify and measure lncRNA found in blood and build software capable of detecting specific RNA patterns for Alzheimer’s disease. RNA-sequencing will allow us to identify candidate RNAs we will then validate in a larger cohort of Alzheimer’s patients, disease controls and age-matched healthy controls. Data derived from this expanded cohort will then be used to train machine learning models to determine if these biomarkers can be used to construct a specific blood-based pattern for Alzheimer’s. Independent blood samples not included in the training will be used to test if the model can accurately and reproducibly distinguish among these groups. This work will consist of patients from across the United States, allowing us also to examine if geography can influence the expression of the RNAs we identify.

What’s interesting about this approach is that machine learning helps us identify the RNAs present in a blood sample that hold the highest level of ‘predictive power’ and determine among those we select which RNAs are more or less important in determining the presence of Alzheimer’s or any other disease we choose to study. While we are explicitly using our approach to build diagnostic strategies to identify presence or absence of disease, use of these methods could uncover novel targets for therapeutic intervention if these biomarkers are found to change as a consequence of intervention.

Medgadget: Can you maybe share some specific success stories? How accurate has the platform been so far?

Spurlock: Pilot funding from the NIH will be used to launch our Alzheimer’s work. It will allow us to expand our focus beyond the company’s traditional emphasis on autoimmune disease to test if our approach can be used to detect Alzheimer’s accurately. What we have documented thus far is that our blood tests are more than 90 percent accurate for the autoimmune and related conditions that we’ve examined.

Medgadget: Do you think work like IQuity’s early detection efforts for Alzheimer’s can lead to a renewed interest in searching for therapeutics for Alzheimer’s?

Spurlock: Absolutely. If we can identify these diseases early using genomics or population-level analytics, we will have a series of useful tools that can help determine the right patients for clinical trials. Identifying these patients at the earliest moment means they can take an investigational drug and have the best chance to reap the benefit of these new therapeutics. As Bill Gates and the Alzheimer’s Drug Discovery Foundation have correctly stated many times, the new drugs currently under development will be most successful in slowing early Alzheimer’s. All too often, patients who develop Alzheimer’s are caught many years after the disease has already caused damage to the brain.

If we can identify diagnostic biomarkers, we can better understand the genetics of how these diseases manifest and begin to understand, at a molecular level, the mechanistic underpinnings of the disease and create targeted assays that can look for these changes. Using population-level analytics to ask these same types of questions, we can begin pinpointing the social determinants of disease and from these studies further refine the inclusion and exclusion criteria for clinical trials. The combination of molecular and population analytics, I believe, will enable us to understand better the types of patients who ultimately arrive at an Alzheimer’s diagnosis and create a window for early intervention.

Medgadget: Where do you see IQuity in the next 5-10 years with your work in Alzheimer’s and other areas?

Spurlock:  IQuity’s future is very bright. We’re at a significant inflection point in healthcare where we are starting to see artificial intelligence/machine learning tools implemented more often for clinical use. At IQuity, we are creating a series of platform technologies that we can apply to many areas of human health and disease. While we have focused on autoimmunity and related disorders, we have found that our blood-based and population-level analytics can affect many conditions. The work we’ve done has shown that we can predict oncoming diagnoses, spotlight misdiagnoses, and stratify severity of disease. A unique aspect of our approach is the ability to trigger not only an alert, but embed a context or reasoning into each alert that helps those receiving this information understand how our tools arrived at a result. I think this level of insight is going to be at the heart of how we can positively shape healthcare to make the patient experience better, improve outcomes and lower healthcare costs.

Medgadget: When should we expect to be hearing more data about IQuity’s Alzheimer’s efforts?

Spurlock:  The focus of this project hits close to home for many on our team. My own family has witnessed firsthand the negative consequences of early Alzheimer’s and dementia. We often wondered if we could have done something differently to recognize or treat the underlying causes of the disease – but it just wasn’t possible. There remains so much work to be done to make this a reality. At IQuity, the second we received funding we immediately began work. Our laboratory efforts are underway to refine the biomarkers we have already identified, and I would expect data to emerge in the next several months that we intend to share at conferences or in peer-reviewed journals.

For more information, check out IQuity’s website or read our previous interview.

Diabeloop, a company based in Grenoble, France, won the European CE Mark of approval for its DBLG1 blood sugar management system for type 1 diabetics.

The system combines data gathered from a continuous blood glucose monitor and smart algorithms to drive the activation of an insulin pump. The system can predict glucose levels based on its continuous learning capability that adjusts to each individual patient.

It’s essentially the brains of a closed-loop system that replicates the functionality of a pancreas.

“We are proud to have passed the regulatory step of the CE marking. Our commercial deployment will be gradual in order to ensure quality of our product and our service towards the patients. We will also keep working for the reimbursement of our system as soon as possible” said Erik Huneker, co-CEO and founder of Diabeloop. “With this certification, we’re getting closer to the market launch and will move towards a new funding round to support our international scaling and our ambitious R&D roadmap. We hope to do all that by the second quarter of 2019” added Marc Julien, Diabeloop co-CEO and CFO.

Product page (in French): DBLG1 System…

Via: Diabeloop…

It’s that time of the year when we call on technological visionaries, medical futurists, and creative people of all kinds to submit medical science fiction stories to our annual Medgadget Sci-Fi Writing Contest. At Medgadget, we keep a record of the progress of medical technologies and hope to inspire you to imagine a future where medicine is able to do things that are currently deemed impossible or, even better, have not yet been imagined.

Medicine, and the people that work within this field, can be influenced by new ideas and technologies, and we hope participants in our writing contest will investigate how that happens and what it can lead to, both in good or not so good ways. Science fiction can entertain, certainly, but it can also help us face important issues and prepare for changes before they suddenly arrive. We hope our contest can help do that.

Many science fiction writers of the past have focused on space travel, surveillance, robotization, artificial intelligence, and how societies will change in the distant future. We encourage our contest’s participants to look into the future of medicine with the same excitement, skepticism, and hope as sci-fi writers did.

Here are the rules:

• Your original fictional essay has to be 250-2500 words of English language emailed to scifi@medgadget.com and marked as “Sci-Fi Writing Contest” entry.
• Top entries will be printed here and, therefore, must be safe for work and families. Please keep the language clean.
• Judges will be blinded. Blinded by your dazzling prose, yes, but also to your identity. We are assembling an all-star judging panel, including Medgadget editors, so you can be assured your work will be reviewed by accomplished writers, physicians, and a few fans of the Blade Runner.
• Submissions from anonymous writers are accepted, but we will need an address or PO Box to send you your prize!
• This year’s top winner will receive from us a gift, the very impressive Eko digital stethoscope that we recently reviewed.
• Second and third place winners will each receive a $50 Amazon gift card.
• Entries are due on November 19th. Winners will be announced, and stories reprinted here on Medgadget, on December 3rd. Send in your submissions to: scifi@medgadget.com.

That’s it! Get your thinking and imagination caps on and start typing! Feel free to browse our archives … for inspiration.

Flashback: Medgadget Sci-Fi Contest 2017: Meet The Winning Stories

Product page: Eko CORE Digital Stethoscope…

Edwards Lifesciences received European CE Mark approval for its SAPIEN 3 Ultra transcatheter aortic heart valve. Indicated for valve replacement in patients with severe, symptomatic aortic stenosis, the device is available in three sizes (20 mm, 23 mm, and 26 mm) to fit most anatomies. It sports modifications to the valve itself, as well as an all-new delivery system and sheath, in order to be able to treat patients for whom other transcatheter aortic valve systems are not appropriate.

The SAPIEN 3 Ultra features an extended skirt on its exterior that helps to avoid leakages and a 14-French low profile sheath. The delivery system uses an “on balloon” design that doesn’t require the surgeon to have to manually align the artificial valve with the native anatomy. This helps to speed up procedures, reducing risks for patients and saving money for hospitals.

“The SAPIEN 3 Ultra system incorporates enhancements to the valve, as well as a new delivery system, which are designed to further build on the exceptional outcomes of the SAPIEN 3 valve, which has shown extremely low rates of mortality and disabling stroke,” in a statement said Larry L. Wood, Edwards’ corporate vice president, transcatheter heart valves. “With the SAPIEN 3 Ultra system, we are building on our best-in-class performance to further advance and improve patient care.”

The device is not yet approved in the U.S. and its launch in Europe is under question. Here’s some details according to Edwards:

As previously announced, Edwards will introduce the SAPIEN 3 Ultra system in Europe as part of a controlled rollout, which includes training, to ensure high procedural success of this advanced valve and delivery system.

The SAPIEN 3 Ultra system will not be launched at this time in Germany, as a result of the preliminary injunction that Boston Scientific chose to implement in the country. Edwards is disappointed in Boston Scientific’s tactic to limit access of this new therapy.  The German court will hold a full hearing on the merits of the dispute in mid-2019, and Edwards continues to believe that it will ultimately prevail in this matter. The SAPIEN 3 and CENTERA valve systems remain available in Europe. The German case pertains to a European patent that Boston acquired in 2017 (No. EP 2 949 292).

Via: Edwards…

Safe and powerful biofuel cells may help power future medical implantables, and researchers at Georgia Institute of Technology and Korea University are helping to make that happen. The team of collaborators has developed a glucose-powered fuel cell that relies on gold-infused cotton fibers to achieve a new level of efficiency for such devices.

Gold nanoparticles are embedded within cotton thread that is made functional thanks to a glucose-oxidase coating, resulting in highly electrically conductive electrodes that are biocompatible and very stable. Because the glucose-oxidase is placed in intimate contact with the electrode, the effectiveness of glucose fuel cells is increased.

“We could use this device as a continuous power source for converting chemical energy from glucose in the body to electrical energy,” said Seung Woo Lee, an assistant professor in Georgia Tech’s Woodruff School of Mechanical Engineering. “The layer-by-layer deposition technique precisely controls deposition of both the gold nanoparticle and enzyme, dramatically increasing the power density of this fuel cell.”

More, according to Georgia Tech:

Fabrication of the electrodes begins with porous cotton fiber composed of multiple hydrophilic microfibrils – cellulose fibers containing hydroxyl groups. Gold nanoparticles about eight nanometers in diameter are then assembled onto the fibers using organic linker materials.

To create the anode for oxidizing the glucose, the researchers apply glucose oxidase enzyme in layers alternating with an amine-functionalized small molecule known as TREN. The cathode, where the oxygen reduction reaction takes place, used the gold-covered electrodes, which have electrocatalytic capabilities.

“We precisely control the loading of the enzyme,” Lee said. “We produce a very thin layer so that the charge transport between the conductive substrate and the enzyme is improved. We have made a very close connection between the materials so the transport of electrons is easier.”

Study in Nature Communications: High-power hybrid biofuel cells using layer-by-layer assembled glucose oxidase-coated metallic cotton fibers…

Via: Georgia Institute of Technology…

Infrared spectroscopy is commonly used for testing the strength of various materials, to study archaeological finds, and in forensics. It’s a bit of a niche in medicine, partially due to the fact that the visible spectrum is itself so useful and equipment relying on it cheap to acquire. Researchers at the Agency for Science, Technology and Research (A*STAR) in Singapore have now developed an infrared sensing technique that relies on cheap visible spectrum detectors to do the job.

The researchers figured out how to split a laser beam into two lower energy, and therefore longer wavelength, beams. One beam is used for reference, while the other can interact with what it’s sensing and then merge back with the reference beam. The interaction between two beams as they come together can be detected using a visible light detector. “It’s a very simple setup, uses simple components, and is very compact, and we’ve hit a resolution comparable with conventional infrared systems,” said Leonid Krivitsky, one of the leads on the research.

Here’s some more details on the actual setup that was used, according to A*STAR:

The team fed laser light into a lithium niobate crystal that split some of the laser photons into two quantum-linked photons of lower energies, one in the infrared, and one in the visible parts of the spectrum, through a nonlinear process known as parametric down-conversion.

In a setup similar to a Michelson interferometer, the three beams were separated and were sent to mirrors that reflected them back into the crystal.

When the original laser beam re-entered the crystal, it created a new pair of down-converted beams that interfered with the light created in the first pass.

It was this interference that the team exploited: a sample placed in the infrared beam affected the interference between first-pass and second-pass beams, which could be detected in both the infrared and visible beams, because they are quantum linked.

Related papers: Measurement of infrared optical constants with visible photons…; Tunable optical coherence tomography in the infrared range using visible photons…

Via: A*STAR…

As of last week, all three parts of this year’s Future Health Index (FHI) by Philips are now available. Started two years ago, the FHI has previously measured perceptions of how healthcare is experienced from the points of view of both patients and providers in different countries (2016) and compared these perceptions to the reality of health systems in those countries (2017). This year, the FHI is focused on where healthcare systems around the world are in their progress towards value-based care. In doing so, the FHI is building on the growing consensus that value-based care is necessary to address the rising prevalence of chronic diseases and high costs of care. Broken up into three parts, another first this year, the report analyzes 16 health systems in developed and developing markets, representing approximately 50% of the global population.

In Part 1, the FHI articulates the Value Measure which incorporates data from across 45 metrics including both third party data and survey data. Some insights from the report include evidence that the US performs well in data collection compared to other countries, but struggles from the lack of a universal health record. Satisfaction with the healthcare system is also significantly lower in the US from the perspectives of both healthcare professionals and the general population. This lack of satisfaction pairs with a lack of trust, with 62% of healthcare professionals and 40% of the general population indicating a lack of trust in the US healthcare system.

Part 2 of the FHI report identifies five recommendations to drive better collection, analysis, and use of healthcare data for the purpose of achieving value-based care. These five recommendations are:

1. Getting regulation right
2. Modernizing education
3. Ending top-down implementation
4. Proving and explaining value
5. Harmonizing data standards

Lastly, Part 3 of the FHI emphasizes the importance of telehealth and identifies four areas where telehealth is realizing early success: radiology, pathology, intensive care, and general practice. Additionally, the report provides four recommendations for driving additional telehealth adoption and delivery of value-based care models. These four recommendations are:

1. Building the financial case for telehealth implementation
2. Ensuring telehealth implementations go beyond the technical
3. Developing a common language
4. Basing telehealth on recognition of differences

As can be seen from both lists of recommendations, two common themes in Philips’ FHI report include standardization, as well as a holistic understanding of the stakeholders involved in creating solutions and working on implementation to ensure buy in, usage, and the highest likelihood of success. Regarding the overlap between the telehealth focus of this year’s FHI report and ongoing efforts at Philips, Vitor Rocha, CEO of Philips North America commented, “At Philips we are working on telehealth and artificial intelligence solutions that can help break down the barriers between hospital and home, giving patients an alternative way to connect with healthcare professionals, both improving access to care and their satisfaction. With value-based care, we can put the emphasis back on the patient, not profits and create the kind of solutions that improve diagnostic confidence and patient outcomes, while at the same time reducing costs. Only then can we engender trust in the U.S. healthcare system and bridge the gap between healthcare professionals and the general population.”

Link: Philips Future Health Index…

Bionic Vision Technologies, a firm based in Australia, has announced that its bionic eye system has been used to restore a “sense of sight” to four completely blind people suffering from retinitis pigmentosa. The findings from the study, which was performed at Royal Victorian Eye and Ear Hospital in Melbourne, were presented at the Royal Australian and New Zealand College of Ophthalmologists Scientific meeting.

Unlike previous studies of the technology that were limited to in-lab use, the four patients were able to use the system in their everyday environments.

Each had an implant placed on the scalp with an electrode stretching to the area behind the retina. A camera within a pair of glasses feeds signals to the implant, that in turns stimulates the remaining cells to produce what looks like light to the patient. The resolution isn’t great, if you’re comparing it to healthy vision, but it’s enough for the people in the study to now begin learning how to use the technology for their benefit during everyday tasks.

“Each of the patients has returned home after surgery and are working with the clinical and research team to learn to use the device and incorporate it into their everyday lives,” in a statement said Assoc Prof Penny Allen, of the Centre for Eye Research Australia and head of the Vitreoretinal Unit at The Royal Victorian Eye and Ear Hospital. “We believe the Australian bionic eye being tested has advantages over international competitors, including a superior surgical approach, stability of the device and unique vision processing software that aims to improve the patient’s experience.

Flashbacks: Bionic Vision Australia’s Bionic Eye Gives New Sight to People Blinded by Retinitis Pigmentosa…; First Successfull Implantation of Bionic Eye…; New Prototype of Australian Bionic Eye Announced…

Link: Bionic Vision Technologies homepage…

Via: Bionic Vision Technologies

E-Motion Medical, an Israeli company, won the European CE Mark for its E-Motion System that stimulates the esophageal peristalsis in order restore failing motor activities of the digestive system.

Patients suffering from acute gastrointestinal dysmotility (GID), which includes many, if not most, of the critically ill, require a great deal of care and multifaceted treatment. Complications are common, so novel treatment options that work well would be welcome by clinicians in the ICU and other wards.

The E-Motion System sends patterns of electrical current through a feeding tube that has electrodes on its surface. As food is delivered to the patient, stimulation can be applied to help activate the motor function of the esophagus, and hopefully the rest of the GI tract.

Over 230 people have been treated with the new system as part four of clinical trials in Europe in Canada. Safety and efficacy was demonstrated in the form of increased gastric emptying, reflux and aspiration, as well as well as how fast patients recovered for discharge from ICU. Additionally, the in-hospital staff reported a reduced workload, an important aspect that not only improves costs but allows clinicians to spend more time on other important tasks.

Here’a promo video introducing the E-Motion System and the accompanying E-Motion Tube:

Link: E-Motion Medical homepage…

Via: E-Motion…

Backpack Health, a health-tech company based in Boston, has partnered with two organizations specializing in rare diseases, Care Beyond Diagnosis and FYMCA Medical, to bring their mobile and cloud-based health management application to patients with rare diseases living in low-income countries.

Rare diseases can be significantly challenging for affected patients, with mountains of paperwork required to keep track of a condition and explain it to non-specialist medical staff, who may lack adequate knowledge and awareness of a specific malady.

These difficulties are compounded in a low-income environment, which may lack even basic medical care facilities and staffed by people who are inexperienced with rare diseases. Backpack Health offers a health management app within which patients with chronic and rare diseases can record their symptoms, store their medical history, track their progress, and share their data with family and medical staff.

This helps to cut through the paperwork that often accompanies a complex medical condition and makes it easier to explain a condition to new medical staff in the case of moving to a new city or country. The app aims to be user friendly, provide patient empowerment, and also provides de-identified data for research projects.

It also allows patients to more easily share their symptoms with medical specialists, or even educate non-specialist medical staff about a rare disease, which could be very useful in remote, low-income settings.

See a video about the system below:

Medgadget asked Jim Cavan, CEO and President of Backpack Health, some questions about the system and the new partnership.

Conn Hastings, Medgadget: How did you become interested in developing a health management system?

Jim Cavan, Backpack Health: Healthcare’s landscape has always been a challenge that excites me. The emotional reward that I receive from helping to mend the healthcare system is something that I love. My entire career has been in healthcare. Beginning at a young age, my love stemmed from volunteering with my town’s emergency response team. I worked my way through college and graduate school as a paramedic, continued on to consult for pharmaceutical companies and eventually ran a variety of research enterprises. At the same time, as I was advancing in my career in healthcare, my family was touched by a rare disease. This led me to see the healthcare system through a new, personal set of eyes that revealed complexity and challenges that I hadn’t seen before. I began to start putting the pieces together.

Medgadget: What are the challenges that patients with rare diseases face?

Jim Cavan: The obvious challenges of rare diseases patients are the symptoms of their disease. However, the challenges don’t end with a patient’s symptoms; they extend to managing their own health, affecting not just them but their caregivers as well. Many of the problems associated with medical centers and doctors are the issue of getting information. How does a caregiver, often a parent, get their child’s medical records? How does a parent share these records with different specialists, teachers, babysitters and coaches? How does a parent make this information useable and accessible both for themselves and for other caregivers? The system of binders filled to capacity with files does not work. In crisis, binders are difficult to navigate and are cumbersome. Flash drives are disorganized, but, even worse, what hospital allows you to put a flash drive into their network? And what happens when visiting a foreign country and files need to be translated?

These options are not viable when dealing with complex and rare diseases. This is where Backpack Health comes in– a patient empowerment tool that helps people with chronic, serious and rare health concerns, and their caregivers, better manage and access personal health information, care and communication.

Medgadget: Why has this new partnership focused on low-income areas? What additional challenges does such an environment pose for people with rare diseases?

Jim Cavan:  Low-income areas are faced with the issue of lack of accessibility to healthcare. Low literacy, poor nutrition and social justice issues further highlight the need for access to care. When it comes to low-income environments, patients with rare diseases suffer the most. It is important for those living with complex conditions to be their own health historians, but it is even more critical for rare disease patients to do so in these areas. Empowerment comes from access to their health information and connecting with rare disease communities and resources globally.

Medgadget: Please tell us about this new partnership, and your partner organizations.

Jim Cavan: Backpack Health is committed to helping both the general rare disease community as well as disease-specific communities. Our partner organizations are our family. Together, we work to bring patients the ability to store all health information and history as well as support medical research.

Specifically, our critical partnership with Care Beyond Diagnosis (CBD) allows patients in low-income and developing countries to have the ability to transform patients into educators of local non-expert health providers. This is especially important in developing countries where health providers may never have seen a patient with a specific rare disease.

CBD’s partner, FYMCA Medical Ltd., will work with Backpack Health to develop tools and assessments to further measure rare disease symptoms. This critical health data can assist with drug development and disease management.

Medgadget: So, how does the Backpack Health app work? How will it aid patients with rare diseases in low-resource settings?

Jim Cavan: Backpack Health’s mobile app is a cloud based, multi-lingual tool that allows patients and their families to control their health journeys. The app, available for Android, IOS and offline, stores medical information, providing one centralized platform for patients to share, track and manage their health information. With their health information at their fingertips, patients are empowered to properly advocate for their own health. The app also connects users to disease-specific communities and resources and helps them easily contribute to critical medical research, with their permission, by sharing their information.

While there is a lack of accessibility to healthcare in low-income countries, smartphone accessibility is on the rise, helping to bridge the gap. With Backpack Health’s mobile app, these patients are placed at the center of their own care, allowing them to share their own management plan and educate non-expert health providers on their rare disease.

Medgadget: Is the system already available to patients in low-resource areas?

Jim Cavan: Backpack Health’s mobile app is ready to go! The app is already being used in over 70 countries. With appropriate affiliations in place, like our partnership with CBD, we have the ability to empower even more patients, putting them in control of their own health while facilitating their contribution to medical research. We are in a very exciting phase as we continue to expand our reach and impact.

Link: Backpack Health…