The Future of Medicine: Improved Malaria Vaccine

flu_vaccineOf the many advances made by medical science in the past century, vaccinations are arguably the greatest. With the ability to inoculate people against infection, diseases like yellow fever, measles, rubella, mumps, typhoid, tetanus, polio, tuberculosis, and even the common flu have become controllable – if not eliminated. Nevertheless, medical researchers agree that there are still some things that can be improved upon when it comes to vaccinations.

Beyond the controversies surrounding a supposed link between vaccinations and autism, there is the simple fact that the current method of inoculating people is rather invasive. Basically, it requires people to sit through the rather uncomfortable process of being stuck with a needle, oftentimes in an uncomfortable place (like the shoulder). Luckily, many researchers are working on a way to immunize people using gentler methods.

malaria_vaccineAt the University College Cork in Ireland, for example, scientists have just finished pre-clinical testing on an experimental malaria vaccine that is delivered through the skin. To deliver the vaccine into the body, the researchers used a skin patch with arrays of tiny silicon microneedles that painlessly create temporary pores. These pores provide an entry point for the vaccine to flow into the skin, as the patch dissolves and releases the drug.

To make the vaccine, the team used a live adenovirus similar to the virus that causes the common cold, but which they engineered to be safer and produce the same protein as the parasite that causes malaria. Adenoviruses are one of the most powerful vaccine platforms scientists have tested, and the one they used produced strong immunity responses to the malaria antigen with lower doses of the vaccine.

TB_microneedlesThe research showed that the administration of the vaccine with the microneedle patch solves a shortcoming related to this type of vaccine, which is inducing immunity to the viral vector – that is, to the vaccine itself. By overcoming this obstacle, the logistics and costs of vaccination could be simpler and cheaper as it would not require boosters to be made with different strains. Besides, with no needles or pain involved, there’s bigger potential to reach more people requiring inoculation.

This is similar to the array used by researchers at King’s College in London, who are also developing a patch for possible HIV vaccine delivery. Researchers at University of Washington used a similar method last year to deliver the tuberculosis vaccine. The method is an improvement on this type of vaccine delivery since it is painless and non-invasive. It’s use is also being researched in relation to other infections, including Ebola and HIV.

The details of the research appeared in the journal Nature. Lead researcher, Dr. Anne Moore, is set to negotiate with Silicon Valley investors and technology companies to commercialize the vaccine.

Sources: gizmag.com, (2), ucc.ie, nature.com

The Future of Medicine: New Blood-Monitoring Devices

medtechNon-invasive medicine is currently one of the fastest growing industries in the world. Thanks to ongoing developments in the fields of nanofabrication, wireless communications, embedded electronics and microsensors, new means are being created all the time that can monitor our health that are both painless and hassle-free.

Consider diabetes, an epidemic that currently affects 8% of the population in the US and is growing worldwide. In October of 2013, some 347 million cases were identified by the World Health Organization, which also claims that diabetes will become the 7th leading cause of death by 2030. To make matters worse, the conditions requires constant blood-monitoring, which is difficult in developing nations and a pain where the means exist.

google_lensesHence why medical researchers and companies are looking to create simpler, non-invasive means. Google is one such company, which back in January announced that they are working on a “smart” contact lens that can measure the amount of glucose in tears. By merging a mini glucose sensor and a small wireless chip into a set of regular soft contact lenses, they are looking to take all the pin-pricks out of blood monitoring.

In a recent post on Google’s official blog, project collaborators Brian Otis and Babak Parviz described the technology:

We’re testing prototypes that can generate a reading once per second. We’re also investigating the potential for this to serve as an early warning for the wearer, so we’re exploring integrating tiny LED lights that could light up to indicate that glucose levels have crossed above or below certain thresholds.

And Google is hardly alone in this respect. Due to growing concern and the advancements being made, others are also looking at alternatives to the finger prick, including glucose measures from breath and saliva. A company called Freedom Meditech, for example, is working on a small device  that can measure glucose levels with an eye scan.

I_Sugar_X_prototype1Their invention is known as the I-SugarX, a handheld device that scans the aqueous humor of eye, yielded accurate results in clinical studies in less than four minutes. John F. Burd, Ph.D., Chief Science Officer of Freedom Meditech, described the process and its benefits in the following way:

The eye can be thought of as an optical window into to body for the painless measurement of glucose in the ocular fluid as opposed to the blood, and is well suited for our proprietary optical polarimetric based measurements. Based on the results of this, and other studies, we plan to begin human clinical studies as we continue our product development.

Between these and other developments, a major trend towards “smart monitoring” is developing and likely to make life easier and cut down on the associated costs of medicine. A smart contact lens or saliva monitor would make it significantly easier to watch out for uncontrolled blood sugar levels, which ultimately lead to serious health complications.

I_Sugar_X_prototype2But of course, new techniques for blood-monitoring goes far beyond addressing chronic conditions like diabetes. Diagnosing and controlling the spread of debilitating, potentially fatal diseases is another major area of focus. Much like diabetes, doing regular bloodwork can be a bit difficult, especially when working in developing areas of the world where proper facilities can be hard to find.

But thanks to researchers at Rice University in Houston, Texas, a new test that requires no blood draws is in the works. Relying on laser pulse technology to create a vapor nanobubble in a malaria-infected cell, this test is able to quickly and non-invasively diagnose the disease. While it does not bring medical science closer to curing this increasingly drug-resistant disease, it could dramatically improve early diagnosis and outcomes.

malaria-blood-free-detectorThe scanner was invented by Dmitro Lapotko, a physicist, astronomer, biochemist, and cellular biologist who studied laser weapons in Belarus before moving to Houston. Here, he and his colleagues began work on a device that used the same kind of laser and acoustic sensing technology employed on sub-hunting destroyers, only on a far smaller scale and for medical purposes.

Dubbed “vapor nanobubble technology,” the device combines a laser scanner and a fiber-optic probe that detect malaria by heating up hemozoin – the iron crystal byproduct of hemoglobin that is found in malaria cells, but not normal blood cells. Because the hemozoin crystals absorb the energy from the laser pulse, they heat up enough to create transient vapor nanobubbles that pop.

malariaThis, in turn, produces a ten-millionth-of-a-second acoustic signature that is then picked up by the device’s fiber-optic acoustic sensor and indicates the presence of the malaria parasite in the blood cells scanned. And because the vapor bubbles are only generated by hemozoin, which is only present in infected cells, the approach is virtually fool-proof.

In an recent issue of Proceedings of the National Academy of Sciences, Lapotko and his research team claimed that the device detected malaria in a preclinical trial on mice where only one red blood cell in a million was infected with zero false positives. In a related school news release, the study’s co-author David Sullivan – a malaria clinician a Johns Hopkins University – had this to say about the new method:

The vapor nanobubble technology for malaria detection is distinct from all previous diagnostic approaches. The vapor nanobubble transdermal detection method adds a new dimension to malaria diagnostics, and it has the potential to support rapid, high-throughput and highly sensitive diagnosis and screening by nonmedical personnel under field conditions.

At present, malaria is one of the world’s deadliest diseases, infecting hundreds of millions of people a year and claiming the lives of more than 600,000. To make matters worse, most the victims are children. All of this combines to make malaria one of the most devastating illness effecting the developing world, comparable only to HIV/AIDS.

malaria_worldwideBy ensuring that blood tests that could detect the virus, and require nothing more than a mobile device that could make the determination quickly, and need only a portable car battery to power it, medical services could penetrate the once-thought impenetrable barriers imposed by geography and development. And this in turn would be a major step towards bringing some of the world’s most infectious diseases to heel.

Ultimately, the aim of non-invasive technology is to remove the testing and diagnostic procedures from the laboratory and make them portable, cheaper, and more user-friendly. In so doing, they also ensure that early detection, which is often the difference between life and death, is far easier to achieve. It also helps to narrow the gap between access between rich people and poor, not to mention developing and developing nations.

Sources: fastcoexist.com, news.cnet.com, businesswire.com, googleblogspot.ca, who.int