Human life is a one big attempt at solving variety of problems. You see, even though we might differ in what purpose we end up finding for ourselves, we are, more or less, always working towards creating some sort of solution within a given context. Now, if we put it like that, such a dynamic does sound overwhelming, but it’s also hugely essential for our lifelong pursuit to achieve growth. In fact, by looking back at the history, we can observe how the humans’ solution-oriented tendency has actually worked tirelessly to deliver some concrete benefits. Now, these benefits, in turn, have touched upon many different areas across our life. However, the only by-product to interact with nearly all of them was technology. Technology’s ability to function under outright dissimilar environments helped us big time around making a rather collective push for something better, and in hindsight, it will be safe to claim that we got there without too much of a struggle. While each area played a pivotal role in making the transition happen, how things panned out on the medical front has to be considered as one majorly influential factor. Using technology’s generational capabilities, the medical sector was able to reinvent an undesirable image that was in place for years by then, thus kickstarting a revolution. After scaling up beyond every known boundary, the industry is now putting-together a bid for an even more advanced future, and this intention seems quite evident in a recent development.
The researching team at University of California has successfully developed a pop up sensor, which is essentially designed for gauging electronic signals circulating inside cardiac cells. Made up from tiny spike-like protrusions, the device is well-equipped to penetrate cell membranes without causing any damage, thus allowing medical professionals to gain insights about cardiac diseases like myocardial infarction and arrhythmias. A step of the said scale is realized through tiny field effect transistors. These transistors are coated with a phospholipid layer that protects the procedure from a potential foreign body response, something we have noticed to negatively impact electrical signals’ measurement over the long-term. According to certain reports, the device not only brings insights regarding signal activity within a particular cell, but it can also track the ones travelling from cell to cell.
Assuming we get a desired result out of this new device, the world can expect a significantly altered landscape for cardiac health. Furthermore, there is a very good chance that we might also be able to use it for conducting meaningful studies on the neurological discipline.
