Skip links

The Technology Trends in Life Sciences In 2022

AI has already had a significant impact on our lives, from self-driving cars to intelligent assistants. In addition, experts predict that AI will soon play an important role in healthcare.

By 2022, artificial intelligence (AI) will play a significant role in healthcare. This means doctors will diagnose diseases faster and better, patients will receive personalized treatment plans, and medical research will become more efficient. It all sounds like science fiction, but it can be true! We look at how AI improves health today and how it will change medicine by 2022.

So what does the future hold for technology? Who knows, but one thing’s for sure, something new and exciting is coming down the pipeline. This article will closely look into the significant trend in Life science and the Must-Know Statistics in life science.

Wearable Technology: Healthcare

The wearable technology market will grow exponentially with time. There is no reason why such devices in healthcare cannot follow suit. Many different wearables are available today, ranging from fitness trackers to smartwatches. In addition, these wearables can perform various functions, including tracking vital signs, monitoring sleep patterns, or even providing feedback about mental health conditions. However, as far as the healthcare industry is concerned, wearable technology is still limited to measuring parameters such as heart rate or blood pressure. Despite this, experts believe that the current limitations of wearable will soon be overcome. By 2022, wearable tech will provide support in diagnosing certain diseases through data collection. All this will happen without any surgical intervention required.

3D Printing: Medical Devices

As mentioned earlier, 3D printing technology is used in many other industries than just creating plastic products, especially manufacturing. Several companies are now using this technology to create custom implants, bones, internal organs, and limbs. But what if such technology could also be applied to healthcare? Experts say that 3D printers will produce customized parts for people requiring organ transplants in the future. Not only that, but they may also be able to print replacement limbs for amputees and even entire human bodies. Although scientists are still working hard to make this possible, they believe that it won’t be long before 3D printed prosthetics match the quality of real ones.

Nanobots: Medicine & Dentistry

Today, nanotechnology is helping us live longer due to its ability to detect diseases early and heal itself quickly. While the benefits of applying this technology to healthcare aren’t new, their application in dentistry is relatively more recent. Once the technology becomes mainstream, it is expected that dental care will improve significantly, leading to fewer cavities and tooth loss. Furthermore, nanobots can help deliver medication directly to the affected area, making them beneficial for treating specific illnesses. For example, nanoparticles can be injected into the bloodstream to reach cancer cells while avoiding healthy tissue. They can then release drugs that slow down tumor growth. By 2022, nanobots will have improved capabilities compared to what we see today.

Personalized Medicine: Treating Patients Better

We all know how important it is to treat our patients individually, considering their unique needs and situations. This approach has become much more common recently. It’s not just about taking a medical history anymore. Many doctors and hospitals collect personal information like lifestyle choices, family history, diet, etc. Physicians can customize treatments and find better patient solutions using this info. Some experts predict that by 2025, most hospitals will offer personalized medicine. It will allow physicians to identify patient groups based on their genetic makeup and prescribe accordingly. By 2027, this trend will accelerate as more individuals gain access to their genome sequences.

Bioengineered Tissues: Healing Wounds Faster

Scientists worldwide spend millions upon millions of dollars every year to figure out how living tissues work. And according to an article published in the New England Journal of Medicine, they might finally achieve the goal of bioengineering skin tissues within the next decade. Currently, researchers already know how to grow small patches of the heart muscle and blood vessels inside laboratory animals or use 3D printing techniques to generate simple structures such as cartilage and bone. However, these technologies cannot yet reproduce complex natural systems. Moreover, even when they eventually learn to do so, there will still be a lot of challenges associated with large-scale production — like keeping the engineered tissues alive and functional for years.

Drug Delivery Devices: Targeted Drugs at Lower Doses

Chronic conditions like diabetes and arthritis increase drastically as the population ages. As a result, pharmaceutical companies need effective delivery methods to treat those diseases. At present, most medicines prescribed to older adults require high doses of drugs because science does not understand how to provide remedies efficiently. However, innovative research being conducted by scientists at UCLA may change that. Researchers are developing intelligent drug delivery devices that allow people to receive lower doses more frequently than current therapies. So far, these devices have been tested successfully in mice and rats, though the transition to humans remains uncertain.

Bioprinting: Printing Organs (Or parts of them)

Remember when we mentioned earlier printing organs? Well, organ printing promises to overcome the limitations of current organ transplantation practices. Because bioprinters can print three-dimensional objects, they also hold great promise for regenerating tissue within the body. While many view this as a futuristic practice, proponents note that 3D printers demonstrate the ability to manufacture biological materials perfectly competently today. However, the machines have mostly printed 2D shapes like sheets of paper and flat panels, limiting their true potential. But advancements in 3D printing are expected to drive its development and help it gain widespread adoption in the medical field.

Robotic Surgery: New Procedures

Thanks to robots, some surgeries are now considered too dangerous for surgeons can be performed precisely and safely. Robots are beneficial for procedures that require extensive training in human hands. For example, robotic surgery is already being utilized by urologists, orthopedic surgeons, and even neurosurgeons. Recently, robots were used to perform a first-ever total wrist replacement. Since robots can sense forces and movements along multiple axes, they can operate with greater precision and agility than their fleshy counterparts. With further improvements in artificial intelligence, expect to see more advanced robots in the operating room soon.

Gene Therapy: Treating Disease

If you’ve seen movies like I, Robot, or Terminator, you will probably know what is involved in gene therapy. This type of treatment consists of introducing healthy copies of genes into cells to resist disease better. It is often treated as a form of medicine and can cure genetic disorders like hemophilia, sickle cell anemia, and cystic fibrosis. Although it is still early days, modern advances in science suggest that gene therapy could eventually come to treat a range of other health issues such as cancer, Alzheimer’s, and cardiovascular disease. And if the benefits of treatments outweigh any risks, who knows? Maybe one day, we will all get superpowers.

Neurotech / Brain-Computer Interface

Imagine having complete control over your computer just through brainpower. That concept seems very sci-fi, but it is becoming a reality today. Several studies show that we will connect our brains to computers using wireless neural implants and read/write data directly from individual neurons in our brains soon. Think of it as replacing the keyboard with our thoughts. Of course, it remains to be seen exactly how we will use these tools. Still, a few ideas include controlling PCs without touching them, creating safer autopilots, preventing car accidents, and fighting addictions. Whatever direction we take, we should never forget to thank Albert Einstein for discovering something we never thought possible – our brain’s direct connection to the internet.

In conclusion, the global market for the life science sector is expected to grow. The growth rate is estimated at a CAGR of 6.2% from 2018 to 2022. This report has covered the most prominent technologies likely to influence the industry and help it flourish. Some of these include AI, Biometrics, Cloud-based services, Data analytics, IoT, Robotics, 3D printing, and Virtual reality. We hope these trends will be followed closely by the research community as they try to find out which ones will work best for them.