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Our tech scouts are tracking the new technologies and innovations that are most responsible for driving precision medicine forward. Three of the most promising are 3D printing, genome editing, and wearable physiological monitoring devices.

3D printing is an emerging technology that allows 3D objects to be 鈥減rinted鈥� layer by layer using specialized hardware and computer-aided design software. Various 3D printing technologies鈥攊ncluding ink-jet printing, binder vetting, and stereolithography鈥攃an of pharmaceutical dosage forms. Recently, 3D printing has been used to initiate groundbreaking brain tumor cell research that aims to develop treatments that are .

The Food and Drug Administration鈥檚 (FDA) Center for Devices and Radiological Health, which regulates medical devices, has cleared , including hearing aids, dental crowns, bone plates, skull plates, spinal cages, facial implants, surgical instruments, and Invisalign braces.

Genome editing is a type of gene therapy that directly modifies pieces of cellular DNA to restore cell function and treat or prevent disease. The FDA has聽, including , which treats an inherited form of vision loss that can result in blindness. Gene editing could potentially treat a , including blood disorders, cancer, bacterial infections, metabolic conditions, and other genetic disorders.

One developing therapy involves the genetic engineering of pig organs to be transplanted into humans. Although this treatment is not yet approved for regular clinical use, genetically engineered pig kidneys into a brain-dead patient, and a pig heart has been . The recipient of the heart died 2 months later, but work in this area could one day lead to the elimination of the organ shortage crisis.

Another recently developed approach to cancer treatment patients' immune cells from close to 2 weeks to only 24 hours. This cell manufacturing process for chimeric antigen receptor T-cell (CAR-T) therapy highlights precision medicine鈥檚 potential to make gene therapy available to more patients by reducing its costs in terms of time, materials, and labor.

Physiological monitoring devices that measure and capture information such as temperature, activity, heart rate, heart rate variability (HRV), respiration, and sleep quality can empower precision medicine practitioners by providing detailed, real-time insights into the health statuses of individual patients. Wearable monitoring devices that are available to the general public include , , , , and the . The FDA has also a variety of more specialized patient monitoring devices for .

The COVID-19 pandemic accelerated the real-time physiological monitoring devices. Use cases that ramped up during the pandemic include monitoring patients at home and dealing with increased demand through better prioritizing treatment to patient risk and need. The pandemic also spurred research and development focused on using physiological monitoring devices for early infection detection within essential workforces, such as s. Continued advancement of real-time physiological monitoring鈥攊ncluding organizing and integrating the incoming data into repositories and IT systems鈥攚ill make care more convenient, scalable, preventative, and precise.

Most medical providers now recognize that precision medicine solutions are poised to become聽. Precision medicine is already improving care by empowering a transition from a one-size-fits-all mindset to a far more individually tailored approach to disease prevention and treatment. Remaining knowledgeable of emerging technologies through well-informed technology scouting efforts will help actualize precision medicine鈥檚 full potential to benefit health and improve patient outcomes.