Penn State researchers highlight the potential for microrobots in diagnosing and treating infectious diseases.
A microscope catching blood cells – artistic interpretation.
Biofilms—structured communities of microorganisms that create a protective matrix shielding them from external threats, including antibiotics—are responsible for about 80% of human infections and present a significant challenge in medical treatments, often resisting conventional methods.
In a Q&A with Penn Today, Hyun (Michel) Koo of the School of Dental Medicine and Edward Steager of the School of Engineering and Applied Science at Penn discuss an innovative approach they’ve partnered on: the use of small-scale robotics, microrobots, to offer a promising solution to tackle these persistent infections, bringing new capabilities and precision to the field of biomedical engineering.
What is the motivation behind opting for tiny robots to tackle infections?
Koo: Treating biofilms is a broad yet unresolved biomedical problem, and conversely, the strategies for tackling biofilms are limited for a number of reasons. For instance, biofilms typically occur on surfaces that can be tricky to reach, like between the teeth in the oral cavity, the respiratory tract, or even within catheters and implants, so treatments for these are usually restricted to antibiotics (or antimicrobials) and other physical methods reliant on mechanical disruption. However, this touches on the problem of antimicrobial resistance: targeting specific microorganisms present in these structures is difficult, so antibiotics often fail to reach and penetrate the biofilm’s protective layers, leading to persistent infections and increased risk of antibiotic resistance.
We needed a way to circumvent these constraints, so Ed and I teamed up in 2017 to develop new, more precise and effective approaches that leverage the engineers’ ability to generate solutions that we, the clinicians and life science researchers, identify.
Steager: Small scale robots present a way to treat, disrupt and remove biofilms by directly targeting the sites of infection, and they also offer new means of retrieving microbial samples and subsequently diagnosing other conditions. The integration of microrobotics into healthcare signifies a paradigm shift in how we approach medical treatments, promising more efficient and less invasive options. We’re happy to see that this trend has gained momentum in the last five years since our first publication, driven by technological advancements and interdisciplinary collaborations like ours.
How are the microrobots powered and controlled?
Steager: We typically categorize these robots into two main types: intrinsically powered and extrinsically powered. The former derive energy from their immediate environment; this can include chemical energy, biological processes, or ambient energy sources, and even from tiny internal engineered power sources. They offer greater autonomy and can operate in various environments, but their independent movement can be challenging to control precisely.
On the other hand, we have extrinsically powered, which are controlled by external means such as magnetic fields, acoustic waves, or optical systems. This external control offers precise and directed movement, allowing for targeted delivery and operations within the body. However, they require external equipment to guide and power their movements.
How are your students reacting to opportunities in this field?
Koo: Students are showing a growing interest in microrobotics and its applications in healthcare and are eagerly suggesting new ways to innovate the field. This field offers a unique opportunity for students to be at the forefront of cutting-edge research and development. It’s a platform that encompasses everything from nanotechnology, artificial intelligence and material sciences, to actuation, energy harvesting, and microfabrication to solve a healthcare problem. Right now, we’re mostly focused on biofilm infections, but there are so many more challenges the students are excited to tackle.
What role does big data play in the future of microrobotics?
Koo: Big data and artificial intelligence are critical components in the future of microrobotics, particularly in healthcare. The vast amount of data being generated in biomedicine can be leveraged to reveal patterns and insights about human health and disease that were previously unattainable. This information is invaluable in improving the design and functionality of microrobotic systems, making them more precise, effective, and efficient. Moreover, the integration of big data with robotics opens up new possibilities for personalized medicine, where treatments can be tailored to the individual patient based on data-driven insights.
Steager: This integration signifies a pivotal shift toward the overlap of sensing in robotics and diagnostics in medicine. This intersection is critical for developing less invasive diagnostic methods and treatments, especially in hard-to-access infection sites. The conversation points towards a future where robotics not only treat but also identifies and analyzes infections, leveraging big data for more precise healthcare.
Source: University of Pennsylvania
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