We use cookies to understand how you use our site and to improve your experience. This includes personalizing content and advertising. To learn more, click here. By continuing to use our site, you accept our use of cookies. Cookie Policy.

Features Partner Sites Information LinkXpress hp
Sign In
Advertise with Us
ARAB HEALTH - INFORMA

Download Mobile App




Parasite-Inspired Medical Device Mimics Tapeworm Hooks for Soft Tissue Anchoring

By HospiMedica International staff writers
Posted on 04 Dec 2024
Print article
Image: Scanning electron micrographs of the fully assembled mechanism shown in both retracted (fully armed) and deployed configurations. The hook assembly is shown in detail as well as an accompanying optical photograph of the same model, with a finger for scale.(Photo courtesy of Maquignaz et al.)
Image: Scanning electron micrographs of the fully assembled mechanism shown in both retracted (fully armed) and deployed configurations. The hook assembly is shown in detail as well as an accompanying optical photograph of the same model, with a finger for scale.(Photo courtesy of Maquignaz et al.)

Implantable and ingestible devices offer minimally invasive approaches for drug delivery, diagnostics, and monitoring previously hard-to-detect conditions. These devices often need mechanisms to attach to tissue in order to function effectively for prolonged periods at specific locations. As a result, enhancing mechanical adhesion to particular human tissue types has become an important area of research over the last two decades, with significant implications for diagnostics, therapeutics, and surgical device design. Attachment mechanisms can help medical devices target specific regions of the gastrointestinal (GI) tract or other soft tissues for tasks such as sensing, sample collection, and drug delivery. Inspired by the attachment structures found in parasites, researchers have now developed a millimeter-scale mechanism to anchor medical devices to soft tissues.

Scientists from Harvard John A. Paulson School of Engineering and Applied Science at Harvard University (SEAS, Cambridge, MA, USA) looked to parasites for inspiration in creating methods to affix small-scale medical devices to soft tissues, such as the gastrointestinal tract, for functions like sensing, sample collection, and extended drug release. Evolution has produced a variety of biomechanical structures for tissue attachment, and the researchers chose to model their design after the curved hook arrays used by certain species of tapeworms. The device, made of stainless steel and polyimide film, features curved hooks that are automatically deployed when external force is applied to the platform.

The device, presented in a paper published in the journal PNAS Nexus, was built using laminate manufacturing techniques, where layers are bonded with adhesive. It weighs just 44 mg and measures less than 5 mm in diameter when deployed, making it small enough to be integrated into ingestible capsule robots. According to scientists, this device can be used in various medical contexts. For example, it could serve as a platform to study how different parasite attachment structures impact tissue irritation and host pathology, paving the way for the development of medical devices that minimize patient morbidities. Future research may focus on further miniaturizing the device for easier integration into surgical tools, thereby reducing tissue damage during use.

Gold Member
SARS‑CoV‑2/Flu A/Flu B/RSV Sample-To-Answer Test
SARS‑CoV‑2/Flu A/Flu B/RSV Cartridge (CE-IVD)
New
Gold Member
X-Ray QA Meter
T3 AD Pro
New
Shoulder Positioner
HE-JB2
New
Family Practice Exam Table
2100M7

Print article

Channels

Critical Care

view channel
Image: Researchers have designed a magnetoplasmonic strain sensor for wearable devices (Photo courtesy of Chemical Engineering Journal, DOI: https://doi.org/10.1016/j.cej.2024.155297)

Power-Free Color-Changing Strain Sensor Enables Applications in Health Monitoring

Wearable devices and smart sensors are revolutionizing health and activity monitoring, enabling functions like heart rate tracking and body movement detection. However, conventional tools like stethoscopes... Read more

Patient Care

view channel
Image: The portable biosensor platform uses printed electrochemical sensors for the rapid, selective detection of Staphylococcus aureus (Photo courtesy of AIMPLAS)

Portable Biosensor Platform to Reduce Hospital-Acquired Infections

Approximately 4 million patients in the European Union acquire healthcare-associated infections (HAIs) or nosocomial infections each year, with around 37,000 deaths directly resulting from these infections,... Read more

Health IT

view channel
Image: First ever institution-specific model provides significant performance advantage over current population-derived models (Photo courtesy of Mount Sinai)

Machine Learning Model Improves Mortality Risk Prediction for Cardiac Surgery Patients

Machine learning algorithms have been deployed to create predictive models in various medical fields, with some demonstrating improved outcomes compared to their standard-of-care counterparts.... Read more

Point of Care

view channel
Image: The acoustic pipette uses sound waves to test for biomarkers in blood (Photo courtesy of Patrick Campbell/CU Boulder)

Handheld, Sound-Based Diagnostic System Delivers Bedside Blood Test Results in An Hour

Patients who go to a doctor for a blood test often have to contend with a needle and syringe, followed by a long wait—sometimes hours or even days—for lab results. Scientists have been working hard to... Read more
Copyright © 2000-2024 Globetech Media. All rights reserved.