#ImplantableDevices hashtag - Bluesky

5 days ago

🧪 Who supports patients when implantable neurotechnology is abandoned? GIVE-A-HAND.tech is building that safety net. Join our SPARC webinar in 1 week with Dr. Kevin Kilgore. Register here: sparc.science/news-a...
#Neurotechnology #ImplantableDevices

0 0 0 0

CITI Program

@citiprogram.org

1 week ago

NIH Seeks Input on Resources for Implantable Device Trials In March 2026, the NIH released two draft resources to improve the design, conduct, and communication with participants in implantable device trials.

In March 2026, the National Institutes of Health (NIH) released two draft resources to improve the design, conduct, and communication with participants in implantable device trials.
https://post.citiprogram.org/4lPLM3e
#NIH #ImplantableDevices

0 0 0 0

@yuvip.bsky.social

3 months ago

Cardiac Pacemaker Market Size, Trends & Forecast 2035 Cardiac Pacemaker industry is projected to grow from 5.027 USD Billion in 2025 to 7.982 USD Billion by 2035, With CAGR of 4.73% during 2025 - 2035

Aging population fuels the Cardiac Pacemaker Market ❤️📈 Explore growth outlook 👉 www.marketresearchfuture.com/reports/card... #Cardiology #ImplantableDevices

0 0 0 0

JMIR Publications

@jmirpub.bsky.social

7 months ago

Using Vibration for Secure Pairing With Implantable Medical Devices: Development and Usability Study Background: Implantable Medical Devices (IMDs), such as pacemakers, increasingly communicate wirelessly with external devices. To secure this wireless communication channel, a pairing process is needed to bootstrap a secret key between the devices. Previous work has proposed pairing approaches that often adopt a “seamless” design and render the pairing process imperceptible to patients. This lack of user perception can significantly compromise security and pose threats to patients. Objective: The objective of this work is to explore the use of highly perceptible vibrations for pairing with IMDs. We aim to propose a novel technique that leverages the natural randomness in human motor behavior as a shared source of entropy for pairing, potentially deployable to current IMD products. Methods: We develop a proof-of-concept to demonstrate our proposed technique. We build a wearable prototype designed for individuals to simulate being an IMD patient (we do not test on real patients to avoid potential risks), and devise signal processing algorithms that utilize accelerometer readings to facilitate secure pairing with an IMD. We thoroughly evaluate the accuracy, security, and usability of our technique in a lab study with 24 participants. Results: Our proposed pairing technique achieves high pairing accuracy, with a zero false acceptance rate (indicating low risks from adversaries) and a false rejection rate of only 0.6% (suggesting that legitimate users will likely experience very few failures). Our approach also offers robust security, which passes the National Institute of Standards and Technology statistical tests (with all p-values > 0.01). Moreover, our technique has high usability, evidenced by an average System Usability Scale questionnaire score of 73.6 (surpassing the standard benchmark of 68 for "good usability") and insights gathered from the interviews. Furthermore, the entire pairing process can be efficiently completed within five seconds. Conclusions: Vibration can be used to realize secure, usable, and deployable pairing in the context of IMDs. Our method also exhibits advantages over previous approaches, e.g., lenient requirements on the sensing capabilities of IMDs and the synchronization between the IMD and the external device.

New JMIR BioMedEng: Using Vibration for Secure Pairing With Implantable Medical Devices: Development and Usability Study #MedicalDevices #WirelessCommunication #ImplantableDevices #SecurePairing #HealthTech

0 0 0 0