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1. A Tunable Soft Silicone Bioadhesive for Secure Anchoring of Diverse Medical Devices to Wet Biological Tissue

   https://doi.org/10.1002/adma.202307288  

   Singh, Manisha; Teodorescu, Debbie_L; Rowlett, Meagan; Wang, Sophie_X; Balcells, Mercedes; Park, Clara; Bernardo, Bruno; McGarel, Sian; Reeves, Charlotte; Mehra, Mandeep_R; et al (December 2023, Advanced Materials)

   Abstract Silicone is utilized widely in medical devices for its compatibility with tissues and bodily fluids, making it a versatile material for implants and wearables. To effectively bond silicone devices to biological tissues, a reliable adhesive is required to create a long‐lasting interface. BioAdheSil, a silicone‐based bioadhesive designed to provide robust adhesion on both sides of the interface is introduced here, facilitating bonding between dissimilar substrates, namely silicone devices and tissues. The adhesive's design focuses on two key aspects: wet tissue adhesion capability and tissue‐infiltration‐based long‐term integration. BioAdheSil is formulated by mixing soft silicone oligomers with siloxane coupling agents and absorbents for bonding the hydrophobic silicone device to hydrophilic tissues. Incorporation of biodegradable absorbents eliminates surface water and controls porosity, while silane crosslinkers provide interfacial strength. Over time, BioAdheSil transitions from nonpermeable to permeable through enzyme degradation, creating a porous structure that facilitates cell migration and tissue integration, potentially enabling long‐lasting adhesion. Experimental results demonstrate that BioAdheSil outperforms commercial adhesives and elicits no adverse response in rats. BioAdheSil offers practical utility for adhering silicone devices to wet tissues, including long‐term implants and transcutaneous devices. Here, its functionality is demonstrated through applications such as tracheal stents and left ventricular assist device lines. 

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2. Advances in Artificial Intelligence-Based Medical Devices for Healthcare Applications

   https://doi.org/10.1007/s44174-025-00379-1  

   Tettey-Engmann, Felix; Parupelli, Santosh_Kumar; Bauer, Steven_R; Bhattarai, Narayan; Desai, Salil (May 2025, Biomedical Materials & Devices)

   Abstract Medical devices play a crucial role in modern healthcare, providing innovative solutions for diagnosing, preventing, monitoring, and treating ailments. Artificial Intelligence is transforming the field of medical devices, offering unprecedented opportunities through diagnostic accuracy, personalized treatment plans, and enhancing patient outcomes. This review outlines the applications of artificial intelligence-based medical devices in healthcare specialties, especially in dentistry, medical imaging, ophthalmology, mental health, autism spectrum disorder diagnosis, oncology, and general medicine. Specifically, the review highlights advancements such as improved diagnostic accuracy, tailored treatment planning, and enhanced clinical outcomes in the above-mentioned applications. Regulatory approval remains a key issue, where medical devices must be approved or cleared by the United States Food and Drug Administration to establish their safety and efficacy. The regulatory guidance pathway for artificial intelligence-based medical devices is presented and moreover the critical technical, ethical, and implementation challenges that must be addressed for large-scale adoption are discussed. The review concludes that the intersection of artificial intelligence with the medical device domain and internet-enabled or enhanced technology, such as biotechnology, nanotechnology, and personalized therapeutics, enables an enormous opportunity to accelerate customized and patient-centered care. By evaluating these advancements and challenges, the study aims to present insights into the future trajectory of smart medical technologies and their role in advancing personalized, patient-centered care. 

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3. Tissue Forge: Interactive biological and biophysics simulation environment

   https://doi.org/10.1371/journal.pcbi.1010768  

   Sego, T. J.; Sluka, James P.; Sauro, Herbert M.; Glazier, James A. (October 2023, PLOS Computational Biology)

   Kemp, Melissa L. (Ed.)

   Tissue Forge is an open-source interactive environment for particle-based physics, chemistry and biology modeling and simulation. Tissue Forge allows users to create, simulate and explore models and virtual experiments based on soft condensed matter physics at multiple scales, from the molecular to the multicellular, using a simple, consistent interface. While Tissue Forge is designed to simplify solving problems in complex subcellular, cellular and tissue biophysics, it supports applications ranging from classic molecular dynamics to agent-based multicellular systems with dynamic populations. Tissue Forge users can build and interact with models and simulations in real-time and change simulation details during execution, or execute simulations off-screen and/or remotely in high-performance computing environments. Tissue Forge provides a growing library of built-in model components along with support for user-specified models during the development and application of custom, agent-based models. Tissue Forge includes an extensive Python API for model and simulation specification via Python scripts, an IPython console and a Jupyter Notebook, as well as C and C++ APIs for integrated applications with other software tools. Tissue Forge supports installations on 64-bit Windows, Linux and MacOS systems and is available for local installation via conda. 

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4. Biocompatible and Nanoenabled Technologies for Biological Modulation

   https://doi.org/10.1002/admt.202100216  

   Ostroff, Eleanor; Parekh, Kavita; Prominski, Aleksander; Tian, Bozhi (June 2021, Advanced Materials Technologies)

   Abstract Biocompatible and nanoscale devices for biological modulation of cells and tissues possess the potential for tremendous impact on medical and industrial technologies. Typical medical devices and therapies tend to be macroscale, comprised of nonbiocompatible materials, and broadly targeted, resulting in imprecise treatments and adverse effects such as chronic immune response and tissue damage. The development of nanoenabled and biocompatible technologies—ranging from biodegradable nanoparticles for localized drug delivery to transient electronic devices for stimulation therapy to engineered biofilms with applications to nanomedicine—will continue to enable the advent of personalized medicine and precision therapies. In this review, recent research into this frontier is reviewed, first analyzing the synthesis of nanoenabled and biocompatible technologies and then presenting significant considerations regarding the development of such materials. Lastly, the latest advancements in biocompatible, nanoenabled devices are examined, followed by a discussion of the direction of future research in the field. 

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5. Pathway of transient electronics towards connected biomedical applications

   https://doi.org/10.1039/d2nr06068j  

   Dutta, Ankan; Cheng, Huanyu (March 2023, Nanoscale)

   Transient electronic devices have shown promising applications in hardware security and medical implants with diagnosing therapeutics capabilities since their inception. Control of the device transience allows the device to “dissolve at will” after its functional operation, leading to the development of on-demand transient electronics. This review discusses the recent developments and advantages of triggering strategies ( e.g. , electrical, thermal, ultrasound, and optical) for controlling the degradation of on-demand transient electronics. We also summarize bioresorbable sensors for medical diagnoses, including representative applications in electrophysiology and neurochemical sensing. Along with the profound advancements in medical diagnosis, the commencement of therapeutic systems such as electrical stimulation and drug delivery for the biomedical or medical implant community has also been discussed. However, implementing a transient electronic system in real healthcare infrastructure is still in its infancy. Many critical challenges still need to be addressed, including strategies to decouple multimodal sensing signals, dissolution selectivity in the presence of multiple stimuli, and a complete sensing–stimulation closed-loop system. Therefore, the review discusses future opportunities in transient decoupling sensors and robust transient devices, which are selective to a particular stimulus and act as hardware-based passwords. Recent advancements in closed-loop controller-enabled electronics have also been analyzed for future opportunities of using data-driven artificial intelligence-powered controllers in fully closed-loop transient systems. 

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