Polypyrrole (PPy) is a conjugated polymer that displays particular electronic properties including conductivity. In biomedical applications, it is usually electrochemically generated with the incorporation of any anionic species including also negatively charged biological macromolecules such as proteins and polysaccharides to give composite materials. In biomedical research, it has mainly been assessed for its role as a reporting interface in biosensors. However, there is an increasing literature on the application of PPy as a potentially electrically addressable tissue/cell support substrate. Here, we review studies that have considered such PPy based conducting polymers in direct contact with biological tissues and conclude that due to its versatile functional properties, it could contribute to a new generation of biomaterials.
SummaryLow-dose exposures to common environmental chemicals that are deemed safe individually may be combining to instigate carcinogenesis, thereby contributing to the incidence of cancer. This risk may be overlooked by current regulatory practices and needs to be vigorously investigated.
This
work presents the design, fabrication, and characterization
of a robust 3D printed microfluidic analysis system that integrates
with FDA-approved clinical microdialysis probes for continuous monitoring
of human tissue metabolite levels. The microfluidic device incorporates
removable needle type integrated biosensors for glucose and lactate,
which are optimized for high tissue concentrations, housed in novel
3D printed electrode holders. A soft compressible 3D printed elastomer
at the base of the holder ensures a good seal with the microfluidic
chip. Optimization of the channel size significantly improves the
response time of the sensor. As a proof-of-concept study, our microfluidic
device was coupled to lab-built wireless potentiostats and used to
monitor real-time subcutaneous glucose and lactate levels in cyclists
undergoing a training regime.
There is a growing interest in the design and engineering of operational biofuel cells that can be implanted. This review highlights the recent progress in the electrochemistry of biofuel cell technologies, but with a particular emphasis on the medical and physiological aspects that impact the biocompatibility of biofuel cells operating inside a living body. We discuss the challenge of supplying power to implantable medical devices, with regard to the limitations of lithium battery technology and why implantable biofuel cells can be a promising alternative to provide the levels of power required for medical devices. In addition to the challenge of designing a biofuel cell that provides a stable level of sufficient power, the review highlights the biocompatibility and biofouling problems of implanting a biofuel cell that have a major impact on the availability of the substrates inside body that provide fuel for the biofuel cell. These physiological challenges and associated ethical considerations are essential to consider for biofuel cells that are designed to be implanted for long-term operation inside a living animal and eventually to human clinical applications.
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