Terms of endearment: Bacteria meet graphene nanosurfaces.

Microbial multidrug resistance poses serious risks in returning the human species into the pre-antibiotic era if it remains unsolved. While conventional research approaches to combat infectious diseases have been inadequate, nanomaterials are a promising alternative for the development of sound antimicrobial countermeasures. Graphene, a two-dimensional ultra-thin nanomaterial, possesses excellent electronic and biocompatibility properties, which position it in the biotechnology forefront for diverse applications in biosensing, therapeutics, diagnostics, drug delivery and device development. Yet, several questions remain unanswered. For instance, the way these nanosurfaces interact with the microbial entities is poorly understood. The mechanistic elucidation of this interface seems critical to determine the feasibility of applications under development. Are graphene derivatives appropriate materials to design potent antimicrobial agents, vehicles or effective diagnostic microsensors? Has the partition of major microbial resistance phenotypic determinants been sufficiently investigated? Can toxicity become a limiting factor? Are we getting closer to clinical implementation? To facilitate research conducive to answer such questions, this review describes the features of the graphene-bacterial interaction. An overview on paradigms of graphene-microbial interactions is expected to shed light on the range of materials available, and identify possible applications, serving the ultimate goal to develop deeper understanding and collective conscience for the true capabilities of this nanomaterial platform.

Recording of ENGs from the nerves innervating the pancreas of a dog during the intravenous glucose tolerance test.

Electroneurograms (ENGs) from the vagus nerve (VN), the splanchnic nerve (SN) and the pancreatic nerve (PN) innervating the pancreas of a dog, were recorded with chronically implanted 33-electrode spiral cuffs (cuff) before and after the pancreas were stimulated with intravenously (i.v.) administered glucose. In the cuffs platinum electrodes were arranged in three parallel spiral groups containing 11 electrodes on the inner surface. The cuffs had an inner diameter of 2 mm and a length of 18 mm. In a two-year study, the cuffs were implanted into two Beagle dogs and were also used for pancreatic stimulation, although this is not described in this paper. In the VN, the cuff was installed on the nerve at the neck, whilst in the SN, the cuff was installed on the nerve before the celiac ganglion, and in the PN, the cuff was installed on the nerve just before it enters the pancreas. Six months after implantation, when the model of interpretation of the results was developed, three recordings of ENG in each animal were conducted. The first one was conducted in the unstimulated pancreas while the second and the third were conducted 1 and 8 min after a known amount of glucose was i.v. administered. Since the results obtained in both animals were actually quite similar, we present the results obtained in one animal. To evaluate the changes in superficial activity of the nerves, elicited by the administration of glucose, the power spectra corresponding to ENGs, recorded from the nerves before and after the administration of glucose, were integrated within the band of frequencies ranging from 1 to 5 kHz. Accordingly, the magnitude of the integrated power spectrum (MIPS), corresponding to the ENG recorded from the SN before administration of glucose, was 2.863 au. One minute after glucose was administered the value fell to 2.795 au while 8 min after the administration the value returned to 2.8 au. The MIPS corresponding to the ENG recorded from the PN before the administration of glucose was 3.236 au. One minute after the administration the value fell to 2.901 au while 8 min after the administration the value rose to 3.009 au. The MIPS, corresponding to the ENG recorded from the VN before the administration of glucose, was 3.656 au. One minute after the administration the value fell to 3.565 au. Eight minutes after the administration the value rose to 3.689 au. The results show that 1 min after glucose was administered superficial activity in all three nerves was reduced while 8 min after administration the activity in the nerves returned to the same level of activity before the glucose was administered. This information could be effectively used in a further study of pancreatic innervation and its function. Moreover, the results suggest that cuffs could also be useful in recording the ENGs from other nerves of the autonomic nervous system that innervate various glands and internal organs.