Silicone-containing thermoresponsive membranes to form an optical glucose biosensor.

Glucose biosensors that could be subcutaneously injected and interrogated without a physically connected electrode and transmitter affixed to skin would represent a major advancement in reducing the user burden of continuous glucose monitors (CGMs). Towards this goal, an optical glucose biosensor was formed by strategically tailoring a thermoresponsive double network (DN) membrane to house a phosphorescence lifetime-based glucose sensing assay. This membrane was selected based on its potential to exhibit reduced biofouling via 'self-cleaning' due to cyclical deswelling/reswelling in vivo. The membrane was strategically tailored to incorporate oxygen-sensitive metalloporphyrin phosphor, Pd meso-tetra(sulfophenyl)-tetrabenzoporphyrin ([PdPh4(SO3Na)4TBP]3) (HULK) and glucose oxidase (GOx). Specifically, electrostatic interactions and colvalent bonds were used to stabilize HULK and GOx within the membrane, respectively. Enhancing the oxygen permeability of the membrane was necessary to achieve sensitivity of HULK/GOx to physiological glucose levels. Thus, silicone microparticles were incorporated at two concentrations. Key properties of SiHy-0.25 and SiHy-0.5 microparticle-containing compositions were compared to a control having no microparticles (SiHy-0). The discrete nature of the silicone microparticles maintained the desired thermosensitivity profile and did not impact water content. While the modulus decreased with silicone microparticle content, membranes were more mechanically robust versus a conventional hydrogel. SiHy-0.25, owing to apparent phase separation, displayed greater glucose diffusion and oxygen permeability versus SiHy-0.5. Furthermore, SiHy-0.25 biosensors exhibited the greatest glucose sensitivity range of 100 to 300 mg dL-1versus only 100 to 150 mg dL-1 for both SiHy-0 and SiHy-0.5 biosensors.

Altered bladder-related brain network in multiple sclerosis women with voiding dysfunction.

OBJECTIVES: A number of neurourology imaging studies have mainly focused on investigating the brain activations during micturition in healthy and neuropathic patients. It is, however, also necessary to study brain functional connectivity (FC) within bladder-related regions to understand the brain organization during the execution of bladder function. This study aims to identify the altered brain network associated with bladder function in multiple sclerosis (MS) women with voiding dysfunction through comparisons with healthy subjects via concurrent urodynamic study (UDS)/functional magnetic resonance imaging (fMRI). MATERIALS AND METHODS: Ten healthy adult women and nine adult ambulatory women with clinically stable MS for ≥6 months and symptomatic voiding phase neurogenic lower urinary tract dysfunction (NLUTD) underwent UDS/fMRI evaluation with a task of bladder filling/emptying that was repeated three to five times. We quantitatively compared their FC within 17 bladder-related brain regions during two UDS phases: "strong desire to void" and "(attempt at) voiding initiation." RESULTS: At "strong desire to void," the healthy group showed significantly stronger FC in regions involved in bladder filling and suppression of voiding compared to the patient group. These regions included the bilateral anterior cingulate cortex, right supplementary motor area, and right middle frontal gyrus. During "(attempt at) voiding initiation," healthy subjects exhibited stronger FC in the right inferior frontal gyrus compared to MS patients. CONCLUSION: Our study offers a new way to identify alterations in the neural mechanisms underlying NLUTD and provides potential targets for clinical interventions (such as cortical neuromodulation) aimed at restoring bladder functions in MS patients.