An automated all-in-one system for carbohydrate tracking, glucose monitoring, and insulin delivery.

Glycemic control through titration of insulin dosing remains the mainstay of diabetes mellitus treatment. Insulin therapy is generally divided into dosing with long- and short-acting insulin, where long-acting insulin provides basal coverage and short-acting insulin supports glycemic excursions associated with eating. The dosing of short-acting insulin often involves several steps for the user including blood glucose measurement and integration of potential carbohydrate loads to inform safe and appropriate dosing. The significant burden placed on the user for blood glucose measurement and effective carbohydrate counting can manifest in substantial effects on adherence. Through the application of computer vision, we have developed a smartphone-based system that is able to detect the carbohydrate load of food by simply taking a single image of the food and converting that information into a required insulin dose by incorporating a blood glucose measurement. Moreover, we report the development of comprehensive all-in-one insulin delivery systems that streamline all operations that peripheral devices require for safe insulin administration, which in turn significantly reduces the complexity and time required for titration of insulin. The development of an autonomous system that supports maximum ease and accuracy of insulin dosing will transform our ability to more effectively support patients with diabetes.

Platform for the Delivery of Unformulated RNA In Vivo.

The successful delivery of RNA therapeutics is the gating hurdle to greater clinical translation and utility of this novel class of therapeutics. Delivery strategies today are limited and predominantly rely on lipid nanoparticles or conjugates, which can facilitate hepatic delivery but are poor for achieving uptake outside the liver. The ability to deliver RNA to other organs outside the liver in a formulation-agnostic approach could serve to unlock the broader potential of these therapies and enable their use in a broader set of disease. Here we demonstrate this formulation-agnostic delivery of two model siRNAs using low-frequency ultrasound to the gastrointestinal (GI) tract. Unformulated siRNAs targeting ß-catenin (Ctnnb 1) and Sjögren syndrome antigen B (SSB) genes were successfully delivered to colonic mucosa in mice, achieving robust knockdown of the target mRNA from whole-colon tissue samples. Indeed, the capacity to target and successfully suppress expression from genes underscores the power of this platform to rapidly deliver unformulated and unoptimized sequences against a range of targets in the GI tract.

Ultra-rapid drug delivery in the oral cavity using ultrasound.

The delivery of therapeutics to the gastrointestinal (GI) mucosa remains primarily a function of diffusion and rapid delivery is a significant goal in drug delivery science. However, delivery is hindered by the molecular barrier properties of the mucosa, as well as environmental factors. We hypothesized that low-frequency ultrasound can overcome these barriers, achieving rapid delivery in an engineered, clinically-relevant system for buccal administration. The hand-held system enabled delivery of macromolecules in short, 60-s treatment times ex vivo. Tolerability of the prototype was demonstrated in awake, (unsedated) dogs. Finally, this technology enhanced the efficacy of the anti-inflammatory agent, budesonide, allowing for prophylactic treatment in a hamster model of oral inflammatory lesions in vivo. The capacity to deliver therapeutics in a targeted and rapid manner in a clinically-relevant form-factor presents an intriguing capability to expand the repertoire of therapeutics that can be applied topically in the mouth and beyond.