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.

Robotically handled whole-tissue culture system for the screening of oral drug formulations.

Monolayers of cancer-derived cell lines are widely used in the modelling of the gastrointestinal (GI) absorption of drugs and in oral drug development. However, they do not generally predict drug absorption in vivo. Here, we report a robotically handled system that uses large porcine GI tissue explants that are functionally maintained for an extended period in culture for the high-throughput interrogation (several thousand samples per day) of whole segments of 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.

Convergence for Translation: Drug-Delivery Research in Multidisciplinary Teams.

The void between drug discovery and successful translation to humans is vast. In order to develop effective solutions, convergence of a multidisciplinary team with a range of expertise is required. In this Essay, examples of successful sustained delivery systems for antimalarials and antiretrovirals, as well as to the gastrointestinal tract are discussed.

Defining optimal permeant characteristics for ultrasound-mediated gastrointestinal delivery.

Ultrasound-mediated drug delivery in the gastrointestinal (GI) tract is a bourgeoning area of study. Localized, low-frequency ultrasound has recently been shown to enable significant enhancement in delivery of a broad set of active pharmaceutical ingredients including small molecules, proteins, and nucleic acids without any formulation or encapsulation of the therapeutic. Traditional chemical formulations are typically required to protect, stabilize, and enable the successful delivery of a given therapeutic.

Ultrasound-Mediated Delivery of RNA to Colonic Mucosa of Live Mice.

Background & Aims: It is a challenge to deliver nucleic acids to gastrointestinal (GI) tissues due to their size and need for intracellular delivery. They are also extremely susceptible to degradation by nucleases, which are ubiquitous in the GI tract. We investigated whether ultrasound, which can permeabilize tissue through a phenomenon known as transient cavitation, can be used to deliver RNA to the colonic mucosa of living mice.

Ultrasound-mediated gastrointestinal drug delivery.

There is a significant clinical need for rapid and efficient delivery of drugs directly to the site of diseased tissues for the treatment of gastrointestinal (GI) pathologies, in particular, Crohn's and ulcerative colitis. However, complex therapeutic molecules cannot easily be delivered through the GI tract because of physiologic and structural barriers. We report the use of ultrasound as a modality for enhanced drug delivery to the GI tract, with an emphasis on rectal delivery.

Applicability and safety of dual-frequency ultrasonic treatment for the transdermal delivery of drugs.

Low-frequency ultrasound presents an attractive method for transdermal drug delivery. The controlled, yet non-specific nature of enhancement broadens the range of therapeutics that can be delivered, while minimizing necessary reformulation efforts for differing compounds. Long and inconsistent treatment times, however, have partially limited the attractiveness of this method.

Ultrasound-enhanced transdermal delivery: recent advances and future challenges.

The skin is a formidable diffusion barrier that restricts passive diffusion to small (<500 Da) lipophilic molecules. Methods used to permeabilize this barrier for the purpose of drug delivery are maturing as an alternative to oral drug delivery and hypodermic injections. Ultrasound can reversibly and non-invasively permeabilize the diffusion barrier posed by the skin.

Microneedles for drug delivery via the gastrointestinal tract.

Both patients and physicians prefer the oral route of drug delivery. The gastrointestinal (GI) tract, though, limits the bioavailability of certain therapeutics because of its protease and bacteria-rich environment as well as general pH variability from pH 1 to 7. These extreme environments make oral delivery particularly challenging for the biologic class of therapeutics.

Single compartment drug delivery.

Drug design is built on the concept that key molecular targets of disease are isolated in the diseased tissue. Systemic drug administration would be sufficient for targeting in such a case. It is, however, common for enzymes or receptors that are integral to disease to be structurally similar or identical to those that play important biological roles in normal tissues of the body.

Skin permeabilization for transdermal drug delivery: recent advances and future prospects.

Introduction: Transdermal delivery has potential advantages over other routes of administration. It could reduce first-pass metabolism associated with oral delivery and is less painful than injections. However, the outermost layer of the skin, the stratum corneum (SC), limits passive diffusion to small lipophilic molecules.

Rapid skin permeabilization by the simultaneous application of dual-frequency, high-intensity ultrasound.

Low-frequency ultrasound has been studied extensively due to its ability to enhance skin permeability. In spite of this effort, improvements in enhancing the efficacy of transdermal ultrasound treatments have been limited. Currently, when greater skin permeability is desired at a given frequency, one is limited to increasing the intensity or the duration of the ultrasound treatment, which carries the risk of thermal side effects.

Computational and experimental investigation of needle-shaped crystal breakage.

Needle-shaped crystals are a common occurrence in many pharmaceutical and fine chemicals processes. Even if the particle size distribution (PSD) obtained in a crystallization step can be controlled by the crystal growth kinetics and hydrodynamic conditions, further fluid-solid separation steps such as filtration, filter washing, drying, and subsequent solids handling can often lead to uncontrolled changes in the PSD due to breakage. In this contribution we present a combined computational and experimental methodology for determining the breakage kernel and the daughter distribution functions of needle-shaped crystals, and for population balance modeling of their breakage.