Nanoparticles in the clinic: An update post COVID-19 vaccines

Nanoparticles are used in the clinic to treat cancer, resolve mineral deficiencies, image tissues, and facilitate vaccination. As a modular technology, nanoparticles combine diagnostic agents or therapeutics (e.g., elements, small molecules, biologics), synthetic materials (e.g., polymers), and biological molecules (e.g., antibodies, peptides, lipids). Leveraging these parameters, nanoparticles can be designed and tuned to navigate biological microenvironments, negotiate biological barriers, and deliver therapeutics or diagnostic agents to specific cells and tissues in the body. Recently, with the Emergency Use Authorization of the COVID-19 lipid nanoparticle vaccines, the advantages and potential of nanoparticles as a delivery vehicle have been displayed at the forefront of biotechnology. Here, we provide a 5-year status update on our original “Nanoparticles in the Clinic” review (also a 2-year update on our second “Nanoparticles in the Clinic” review) by discussing recent nanoparticle delivery system approvals, highlighting new clinical trials, and providing an update on the previously highlighted clinical trials

Modulating Oral Delivery and Gastrointestinal Kinetics of Recombinant Proteins via Engineered Fungi

A new modality in microbe-mediated drug delivery has recently emerged wherein genetically engineered microbes are used to locally deliver recombinant therapeutic proteins to the gastrointestinal tract. These engineered microbes are often referred to as live biotherapeutic products (LBPs). Despite advanced genetic engineering and recombinant protein expression approaches, little is known on how to control the spatiotemporal dynamics of LBPs and their secreted therapeutics within the gastrointestinal tract. To date, the fundamental pharmacokinetic analyses for microbe-mediated drug delivery systems have not been described. Here, we explore the pharmacokinetics of an engineered, model protein-secreting Saccharomyces cerevisiae, which serves as an ideal organism for the oral delivery of complex, post-translationally modified proteins. We establish three methods to modulate the pharmacokinetics of an engineered, recombinant protein-secreting fungi system: (i) altering oral dose of engineered fungi, (ii) co-administering antibiotics, and (iii) altering recombinant protein secretion titer. Our findings establish the fundamental pharmacokinetics which will be essential in controlling downstream therapeutic response for this new delivery modality

An overview of clinical and commercial impact of drug delivery systems

Drug delivery systems are widely researched and developed to improve the delivery of pharmaceutical compounds and molecules. The last few decades have seen a marked growth of the field fueled by increased number of researchers, research funding, venture capital and the number of start-ups. Collectively, the growth has led to novel systems that make use of micro/nano-particles, transdermal patches, inhalers, drug reservoir implants and antibody-drug conjugates. While the increased research activity is clearly an indication of proliferation of the field, clinical and commercial translation of early-stage research ideas is critically important for future growth and interest in the field. Here, we will highlight some of the examples of novel drug delivery systems that have undergone such translation. Specifically, we will discuss the developments, advantages, limitations and lessons learned from: (i) microparticle-based depot formulations, (ii) nanoparticle-based cancer drugs, (iii) transdermal systems, (iv) oral drug delivery systems, (v) pulmonary drug delivery, (vi) implants and (vii) antibody-drug conjugates. These systems have impacted treatment of many prevalent diseases including diabetes, cancer and cardiovascular diseases, among others. At the same time, these systems are integral and enabling components of products that collectively generate annual revenues exceeding US $100 billion. These examples provide strong evidence of the clinical and commercial impact of drug delivery systems

Batch Culture Formulation of Live Biotherapeutic Products

Live biotherapeutic products (LBPs) are an emerging therapeutic modality that have been clinically investigated for treating pathogenic infections and inflammatory diseases. A major class of LBPs are feces-derived microbial consortiums which require numerous process development steps (e.g., separation, purification, blending) to facilitate LBP formulation into oral dosage forms. A subset of these LBPs circumvents the need for continuous fecal processing by batch culture for individual strains of microbes that are rationally defined and combined in the final LBP formulation. Separately, delivery formulations (e.g., polymer encapsulation) are being developed for LBPs to improve storage and intestinal engraftment; however, formulation requires additional manufacturing processes distinct from fecal processing or batch culture. Here, a streamlined approach termed batch culture formulation (BCF) is developed to combine the individual batch culture and formulation processes into a single-step process. Based on a previously described polymeric film formulation that encapsulates LBPs, BCF is shown to reduce the number of required processes to formulate LBP-films without altering LBP phenotype, function, or storage profiles compared to the standard LBP-film formulation approach. Additionally, it is demonstrated that BCF facilitates scaled-fabrication from the milligram to gram scale with predictable loading, highlighting the potential that BCF has for clinical translation

Evaluation of Surface Modified Live Biotherapeutic Products for Oral Delivery

Live biotherapeutic products (LBPs), including symbiotic and genetically engineered bacteria, are a promising class of emerging therapeutics that are widely investigated both preclinically and clinically for their oral delivery to the gastrointestinal (GI) tract. One emergent delivery strategy involves the direct functionalization of LBP surfaces through noncovalent or covalent modifications to control LBP interactions with the GI microenvironment, thereby improving their viability, attachment, or therapeutic effect. However, unlike other therapeutic modalities, LBPs are living organisms which present two unique challenges for surface modifications: (1) this approach can directly interfere with key LBP biological processes (e.g., colonization, metabolite secretion) and (2) modification can be variable due to the dynamic nature of LBP surfaces. Collectively, these factors remain uncharacterized as they relate to the oral delivery of LBPs. Herein, we leverage our previously reported surface modification platform, which enables LBP surface-presentation of targeting ligands, to broadly evaluate and characterize surface modifications on LBPs. Specifically, we evaluate how LBP growth affects the dilution of surface-presented targeting ligands and the subsequent loss of specific target attachment over time. Next, we describe key surface modification parameters (e.g., concentration, residence time) that can be optimized to facilitate LBP target attachment. We then characterize how bioconjugation influences the suitability of LBPs for oral delivery by evaluating their growth, viability, storage, toxicity against mammalian cells, and in vivo colonization. Broadly, we describe key parameters that influence the performance of surface modified LBPs and subsequently outline an experimental pipeline for characterizing and evaluating their suitability for oral delivery

Enhanced Storage of Anaerobic Bacteria through Polymeric Encapsulation

Live microbes such as lactobacilli have long been used as probiotic supplements and, more recently, have been explored as live biotherapeutic products with the potential to treat a range of conditions. Among these microbes is a category of anaerobes that possess therapeutic potential while exhibiting unique oxygen sensitivity and thus requiring careful considerations in the formulation and storage processes. Existing microbial formulation development has focused on facultative anaerobes with natural oxygen tolerance; a few strategies have been reported for anaerobes with demonstrated oxygen intolerance, warranting novel approaches toward addressing the challenges for these oxygen-sensitive anaerobes. Here, we develop a polymeric encapsulation system for the formulation and storage ofBifidobacterium adolescentis(B. adolescentis), a model anaerobe that loses viability in aerobic incubation at 37 °C within 1 day. We discover that this strain remains viable under aerobic conditions for 14 days at 4 °C, enabling formulation development such as solution casting and air drying in an aerobic environment. Next, through a systematic selection of polymer encapsulants and excipients, we show that encapsulation with poly(vinyl alcohol) (PVA) acts as an oxygen barrier and facilitates long-term storage ofB. adolescentis, which is partially attributed to reduced generation of reactive oxygen species. Lastly, PVA-based formulations can produce oral capsule-loaded films and edible gummy bears, demonstrating its compatibility with both pharmaceutical and food dosage forms

Cell-mediated delivery of nanoparticles: Taking advantage of circulatory cells to target nanoparticles

Cellular hitchhiking leverages the use of circulatory cells to enhance the biological outcome of nanoparticle drug delivery systems, which often suffer from poor circulation time and limited targeting. Cellular hitchhiking utilizes the natural abilities of circulatory cells to: (i) navigate the vasculature while avoiding immune system clearance, (ii) remain relatively inert until needed and (iii) perform specific functions, including nutrient delivery to tissues, clearance of pathogens, and immune system surveillance. A variety of synthetic nanoparticles attempt to mimic these functional attributes of circulatory cells for drug delivery purposes. By combining the advantages of circulatory cells and synthetic nanoparticles, many advanced drug delivery systems have been developed that adopt the concept of cellular hitchhiking. Here, we review the development and specific applications of cellular hitchhiking-based drug delivery systems

Viral vector-based gene therapies in the clinic

Gene therapies are currently one of the most investigated therapeutic modalities in both the preclinical and clinical settings and have shown promise in treating a diverse spectrum of diseases. Gene therapies aim at introducing a gene material in target cells and represent a promising approach to cure diseases that were thought to be incurable by conventional modalities. In many cases, a gene therapy requires a vector to deliver gene therapeutics into target cells; viral vectors are among the most widely studied vectors owing to their distinguished advantages such as outstanding transduction efficiency. With decades of development, viral vector-based gene therapies have achieved promising clinical outcomes with many products approved for treating a range of diseases including cancer, infectious diseases and monogenic diseases. In addition, a number of active clinical trials are underway to further expand their therapeutic potential. In this review, we highlight the diversity of viral vectors, review approved products, and discuss the current clinical landscape of in vivo viral vector-based gene therapies. We have reviewed 13 approved products and their clinical applications. We have also analyzed more than 200 active trials based on various viral vectors and discussed their respective therapeutic applications. Moreover, we provide a critical analysis of the major translational challenges for in vivo viral vector-based gene therapies and discuss possible strategies to address the same

Surface Modifications for Improved Delivery and Function of Therapeutic Bacteria

Live therapeutic bacteria (LTBs) hold promise to treat microbiome-related diseases. However, few approaches to improve the colonization of LTBs in the gastrointestinal tract exist, despite colonization being a prerequisite for efficacy of many LTBs. Here, a modular platform to rapidly modify the surface of LTBs to enable receptor-specific interactions with target surfaces is reported. Inspired by bacterial adhesins that facilitate colonization, synthetic adhesins (SAs) are developed for LTBs in the form of antibodies conjugated to their surface. The SA platform is nontoxic, does not alter LTB growth kinetics, and can be used with any antibody or bacterial strain combination. By improving adhesion, SA-modified bacteria demonstrate enhanced in vitro pathogen exclusion from cell monolayers. In vivo kinetics of SA-modified LTBs is tracked in the feces and intestines of treated mice, demonstrating that SA-modified bacteria alter short-term intestinal transit and improve LTB colonization and pharmacokinetics. This platform enables rapid formation of an intestinal niche, leading to an increased maximum concentration and a 20% improvement in total LTB exposure. This work is the first application of traditional pharmacokinetic analysis to design and evaluate LTB drug delivery systems and provides a platform toward controlling adhesion, colonization, and efficacy of LTBs

Inorganic nanoparticles and the microbiome

Routine exposure to inorganic nanoparticles (NPs) that are incorporated into consumer products such as foods/drinks, packaging materials, pharmaceuticals, and personal care products (e.g. cosmetics, sunscreens, shampoos) occurs on a daily basis. The standard everyday use of these products facilitates interactions between the incorporated inorganic NPs, mammalian tissues (e.g. skin, gastrointestinal tract, oral cavity), and the community of microbes that resides on these tissues. Changes to the microbiome have been linked to the initiation/ progression of many diseases and there is a growing interest focused on understanding how inorganic NPs can initiate these changes. As these mechanisms are revealed and defined, it may be possible to rationally design microbiotamodulating therapies based on inorganic NPs. In this article, we will: (i) provide a background on inorganic NPs that are commonly found in consumer products such as those that incorporate titanium, zinc, silver, silica, or iron, (ii) discuss how NP properties, microbiota composition, and the physiological microenvironment can mediate the effects that inorganic NPs have on the microbiota, and (iii) highlight opportunities for inorganic NP therapies that are designed to interact with, and navigate, the microbiome