Brijeshkumar Patel

PEG-PLGA based large porous particles for pulmonary delivery of a highly soluble drug, low molecular weight heparin.

This study was designed to evaluate the feasibility of PEG-PLGA copolymers as carriers for pulmonary delivery of a highly soluble drug. We attempt to address the limitations of low entrapment efficiencies and poor release profiles that are associated with the use of conventional PLGAs. We have used low molecular weight heparin (LMWH) as a model for highly soluble and ionizable drugs and a 3 × 3 full factorial design to prepare nine formulations. We considered polymer type and percent NaCl in external phase as two independent variables at three different levels; the levels for polymer type were PLGA, PEG-PLGA and PLGA-PEG-PLGA and that for percent NaCl were 0%, 5% and 8%. Formulations were characterized for various physical properties, respirability, drug release, and evaluated for in vivo absorption, alveolar uptake, and safety. Statistical analyses suggest that both polymer type and salt concentration influenced the morphology and micromeritic properties of the particles. Compared with PLGA, PEG-PLGA copolymers produced inherently larger porous particles with high drug entrapment and a greater extent of drug release. Moreover, addition of NaCl in the external phase maximized drug entrapment but minimized burst release and produced smaller and denser particles. Fluorescent PEG-PLGA particles showed reduced uptake by alveolar macrophages, and exhibited a uniform distribution in the lungs compared with PLGA particles. Further, ~85% of the particles were cleared off the lungs within 6 days. Intratracheally administered PEG-PLGA based optimized formulation exhibited a biological half-life of 18.64 h, which was ~4.5 times longer than plain LMWH. No cytotoxic effect was observed when bronchial epithelial cells were incubated with PEG-PLGA based formulations. Similarly, no increase in the injury markers was observed in the bronchoalveolar lavage fluids collected from rats treated with PEG-PLGA particles of LMWH. Overall, this study suggests that PEG-PLGA block copolymers have the potential to be developed as efficient and biocompatible carriers for pulmonary delivery of highly water-soluble drugs.

In vitro, in vivo and ex vivo models for studying particle deposition and drug absorption of inhaled pharmaceuticals

Delivery of therapeutic agents via the pulmonary route has gained significant attention over the past few decades because this route of administration offers multiple advantages over traditional routes that include localized action, non-invasive nature and favorable lung-to-plasma ratio. However, assessment of post administration behavior of inhaled pharmaceuticals-such as deposition of particles over the respiratory airways, interaction with the respiratory fluid and movement across the air-blood barrier-is challenging because the lung is a very complex organs that is composed of airways with thousands of bifurcations with variable diameters. Thus, much effort has been put forward to develop models that mimic human lungs and allow evaluation of various pharmaceutical and physiological factors that influence the deposition and absorption profiles of inhaled formulations. In this review, we sought to discuss in vitro, in vivo and ex vivo models that have been extensively used to study the behaviors of airborne particles in the lungs and determine the absorption of drugs after pulmonary administration. We have provided a summary of lung cast models, cascade impactors, noninvasive imaging, intact animals, cell culture and isolated perfused lung models as tools to evaluate the distribution and absorption of inhaled particles. We have also outlined the limitations of currently used models and proposed future studies to enhance the reproducibility of these models.

Microfluidics-based 3D cell culture models: Utility in novel drug discovery and delivery research

Abstract The implementation of microfluidic devices within life sciences has furthered the possibilities of both academic and industrial applications such as rapid genome sequencing, predictive drug studies, and single cell manipulation. In contrast to the preferred two‐dimensional cell‐based screening, three‐dimensional (3D) systems have more in vivo relevance as well as ability to perform as a predictive tool for the success or failure of a drug screening campaign. 3D cell culture has shown an adaptive response to the recent advancements in microfluidic technologies which has allowed better control over spheroid sizes and subsequent drug screening studies. In this review, we highlight the most significant developments in the field of microfluidic 3D culture over the past half‐decade with a special focus on their benefits and challenges down the lane. With the newer technologies emerging, implementation of microfluidic 3D culture systems into the drug discovery pipeline is right around the bend.

Particle engineering to enhance or lessen particle uptake by alveolar macrophages and to influence the therapeutic outcome

The alveolar macrophages defend the lung against airborne pollutants and infectious microorganisms. Recent advances in the understanding of the role of macrophages in generation of immunological and inflammatory responses have established that alveolar macrophages could be used as targets for drug delivery. Enhanced uptake of particulate drug carriers by macrophages could be beneficial in pathological conditions such as tuberculosis and HIV where infectious microorganisms utilize macrophages as a safe haven and a vehicle to further infections. In contrary, to achieve prolonged residence time, extended drug release and in desired situations, increased systemic absorption, drug carrying particles that can avoid recognition and uptake by alveolar macrophages may prove to be significantly advantageous. Drug targeting to macrophages can achieve superior therapeutic efficacy for the treatment of medical conditions that involve tumorigenesis, inflammation and infections. Various particulate carriers containing therapeutic agents have been used to deliver drugs to the macrophages residing in the lung. Particulate systems have also been engineered to facilitate or avoid uptake by macrophages. But pathological conditions to be treated and drug delivery goals dictate the engineering approach for reducing or enhancing uptake by macrophages. In this review, we have summarized the influence of various physicochemical properties--composition, size, shape, pegylation and presence or absence of surface ligands--of particulate carriers on their uptake by macrophages. We have also described the macrophage biology and strategies that have been used to influence uptake and avoidance of particulate carriers by macrophages.

Starch-coated magnetic liposomes as an inhalable carrier for accumulation of fasudil in the pulmonary vasculature

In this study, we tested the feasibility of magnetic liposomes as a carrier for pulmonary preferential accumulation of fasudil, an investigational drug for the treatment of pulmonary arterial hypertension (PAH). To develop an optimal inhalable formulation, various magnetic liposomes were prepared and characterized for physicochemical properties, storage stability and in vitro release profiles. Select formulations were evaluated for uptake by pulmonary arterial smooth muscle cells (PASMCs) - target cells - using fluorescence microscopy and HPLC. The efficacy of the magnetic liposomes in reducing hyperplasia was tested in 5-HT-induced proliferated PASMCs. The drug absorption profiles upon intratracheal administration were monitored in healthy rats. Optimized spherical liposomes - with mean size of 170 nm, zeta potential of -35mV and entrapment efficiency of 85% - exhibited an 80% cumulative drug release over 120 h. Fluorescence microscopic study revealed an enhanced uptake of liposomes by PASMCs under an applied magnetic field: the uptake was 3-fold greater compared with that observed in the absence of magnetic field. PASMC proliferation was reduced by 40% under the influence of the magnetic field. Optimized liposomes appeared to be safe when incubated with PASMCs and bronchial epithelial cells. Compared with plain fasudil, intratracheal magnetic liposomes containing fasudil extended the half-life and area under the curve by 27- and 14-fold, respectively. Magnetic-liposomes could be a viable delivery system for site-specific treatment of PAH.

Fasudil and SOD packaged in peptide-studded-liposomes: Properties, pharmacokinetics and ex-vivo targeting to isolated perfused rat lungs

The present study investigated the feasibility of encapsulating two drugs, fasudil and superoxide dismutase (SOD), into liposomes for targeted and inhalational delivery to the pulmonary vasculature to treat pulmonary arterial hypertension (PAH). Nanosized liposomes were prepared by a thin-film formation and extrusion method, and the drugs were encapsulated by a modified freeze-thaw technique. The peptide CARSKNKDC (CAR), a pulmonary-specific targeting sequence, was conjugated on the surface of liposomes. Formulations were optimized for various physicochemical properties, tested for their ex-vivo and in-vivo drug absorption after intratracheal administration, and evaluated for short-term safety in healthy rats. The homogenous nanosized liposomes contained both SOD (~55% entrapment) and fasudil (~40% entrapment), and were stable at 4°C and after nebulization. Liposomes released the drugs in a controlled-release fashion. Compared with plain liposomes, CAR-liposomes increased the uptake by pulmonary endothelial and smooth muscle cells by ~2-fold. CAR-liposomes extended the biological half-lives of SOD and fasudil by ~3-fold. Ex-vivo studies demonstrated that CAR-liposomes were better retained in the lungs than plain liposomes. Bronchoalveolar lavage studies indicated the safety of peptide-equipped liposomes as pulmonary delivery carriers. Overall, this study demonstrates that CAR-liposomes may be used as inhalational carriers for SOD plus fasudil-based combination therapy for PAH.

Computational and bioengineered lungs as alternatives to whole animal, isolated organ, and cell-based lung models

Development of lung models for testing a drug substance or delivery system has been an intensive area of research. However, a model that mimics physiological and anatomical features of human lungs is yet to be established. Although in vitro lung models, developed and fine-tuned over the past few decades, were instrumental for the development of many commercially available drugs, they are suboptimal in reproducing the physiological microenvironment and complex anatomy of human lungs. Similarly, intersubject variability and high costs have been major limitations of using animals in the development and discovery of drugs used in the treatment of respiratory disorders. To address the complexity and limitations associated with in vivo and in vitro models, attempts have been made to develop in silico and tissue-engineered lung models that allow incorporation of various mechanical and biological factors that are otherwise difficult to reproduce in conventional cell or organ-based systems. The in silico models utilize the information obtained from in vitro and in vivo models and apply computational algorithms to incorporate multiple physiological parameters that can affect drug deposition, distribution, and disposition upon administration via the lungs. Bioengineered lungs, on the other hand, exhibit significant promise due to recent advances in stem or progenitor cell technologies. However, bioengineered approaches have met with limited success in terms of development of various components of the human respiratory system. In this review, we summarize the approaches used and advancements made toward the development of in silico and tissue-engineered lung models and discuss potential challenges associated with the development and efficacy of these models.

Low-molecular-weight heparin (LMWH)-loaded large porous PEG-PLGA particles for the treatment of asthma.

BACKGROUND Heparin-like compounds interrupt leukocyte adhesion and migration, and prevent release of chemical mediators during the process of inflammation. However, little is known whether the anti-inflammatory property of smaller heparin fragments, low-molecular-weight heparin (LMWH), plays any role in the process of airway inflammation. In this study, we sought to evaluate the efficacy of LMWH-loaded large porous polyethylene glycol-poly(D,L-lactide-co-glycolide) (PEG-PLGA) particulate formulations in alleviating the cellular and biochemical changes associated with asthma. METHODS To study the pharmacological efficacy of LMWH for the treatment of asthma, we have used a previously optimized polymeric formulation of LMWH. The anti-asthmatic efficacy of the optimized formulation was studied in an ovalbumin-sensitized rat model of asthma. The influence of the formulation on asthmatic lungs was assessed by measuring the total protein content and number of inflammatory cells in the bronchoalveolar lavage fluid (BALF). Lungs were also examined for morphological and structural changes that may occur in asthmatic lungs. RESULTS Compared with healthy animals, asthmatic animals showed a seven- and threefold increase in the protein content and number of inflammatory cells in BALF, respectively. However, intratracheal LMWH particles reduced the protein content by 2.5-fold and the number of inflammatory cells by 1.8-fold-comparable to those of sham animals. Similarly, LMWH particles reduced the lactate dehydrogenase levels by 2.8- and threefold in BALF and plasma, respectively. The airway wall thickness also decreased from 47.37±6.02 μm to 21.35±3.60 μm upon treatment with PEG-PLGA particles of LMWH. Goblet cell hyperplasia was also reduced in asthmatic rats treated with LMWH particles. CONCLUSION PLGA particles of LMWH were efficacious in improving cellular and histological changes associated with asthma, and thus this polymeric formulation has the potential for further development into a clinically viable anti-asthma therapy.

Aerosolized Montelukast Polymeric Particles—An Alternative to Oral Montelukast–Alleviate Symptoms of Asthma in a Rodent Model

ABSTRACTPurposeCysteinyl leukotrienes (CysLTs) propagate inflammatory reactions that result from allergen exposure in asthma. Montelukast, a CysLT type-1 receptor antagonist, disrupts mediator–receptor interactions and minimizes inflammatory response. In this study, we have evaluated anti-asthmatic efficacy of inhalable montelukast-loaded large porous particulate formulations in ovalbumin-induced rat airway inflammation model that mimics asthma.MethodsThe anti-inflammatory effects of a montelukast-loaded formulation were investigated in rats by measuring the total protein content, levels of injury markers and number of inflammatory cells in the bronchoalveolar lavage fluid (BALF). The histopathological studies assessed the morphological and structural changes that occur in asthmatic lungs. Animals were also challenged with methacholine to examine the airway hyper-reactivity.ResultsCompared with healthy animals, asthmatic animals showed a 3.8- and 4.77-fold increase in the protein content and number of inflammatory cells in BALF, respectively. Intratracheal montelukast particles reduced the protein content by 3.3-fold and the number of inflammatory cells by 2.62-fold. Also, montelukast particles reduced the lactate dehydrogenase (LDH) and myeloperoxidase (MPO) levels by a 4.87- and 6.8-fold in BALF, respectively. Montelukast particles reduced the airway wall thickness by 2.5-fold compared with untreated asthmatic lungs. Further, particulate formulation protected the lungs against methacholine-induced bronchial provocation (p < 0.05).ConclusionsRespirable large porous particles containing montelukast alleviated allergen-induced inflammatory response in an animal model and prevented histological changes associated with asthma. Thus montelukast-loaded large porous polylactic acid (PLA) particles could be an aerosolized delivery approach for administration of currently available oral montelukast.

Inhaled sildenafil as an alternative to oral sildenafil in the treatment of pulmonary arterial hypertension (PAH)

ABSTRACT The practice of treating PAH patients with oral or intravenous sildenafil suffers from the limitations of short dosing intervals, peripheral vasodilation, unwanted side effects, and restricted use in pediatric patients. In this study, we sought to test the hypothesis that inhalable poly(lactic‐co‐glycolic acid) (PLGA) particles of sildenafil prolong the release of the drug, produce pulmonary specific vasodilation, reduce the systemic exposure of the drug, and may be used as an alternative to oral sildenafil in the treatment of PAH. Thus, we prepared porous PLGA particles of sildenafil using a water‐in‐oil‐in‐water double emulsion solvent evaporation method with polyethyleneimine (PEI) as a porosigen and characterized the formulations for surface morphology, respirability, in‐vitro drug release, and evaluated for in vivo absorption, alveolar macrophage uptake, and safety. PEI increased the particle porosity, drug entrapment, and produced drug release for 36 h. Fluorescent particles showed reduced uptake by alveolar macrophages. The polymeric particles were safe to rat pulmonary arterial smooth muscle cell and to the lungs, as evidenced by the cytotoxicity assay and analyses of the injury markers in the bronchoalveolar lavage fluid, respectively. Intratracheally administered sildenafil particles elicited more pulmonary specific and sustained vasodilation in SUGEN‐5416/hypoxia‐induced PAH rats than oral, intravenous, or intratracheal plain sildenafil did, when administered at the same dose. Overall, true to the hypothesis, this study shows that inhaled PLGA particles of sildenafil can be administered, as a substitute for oral form of sildenafil, at a reduced dose and longer dosing interval.