Vinod Labhasetwar

Gastrointestinal Uptake of Biodegradable Microparticles: Effect of Particle Size

AbstractPurpose. To investigate the effect of microparticle size on gastrointestinal tissue uptake. Methods. Biodegradable microparticles of various sizes using polylactic polyglycolic acid (50:50) co-polymer (100 nm, 500 nm, 1µm, and 10 µm) and bovine serum albumin as a model protein were formulated by water-in-oil-in-water emulsion solvent evaporation technique. The uptake of microparticles was studied in rat in situ intestinal loop model and quantitatively analyzed for efficiency of uptake. Results. In general, the efficiency of uptake of 100 nm size particles by the intestinal tissue was 15–250 fold higher compared to larger size microparticles. The efficiency of uptake was dependent on the type of tissue, such as Peyers patch and non patch as well as on the location of the tissue collected i.e. duodenum or ileum. Depending on the size of microparticles, the Peyers patch tissue had 2–200 fold higher uptake of particles than the non-patch tissue collected from the same region of the intestine. Histological evaluation of the tissue sections demonstrated that 100 nm particles were diffused throughout the submucosal layers while the larger size nano/microparticles were predominantly localized in the epithelial lining of the tissue. Conclusions. There is a microparticle size dependent exclusion phenomena in the gastrointestinal mucosal tissue with 100 nm size particles showing significantly greater tissue uptake. This has important implications in designing of nanoparticle-based oral drug delivery systems, such as an oral vaccine system.

The mechanism of uptake of biodegradable microparticles in Caco-2 cells is size dependent

AbstractPurpose. To study the uptake of biodegradable microparticles in Caco-2 cells. Methods. Biodegradable microparticles of polylactic polyglycolic acid co-polymer (PLGA 50:50) of mean diameters 0.1 μm, 1 μm, and 10 μm containing bovine serum albumin as a model protein and 6-coumarin as a fluorescent marker were formulated by a multiple emulsion technique. The Caco-2 cell monolayers were incubated with each diameter microparticles (100 μg/ml) for two hours. The microparticle uptake in Caco-2 cells was studied by confocal microscopy and also by quantitating the 6-coumarin content of the microparticles taken up by the cells. The effects of microparticle concentration, and incubation time and temperature on microparticle cell uptake were also studied. Results. The study demonstrated that the Caco-2 cell microparticle uptake significantly depends upon the microparticle diameter. The 0.1 μm diameter microparticles had 2.5 fold greater uptake on the weight basis than the 1 μm and 6 fold greater than the 10 μm diameter microparticles. Similarly in terms of number the uptake of 0.1 μm diameter microparticles was 2.7 × 103 fold greater than the 1 μm and 6.7 × 106 greater than the 10 μm diameter microparticles. The efficiency of uptake of 0.1 μm diameter microparticles at 100 μg/ml concentration was 41% compared to 15% and 6% for the 1 μm and the 10 μm diameter microparticles, respectively. The Caco-2 cell microparticle (0.1 μm) uptake increased with concentration in the range of 100 μg/ml to 500 μg/ml which then reached a plateau at higher concentration. The uptake of microparticles increased with incubation time, reaching a steady state at two hours. The uptake was greater at an incubation temperature of 37°C compared to at 4°C. Conclusions. The Caco-2 cell microparticle uptake was microparticle diameter, concentration, and incubation time and temperature dependent. The small diameter microparticles (0.1 μm) had significantly greater uptake compared to larger diameter microparticles. The results thus suggest that the mechanism of uptake of microparticles in Caco-2 cell is particle diameter dependent. Caco-2 cells are used as an in vitro model for gastrointestinal uptake, and therefore the results obtained in these studies could be of significant importance in optimizing the microparticle-based oral drug delivery systems.

Biodistribution, Clearance, and Biocompatibility of Iron Oxide Magnetic Nanoparticles in Rats

It is essential to determine the biodistribution, clearance, and biocompatibility of magnetic nanoparticles (MNPs) for in vivo biomedical applications to ensure their safe clinical use. We have studied these aspects with our novel iron oxide MNP formulation, which can be used as a magnetic resonance imaging (MRI) agent and a drug carrier system. Changes in serum and tissue iron levels were analyzed over 3 weeks after intravenous administration of MNPs to rats. Serum alanine aminotransferase (ALT), aspartate aminotransferase (AST), alkaline phosphatase (AKP) levels, and total iron-binding capacity (TIBC) were also measured with time to assess the effect of MNPs on liver function. Selected tissues were also analyzed for oxidative stress and studied histologically to determine biocompatibility of MNPs. Serum iron levels gradually increased for up to 1 week but levels slowly declined thereafter. Biodistribution of iron in various body tissues changed with time but greater fraction of the injected iron localized in the liver and spleen than in the brain, heart, kidney, and lung. Magnetization measurements of the liver and spleen samples showed a steady decrease over 3 weeks, suggesting particle degradation. Serum showed a transient increase in ALT, AST, AKP levels, and TIBC over a period of 6-24 h following MNP injection. The increase in oxidative stress was tissue dependent, reaching a peak at approximately 3 days and then slowly declining thereafter. Histological analyses of liver, spleen, and kidney samples collected at 1 and 7 days showed no apparent abnormal changes. In conclusion, our MNPs did not cause long-term changes in the liver enzyme levels or induce oxidative stress and thus can be safely used for drug delivery and imaging applications.

Magnetic nanoparticles with dual functional properties : Drug delivery and magnetic resonance imaging

There is significant interest in recent years in developing magnetic nanoparticles (MNPs) having multifunctional characteristics with complimentary roles. In this study, we investigated the drug delivery and magnetic resonance imaging (MRI) properties of our novel oleic acid-coated iron-oxide and pluronic-stabilized MNPs. The drug incorporation efficiency of doxorubicin and paclitaxel (alone or in combination) in MNPs was 74-95%; the drug release was sustained and the incorporated drugs had marginal effects on physical (size and zeta potential) and magnetization properties of the MNPs. The drugs in combination incorporated in MNPs demonstrated highly synergistic antiproliferative activity in MCF-7 breast cancer cells. The T2 relaxivity (r(2)) was higher for our MNPs than Feridex IV, whereas the T1 relaxivity (r(1)) was better for Feridex IV than for our MNPs, suggesting greater sensitivity of our MNPs than Feridex IV in T2 weighted imaging. The circulation half-life (t(1/2)), determined from the changes in the MRI signal intensity in carotid arteries in mice, was longer for our MNPs than Feridex IV (t(1/2)=31.2 vs. 6.4 min). MNPs with combined characteristics of MRI and drug delivery could be of high clinical significance in the treatment of various disease conditions.

Formulation and characterization of biodegradable nanoparticles for intravascular local drug delivery

Abstract Various drug-loaded poly(lactic-co-glycolic acid) (PLGA) nanoparticles (NP) were prepared using an emulsification/solvent evaporation technique. Different emulsion systems were employed according to the solubility of individual drugs so that an optimal drug incorporation efficiency and release profile were achieved for a variety of model compounds. Bovine serum albumin was studied as a model protein. Several specific Pharmacia and Upjohn drugs, U-86983, U-61431F, and U-74389G, as well as dexamethasone were tested because of our interest in intravascular drug delivery for the prevention of post-angioplasty restenosis. Drug loading in nanoparticles ranged from 10% to 30%. Typical particle size ranged from 60–200 nm with 85% of the particles in the range of 70–165 nm. The in vitro release rate for albumin was dependent upon the molecular weight (MW) of PLGA. Low MW (58 000) PLGA resulted in much faster BSA release than that of high MW (102 000) PLGA over 7 weeks. Cross-linking on the NP surface reduced the rate of drug release. Nanoparticle uptake by the arterial wall was evaluated by an ex vivo model utilizing freshly explanted dog carotid arteries. It was demonstrated that about 26% of the infused NP was initially retained by the intravascular matrix. A fraction (about 20%) of the initially retained NP remained in the arterial tissue 30 min or more after the end of the infusion. Nanoparticles with smaller mean size (100 nm vs. 266 nm) and lower drug loading (13.1% vs. 20.7%) resulted in higher arterial uptakes compared to nanoparticles of larger size and higher drug loadings. Sterilization of the drug-loaded nanoparticles by γ -irradiation at 2.5 Mrad dose showed no adverse effect on particle size, drug release behavior as well as ex vivo arterial uptake of the nanoparticles. In conclusion, this study demonstrated that a wide variety of water soluble and insoluble bioactive agents can be incorporated into PLGA nanoparticles with a high efficiency and adjustable drug loadings. By choosing the composition and the molecular weight of the polymeric matrix, the drug release kinetics from the nanoparticles can be controlled. Drug-loaded PLGA nanoparticles show great potential in intravascular local drug delivery.

Biophysical Interactions with Model Lipid Membranes: Applications in Drug Discovery and Drug Delivery

The transport of drugs or drug delivery systems across the cell membrane is a complex biological process, often difficult to understand because of its dynamic nature. In this regard, model lipid membranes, which mimic many aspects of cell-membrane lipids, have been very useful in helping investigators to discern the roles of lipids in cellular interactions. One can use drug-lipid interactions to predict pharmacokinetic properties of drugs, such as their transport, biodistribution, accumulation, and hence efficacy. These interactions can also be used to study the mechanisms of transport, based on the structure and hydrophilicity/hydrophobicity of drug molecules. In recent years, model lipid membranes have also been explored to understand their mechanisms of interactions with peptides, polymers, and nanocarriers. These interaction studies can be used to design and develop efficient drug delivery systems. Changes in the lipid composition of cells and tissue in certain disease conditions may alter biophysical interactions, which could be explored to develop target-specific drugs and drug delivery systems. In this review, we discuss different model membranes, drug-lipid interactions and their significance, studies of model membrane interactions with nanocarriers, and how biophysical interaction studies with lipid model membranes could play an important role in drug discovery and drug delivery.

3-D Tumor Model for In Vitro Evaluation of Anticancer Drugs

The efficacy of potential anticancer drugs during preclinical development is generally tested in vitro using cancer cells grown in monolayer; however, a significant discrepancy in their efficacy is observed when these drugs are evaluated in vivo. This discrepancy, in part, could be due to the three-dimensional (3-D) nature of tumors as compared to the two-dimensional (2-D) nature of monolayer cultures. Therefore, there is a need for an in vitro model that would mimic the 3-D nature of tumors. With this objective, we have developed surface-engineered, large and porous biodegradable polymeric microparticles as a scaffold for 3-D growth of cancer cells. Using the MCF-7 cell line as model breast cancer cells, we evaluated the antiproliferative effect of three anticancer drugs: doxorubicin, paclitaxel and tamoxifen in 3-D model vs in 2-D monolayer. With optimized composition of microparticles and cell culture conditions, a density of 4.5 x 10 (6) MCF-7 cells/mg of microparticles, which is an 18-fold increase from the seeding density, was achieved in six days of culture. Cells were observed to have grown in clumps on the microparticle surface as well as in their interior matrix structure. The antiproliferative effect of the drugs in 3-D model was significantly lower than in 2-D monolayer, which was evident from the 12- to 23-fold differences in their IC 50 values. Using doxorubicin, the flow cytometry data demonstrated approximately 2.6-fold lower drug accumulation in the cells grown in 3-D model than in the cells grown as 2-D monolayer. Further, only 26% of the cells in 3-D model had the same concentration of drug as the cells in monolayer, thus explaining the reduced activity of the drugs in 3-D model. The collagen content of the cells grown in 3-D model was 2-fold greater than that of the cells grown in 2-D, suggesting greater synthesis of extracellular matrix in 3-D model, which acted as a barrier to drug diffusion. The microarray analysis showed changes in several genes in cells grown in 3-D, which could also influence the drug effect. In conclusion, the cells grown in 3-D are more resistant to chemotherapy than those grown in 2-D culture, suggesting the significant roles of cellular architecture, phenotypic variations, and extracellular matrix barrier to drug transport in drug efficacy. We propose that our model provides a better assessment of drug efficacy than the currently used 2-D monolayer as many of its characteristic features are similar to an actual tumor. A well-characterized 3-D model can particularly be useful for rapid screening of a large number of therapeutics for their efficacy during the drug discovery phase.

TAT-conjugated nanoparticles for the CNS delivery of anti-HIV drugs

We have shown that nanoparticles (NPs) conjugated to trans-activating transcriptor (TAT) peptide bypass the efflux action of P-glycoprotein and increase the transport of the encapsulated ritonavir, a protease inhibitor (PI), across the blood-brain-barrier (BBB) to the central nervous system (CNS). A steady increase in the drug parenchyma/capillary ratio over time without disrupting the BBB integrity suggests that TAT-conjugated NPs are first immobilized in the brain vasculature prior to their transport into parenchyma. Localization of NPs in the brain parenchyma was further confirmed with histological analysis of the brain sections. The brain drug level with conjugated NPs was 800-fold higher than that with drug in solution at two weeks. Drug clearance was seen within four weeks. In conclusion, TAT-conjugated NPs enhanced the CNS bioavailability of the encapsulated PI and maintained therapeutic drug levels in the brain for a sustained period that could be effective in reducing the viral load in the CNS, which acts as a reservoir for the replicating HIV-1 virus.

Local intraluminal infusion of biodegradable polymeric nanoparticles: A novel approach for prolonged drug delivery after balloon angioplasty

BACKGROUND Several perfusion balloon catheters are under investigation for local drug delivery; however, sustained tissue drug levels are difficult to achieve with these techniques. To overcome this problem, sustained-release, biodegradable nanoparticles represent a potential alternative for prolonged local delivery. METHODS AND RESULTS A biodegradable polylactic-polyglycolic acid (PLGA) copolymer was used to formulate nanoparticles. Fluorescent-labeled nanoparticles were intraluminally administered in a single, 180-second infusion after balloon injury in the rat carotid model. Localization and retention at different time points and biocompatibility of nanoparticles were evaluated. To evaluate the potential of the system in the prevention of neointimal formation, dexamethasone was incorporated into the particles and delivered locally as above. Nanoparticles were seen in the three layers of the artery at 3 hours and 24 hours. At 3 days, they were mainly present in the adventitial layer, decreasing at 7 days, with no fluorescent activity at 14 days. The PLGA nanoparticles appeared to be fully biocompatible. In the dexamethasone nanoparticle study, a significant amount of dexamethasone was present in the treated segment for up to 14 days after a single infusion, with no plasma levels detected after the first 3 hours. There was a 31% reduction in intima-media ratio in animals treated with local dexamethasone nanoparticles compared with control. CONCLUSIONS Nanoparticles successfully penetrated into the vessel wall and persisted for up to 14 days after a short, single intraluminal infusion. Local administration of nanoparticles with incorporated dexamethasone significantly decreased neointimal formation. This methodology appears to have important potential for clinical applications in local drug delivery.

Quantification of the Force of Nanoparticle-Cell Membrane Interactions and Its Influence on Intracellular Trafficking of Nanoparticles

Understanding the interaction of nanoparticles (NPs) with the cell membrane and their trafficking through cells is imperative to fully explore the use of NPs for efficient intracellular delivery of therapeutics. Here, we report a novel method of measuring the force of NP-cell membrane interactions using atomic force microscopy (AFM). Poly(D,L-lactide-co-glycolide) (PLGA) NPs functionalized with poly-L-lysine were used as a model system to demonstrate that this force determines the adhesive interaction of NPs with the cell membrane and in turn the extent of cellular uptake of NPs, and hence that of the encapsulated therapeutic. Cellular uptake of NPs was monitored using AFM imaging and the dynamics of their intracellular distribution was quantified using confocal microscopy. Results demonstrated that the functionalized NPs have a five-fold greater force of adhesion with the cell membrane and the time-lapse AFM images show their rapid internalization than unmodified NPs. The intracellular trafficking study showed that the functionalized NPs escape more rapidly and efficiently from late endosomes than unmodified NPs and result in 10-fold higher intracellular delivery of the encapsulated model protein. The findings described herein enhance our basic understanding of the NP-cell membrane interaction on the basis of physical phenomena that could have wider applications in developing efficient nanocarrier systems for intracellular delivery of therapeutics.