Pentamidine-loaded poly(D,L-lactide) nanoparticles: Adsorption and drug release

Nanotechnological approaches for pentamidine delivery

Pentamidine (PTM), which is a diamine that is widely known for its antimicrobial activity, is a very interesting drug whose mechanism of action is not fully understood. In recent years, PTM has been proposed as a novel potential drug candidate for the treatment of mental illnesses, myotonic dystrophy, diabetes, and tumors. Nevertheless, the systemic administration of PTM causes severe side effects, especially nephrotoxicity. In order to efficiently deliver PTM and reduce its side effects, several nanosystems that take advantage of the chemical characteristics of PTM, such as the presence of two positively charged amidine groups at physiological pH, have been proposed as useful delivery tools. Polymeric, lipidic, inorganic, and other types of nanocarriers have been reported in the literature for PTM delivery, and they are all in different development phases. The available approaches for the design of PTM nanoparticulate delivery systems are reported in this review, with a particular emphasis on formulation strategies and in vitro/in vivo applications. Furthermore, a critical view of the future developments of nanomedicine for PTM applications, based on recent repurposing studies, is provided. Created with BioRender.com.

Comparative in vitro transportation of pentamidine across the blood-brain barrier using polycaprolactone nanoparticles and phosphatidylcholine liposomes

Nanoparticles (NPs) have gained importance in addressing drug delivery challenges across biological barriers. Here, we reformulated pentamidine, a drug used to treat Human African Trypanosomiasis (HAT) in polymer based nanoparticles and liposomes and compared their capability to enhance pentamidine penetration across blood brain barrier (BBB). Size, polydispersity index, zeta potential, morphology, pentamidine loading and drug release profiles were determined by various methods. Cytotoxicity was tested against the immortalized mouse brain endothelioma cells over 96 h. Moreover, cells monolayer integrity and transportation ability were examined for 24 h. Pentamidine-loaded polycaprolactone (PCL) nanoparticles had a mean size of 267.58, PDI of 0.25 and zeta potential of -28.1 mV and pentamidine-loaded liposomes had a mean size of 119.61 nm, PDI of 0.25 and zeta potential 11.78. Pentamidine loading was 0.16 µg/mg (w/w) and 0.17 µg/mg (w/w) in PCL NPs and liposomes respectively. PCL nanoparticles and liposomes released 12.13% and 22.21% of pentamidine respectively after 24 h. Liposomes transported 87% of the dose, PCL NPs 66% of the dose and free pentamidine penetration was 63% of the dose. These results suggest that liposomes are comparatively promising nanocarriers for transportation of pentamidine across BBB.

mPEG-PLA and PLA-PEG-PLA nanoparticles as new carriers for delivery of recombinant human Growth Hormone (rhGH)

mPEG-PLA and PLA-PEG-PLA copolymeric nanoparticles with three different PLA to PEG ratios are synthesized and used for encapsulation of recombinant human Growth hormone (rhGH). The structure and composition of the synthesized copolymers were analyzed by ¹H NMR and GPC techniques. Moreover, morphology, encapsulation efficiency (EE), cytotoxicity, release profile and stability of the encapsulated rhGH were measured. Structural analysis of the prepared copolymers showed that they were successfully synthesized with approximately expected molecular weight and relatively low size distribution. It was also revealed that by increasing amounts of PLA/PEG ratio, EE content and size of nanoparticles were increased. Release profile evaluation of rhGH from both formulations indicated that copolymeric nanoparticles of Di-B2 and Tri-B2 exhibited the best results among the synthesized nanospheres, by having initial burst release of 17.5% and 28% and then slow and constant release of rhGH up to 65% and 77% of the encapsulated drug, respectively. Furthermore, results of HPLC, SDS-PAGE and CD analyses showed stability of rhGH during encapsulation and release from nanoparticles. Finally, the results showed that these two formulations provided safe and efficient sustained release of rhGH for more than a month and they have the potential to do further studies under in vivo conditions.

Nanospheres encapsulating anti-leishmanial drugs for their specific macrophage targeting, reduced toxicity, and deliberate intracellular release

The current work focuses on the study of polymeric, biodegradable nanoparticles (NPs) for the encapsulation of doxorubicin and mitomycin C (anti-leishmanial drugs), and their efficient delivery to macrophages, the parasite's home. The biodegradable polymer methoxypoly-(ethylene glycol)-b-poly (lactic acid) (MPEG-PLA) was used to prepare polymeric NPs encapsulating doxorubicin and mitomycin C. The morphology, mean diameter, and surface area of spherical NPs were determined by transmission electron microscopy (TEM), field emission scanning electron microscopy (FESEM), and BET surface area analysis. X-ray diffraction was performed to validate drug encapsulation. An in vitro release profile of the drugs suggested a fairly slow release. These polymeric NPs were efficiently capable of releasing drug inside macrophages at a slower pace than the free drug, which was monitored by epi-fluorescence microscopy. Encapsulation of doxorubicin and mitomycin C into NPs also decreases cellular toxicity in mouse macrophages (J774.1A).

Physicochemical and biological aspects of macrophage-mediated drug targeting in anti-microbial therapy

Macrophages are important drug targets as they mediate a wide variety of infectious diseases. Visceral leishmaniasis (VL), schistosomiasis, brucellosis, and salmonellosis are some of the well-known infectious diseases in which macrophages play a prominent pathophysiological role. For instance, VL parasites exclusively house in the macrophages of liver and spleen. They are resistant to lysosomal degradation by unknown mechanisms, they survive and thrive safely within macrophages, they multiply, and they ultimately affect visceral organs, leading to severe pathological and sometimes even fatal conditions. The majority of routinely used drugs administered in free form distribute all over the body via systemic circulation, leading to relatively low therapeutic activity and a certain degree of toxicity. Unlike for nonmicrobial diseases, targeting parasites procuring resistance and ineffective therapeutic outcome can be obviously speculated in case of infectious disease. The preferential uptake by macrophages, intended to improve the balance between efficacy and toxicity, can be achieved by the use of nanomedicines, i.e. submicron-sized macromolecular or particulate drug delivery systems. This insight has stimulated researchers to use nanomedicines--which tend to be recognized by macrophages as 'foreign' and consequently are taken up by the intended target cells much more effectively than their free drug counterparts--to improve the treatment of infectious diseases. The literature reports extensively on such approaches; however, there are several constraints that limit the application of nanomedicine in macrophage-mediated drug targeting. Here, we briefly describe the strategies that are used to achieve effective drug targeting to macrophages, using VL as a model disease, and we also put forth an understanding of the most important limiting factors. Various physicochemical and biological factors used by researchers as reported in the literature are addressed, and the most important mechanisms and modes by which macrophage-specific drug targeting can be achieved are summarized. Based on the evidence obtained to date, it can be concluded that targeting macrophages is a valuable and validated strategy for improving the treatment of infectious diseases.

Relationship between drug release and some physical parameters of drug sorption onto PLA fibers

Drug release and its relationship with kinetic and thermodynamic parameters of drug sorption onto poly(lactic acid) (PLA) fibers have been studied using Diclofenac, 5-Fluorouracil (5-FU) and Metformin as model drugs. The sorption method is more flexible and avoids the damaged drugs, remaining toxic organic solvents and safety problems which occurred with the dissolution method. The quantitative relationship with high correlation between drug-release and drug-loading concentration, affinity and activation energy for diffusion has been established to predict the initial burst and subsequent release of the drugs. Drugs with higher activation energy for diffusion, lower diffusion coefficients and higher affinity on PLA fiber, such as Diclofenac, can achieve high loading capacity and constant drug release. It has also been found that elevated temperatures can achieve high loading capacity and constant release. In addition, the study showed that Diclofenac release profiles were similar for sorption and dissolution loading methods.

Antibody-functionalized nano test tubes target breast cancer cells

Aim: To develop nano test tubes that will deliver a biomedical payload to a specific cell type. Methods: The template-synthesis method was used to prepare silica nano test tubes. An antibody that is specific for breast cancer cells was attached to the outer tube surfaces. A fluorophore was attached to the inner surfaces of the nano test tubes. The tubes were incubated with the breast cancer cells and the extent of attachment to the cell surfaces was investigated by fluorescence microscopy. Results: Tubes modified on their outer surfaces with the target antibody showed enhanced attachment to breast-cancer cells, relative to tubes modified on their outer surfaces with a species and isotype-matched control antibody. Conclusions: This work is a first step toward demonstrating that nano test tubes can be used as cell-specific delivery vehicles.

Development and characterization of hyaluronic acid-anchored PLGA nanoparticulate carriers of doxorubicin

A novel hyaluronic acid-poly(ethylene glycol)-poly(lactide-co-glycolide) (HA-PEG-PLGA) copolymer was synthesized and characterized by infrared and nuclear magnetic resonance spectroscopy. The nanoparticles of doxorubicin (DOX)-loaded HA-PEG-PLGA were prepared and compared with monomethoxy(polyethylene glycol) (MPEG)-PLGA nanoparticles. Nanoparticles were prepared using drug-to-polymer ratios of 1:1 to 1:3. Drug-to-polymer ratio of 1:1 is considered the optimum formulation on the basis of low particle size and high entrapment efficiency. The optimized nanoparticles were characterized for morphology, particle size measurements, differential scanning calorimetry, x-ray diffractometer measurement, drug content, hemolytic toxicity, subacute toxicity, and in vitro DOX release. The in vitro DOX release study was performed at pH 7.4 using a dialysis membrane. HA-PEG-PLGA nanoparticles were able to sustain the release for up to 15 days. The tissue distribution studies were performed with DOX-loaded HA-PEG-PLGA and MPEG-PLGA nanoparticles after intravenous (IV) injection in Ehrlich ascites tumor-bearing mice. The tissue distribution studies showed a higher concentration of DOX in the tumor as compared with MPEG-PLGA nanoparticles. The in vivo tumor inhibition study was also performed after IV injection of DOX-loaded HA-PEG-PLGA nanoparticles up to 15 days. DOX-loaded HA-PEG-PLGA nanoparticles were able to deliver a higher amount of DOX as compared with MPEG-PLGA nanoparticles. The DOX-loaded HA-PEG-PLGA nanoparticles reduced tumor volume significantly as compared with MPEG-PLGA nanoparticles.

Methoxy poly(ethylene glycol)-poly(lactide) (MPEG-PLA) nanoparticles for controlled delivery of anticancer drugs

Methoxy poly(ethylene glycol)-poly(lactide) copolymer (MPEG-PLA) was synthesized and used to make nanoparticles by the nanoprecipitation method for clinical administration of antineoplastic drugs. Paclitaxel was used as a prototype drug due to its excellent efficacy and commercially great success. The size and size distribution, surface morphology, surface charge and surface chemistry of the paclitaxel-loaded nanoparticles were then investigated by laser light scattering, atomic force microscopy, zeta-potential analyzer and X-ray photoelectron spectroscopy (XPS). The drug encapsulation efficiency (EE) and in vitro release profile were measured by high-performance liquid chromatography. The effects of various formulation parameters were evaluated. The prepared nanoparticles were found of spherical shape with size less than 100 nm. Zeta potential measurement and XPS analysis demonstrated the presence of PEG layer on the particle surface. Viscosity of the organic phase was found to be one of the main process factors for the size determination. The EE was found to be greatly influenced by the drug loading. The drug release pattern was biphasic with a fast release rate followed by a slow one. The particle suspension exhibited good steric stability in vitro. Such a nanoparticle formulation of paclitaxel can be expected to have long-circulating effects in circulation.