Long circulating PEGylated PLGA nanoparticles of cytarabine for targeting leukemia

The present investigation was aimed at developing PEGylated PLGA nanoparticles of cytarabine. PLGA Nanoparticles were prepared by modified nanoprecipitation method, optimized for mean particle size (152?±?6?nm) and entrapment efficiency (41.1?±?0.8%) by a 32 factorial design. The PEGylated PLGA nanoparticles of cytarabine had a zeta potential of -7.5?±?1.3?mV and sustained the release of cytarabine for 48?h by Fickian diffusion. The IC?? values for L1210 cells were 6.5, 5.3, and 2.2 μM for cytarabine, cytarabine loaded PLGA nanoparticles and cytarabine loaded PLGA-mPEG nanoparticles respectively. Confocal microscopy and flow cytometry showed that the nanoparticles were internalized by the L1210 cells and not simply bound to their surface. Biodistribution studies showed that the PEGylated nanoparticles of cytarabine were present in significantly higher concentrations in blood circulation as well as in brain and bones and avoided RES uptake as compared to the free drug.     

Formulation,characterization and evaluation of cyclodextrin-complexed bendamustine-encapsulated PLGA nanospheres for sustained delivery in cancer treatment

PLGA nanospheres are considered to be promising drug carrier in the treatment of cancer. Inclusion complex of bendamustine (BM) with epichlorohydrin beta cyclodextrin polymer was prepared by freeze-drying method. Phase solubility study revealed formation of A_L type complex with stability constant (Ks?=?645?M^?1). This inclusion complex was encapsulated into PLGA nanospheres using solid-in-oil-in-water (S/O/W) technique. The particle size and zeta potential of PLGA nanospheres loaded with cyclodextrin-complexed BM were about 151.4?±?2.53?nm and???31.9?±?(?3.08)?mV. In-vitro release study represented biphasic release pattern with 20% burst effect and sustained slow release. DSC studies indicated that inclusion complex incorporated in PLGA nanospheres was not in a crystalline state but existed in an amorphous or molecular state. The cytotoxicity experiment was studied in Z-138 cells and IC₅₀ value was found to be 4.3?±?0.11?µM. Cell viability studies revealed that the PLGA nanospheres loaded with complex exerts a more pronounced effect on the cancer cells as compared to the free drug. In conclusion, PLGA nanospheres loaded with inclusion complex of BM led to sustained drug delivery. The nanospheres were stable after 3 months of storage conditions with slight change in their particle size, zeta potential and entrapment efficiency.     

Amphotericin B-loaded polymeric nanoparticles: formulation optimization by factorial design

In this study, PLGA or PLGA-PEG blend nanoparticles were developed loading amphotericin B (AmB), an antifungal agent broadly used in therapy. A 2²?×?3¹ factorial experimental design was conducted to indicate an optimal formulation of nanoparticles containing AmB and demonstrate the influence of the interactions of components on the mean particle size and drug encapsulation efficiency. The independent variables analyzed were polymer amount (two levels) and organic phase (three factors in one level). The parameters methanol as cosolvent and higher polymer amount originated from the higher AmB encapsulation, but with the larger particle size. The selected optimized parameters were set as the lower polymer amount and ethyl acetate as cosolvent in organic phase, for both PLGA and PLGA-PEG nanoparticles. These parameters originated from nanoparticles with the size of 189.5?±?90?nm and 169?±?6.9?nm and AmB encapsulation efficiency of 94.0?±?1.3% and 92.8?±?2.9% for PLGA and PLGA-PEG nanoparticles, respectively. Additionally, these formulations showed a narrow size distribution indicating homogeneity in the particle size. PLGA and PLGA-PEG nanoparticles are potential carrier for AmB delivery and the factorial design presented an important tool in optimizing nanoparticles formulations.     

Preparation,Physicochemical Characterization and Anti-fungal Evaluation of Nystatin-Loaded PLGA-Glucosamine Nanoparticles

Purpose

Nystatin loaded PLGA and PLGA-Glucosamine nanoparticles were formulated. PLGA were functionalized with Glucosamine (PLGA-GlcN) to enhance the adhesion of nanoparticles to Candida Albicans (C.albicans) cell walls.

Method

Quasi-emulsion solvent diffusion method was employed using PLGA and PLGA-GlcN with various drug–polymer ratios for the preparation of nanoparticles. The nanoparticles were evaluated for size, zeta potential, polydispersity index, drug crystallinity, loading efficiency and release properties. DSC, SEM, XRPD, ¹H-NMR, and FT-IR were performed to analyze the physicochemical properties of the nanoparticles. Antifungal activity of the nanoparticles was evaluated by determination of MICs against C.albicans.

Results

The spectra of ¹H-NMR and FT-IR analysis ensured GlcN functionalization on PLGA nanoparticles. SEM characterization confirmed that particles were in the nanosize range and the particle size for PLGA and PLGA-GlcN nanoparticles were in the range of 108.63?±?4.5 to 168.8?±?5.65 nm and 208.76?±?16.85 nm, respectively. DSC and XRPD analysis ensured reduction of the drug crystallinity in the nanoparticles. PLGA-GlcN nanoparticles exhibit higher antifungal activity than PLGA nanoparticles.

Conclusion

PLGA-GlcN nanoparticles showed more antifungal activity with appropriate physicochemical properties than pure Nystatin and PLGA nanoparticles.

     

In vitro schistosomicidal activity of the lignan (−)-6,6′-dinitrohinokinin (DNHK) loaded into poly(lactic-co-glycolic acid) nanoparticles against Schistosoma mansoni

Context: (?)-6,6′-Dinitrohinokinin (DNHK) display remarkable antiparasitic activity and was, therefore, incorporated into a nanoparticle formulation.

Objective: Incorporation of DNHK in poly lactic-co-glycolic acid (PLGA) nanoparticles aiming to improve its biological activities.

Materials and methods: Synthesis, characterization and incorporation of DNHK into glycolic acid (PLGA) nanoparticles by nanoprecipitation method. The nanoparticles were characterized by ultraviolet-visible spectroscopy, X-ray diffraction, field emission electron microscopic scanning mansoni (FESEM), and dynamic light scattering (DLS). For the in vitro test with Schistosoma mansoni, the DNHK-loaded PLGA was diluted into the medium, and added at concentrations 10–200?µM to the culture medium containing one adult worm pair. The parasites were kept for 120?h and monitored every 24?h to evaluate their general condition, including: pairing, alterations in motor activity and mortality.

Results: The loaded PLGA nanoparticles gave an encapsulation efficiency of 42.2% and showed spherical characteristics in monodisperse polymeric matrix. The adult worm pairs were separated after 120?h of incubation for concentrations higher than 50?µM of DNHK-loaded PLGA. The groups incubated with 150 and 200?µM of DNHK-loaded PLGA for 24 and 120?h killed 100% of adult worms, afforded LC₅₀ values of 137.0?±?2.12?µM and 79.01?±?1.90?µM, respectively, which was similar to the effect displayed by 10?µM of praziquantel.

Discussion and conclusions: The incorporation of DNHK-loaded showed schistosomicidal activity and allowed its sustained release. The loaded PLGA system can be administered intravenously, as well as it may be internalized by endocytosis by the target organisms.     

Long circulating nanoparticles of etoposide using PLGA‐MPEG and PLGA‐pluronic block copolymers: characterization,drug‐release,blood‐clearance,and biodistribution studies

The anti‐leukemic drug, etoposide (ETO), has variable oral bioavailability ranging from 24–74% with a short terminal half‐life of 1.5 h i.v. necessitating continuous infusion for 24–34 h for the treatment of leukemia. In the present study, etoposide‐loaded PLGA‐based surface‐modified nanoparticles (NPs) with long circulation were designed as an alternative to continuous i.v. administration. PLGA‐mPEG and PLGA‐PLURONIC copolymers were synthesised and used to prepared ETO‐loaded NPs by high‐pressure homogenization. The mean particle size of ETO‐loaded PLGA‐MPEG nanoparticles was 94.02±3.4 nm, with an Entrapment Efficiency (EE) of 71.2% and zeta potential value of −6.9±1.3 mV. ETO‐loaded PLGA‐pluronic nanoparticles had a mean particle size of 148.0±2.1 nm, an EE of 73.12±2.7%, and zeta potential value of −21.5±1.6 mV. In vitro release of the pure drug was complete within 4 h, but was sustained up to 7 days from PLGA‐mPEG nanoparticles and for 5 days from PLGA‐pluronic nanoparticles. Release was first order and followed non‐Fickian diffusion kinetics in both instances. ETO and ETO‐loaded PLGA nanoparticles labeled with ^99mTc were used in blood clearance studies in rats where the two coated NPs, ^99mTc‐ ETO‐PLGA‐PLU NP and ^99mTc‐ ETO‐PLGA‐mPEG NP, were found to be available in higher concentrations in the circulation as compared to the pure drug. Biodistribution studies in mice showed that ETO‐loaded PLGA‐MPEG NP and PLGA‐PLURONIC NP had reduced uptake by the RES due to their steric barrier properties and were present in the circulation for a longer time. Moreover, the NPs had greater uptake in bone and brain where concentration of the free drug, ETO, was negligible. Drug delivered from these NPs could result in a single i.v. injection that would release the drug for a number of days, which would be potentially beneficial and in better control of leukemia therapy. Drug Dev Res 71: 228–239, 2010. © 2010 Wiley‐Liss, Inc.     

Triamcinolone acetonide nanoparticles incorporated in thermoreversible gels for age-related macular degeneration

Age-related macular degeneration (AMD) is one of the leading causes of blindness in the US affecting millions yearly. It is characterized by intraocular neovascularization, inflammation and retinal damage which can be ameliorated through intraocular injections of glucocorticoids. However, the complications that arise from repetitive injections as well as the difficulty posed by targeting the posterior segment of the eye make this interesting territory for the development of novel drug delivery systems (DDS). In the present study, we described the development of a DDS composed of triamcinolone acetonide-encapsulated PEGylated PLGA nanoparticles (NP) incorporated into PLGA–PEG–PLGA thermoreversible gel and its use against VEGF expression characteristic of AMD. We found that the NP with mean size of 208?±?1.0?nm showed uniform size distribution and exhibited sustained release of the drug. We also demonstrated that the polymer can be injected as a solution and transition to a gel phase based on the biological temperature of the eye. Additionally, the proposed DDS was non-cytotoxic to ARPE-19 cells and significantly reduced VEGF expression by 43.5?±?3.9% as compared to a 1.53?±?11.1% reduction with triamcinolone. These results suggest the proposed DDS will contribute to the development of novel therapeutic strategies for AMD.     

Improved bioavailability of orally delivered insulin using Eudragit-L30D coated PLGA microparticles

Large porous microparticles of PLGA entrapping insulin were prepared by solvent evaporation method and evaluated in diabetes induced rat for its efficacy in maintaining blood sugar level from a single oral dose. Incorporation of Eudragit L30D (0.03% w/v) in the external aqueous phase resulted in formation of pH responsive enteric coated polymer particles which release most of the entrapped insulin in alkaline pH. At acidic pH, release of insulin from uncoated PLGA microparticles and Eudragit L30D coated PLGA microparticles was 31.62?±?1.8% and 17.5?±?1.29%, respectively, for initial 30 min. However, in 24 h, in vitro released insulin from uncoated PLGA and Eudragit coated particles was 96.29?±?1.01% and 88.30?±?1%, respectively. Released insulin from composite polymer particles were mostly in monomer form without aggregation and was stable for a month at 37°C. Oral administration of insulin loaded PLGA (50 : 50) and Eudragit L30D coated PLGA (50 : 50) microparticles (equivalent to 25 IU insulin/kg of animal weight) in alloxan induced diabetic rats resulted in 37.3?±?11% and 62.7?±?3.8% reduction in blood glucose level, respectively, in 2 h. This effect continued up to 24 h in the case of Eudragit L30D coated PLGA microparticles. Results demonstrate that use of stabilizers during PLGA particle formulation, large porous particle for quick release of insulin and coating with Eudragit L30D resulted in a novel oral formulation for once a day delivery of insulin.     

Cyclodextrin-based nanosponges: effective nanocarrier for Tamoxifen delivery

The purpose of the present study was to develop Tamoxifen loaded β-cyclodextrin nanosponges for oral drug delivery. The three types of Tamoxifen loaded β-cyclodextrin nanosponges were synthesized by varying the molar ratios of β-cyclodextrin to carbonyldiimidazole as a crosslinker viz. 1:2, 1:4 and 1:8. The Tamoxifen nanosponge complex (TNC) with particle size of 400–600?nm was obtained by freeze drying method. Differential scanning calorimetry, Fourier transformed infra-red spectroscopy and X-ray powder diffraction studies confirmed the complexation of Tamoxifen with cyclodextrin nanosponge. AUC and C_max of TNC formulation (1236.4?±?16.12 µg·mL^?1 h, 421.156?±?0.91 µg/mL) after gastric intubation were 1.44 fold and 1.38 fold higher than plain drug (856.079?±?15.18 µg·mL^?1 h, 298.532?±?1.15 µg/mL). Cytotoxic studies on MCF-7 cells showed that TNC formulation was more cytotoxic than plain Tamoxifen after 24 and 48?h of incubation.     

Pharmacokinetics and tissue distribution studies of orally administered nanoparticles encapsulated ethionamide used as potential drug delivery system in management of multi-drug resistant tuberculosis

Sustained release nanoformulations of second line anti-tubercular drugs can help in reducing their dosing frequency and improve patient’s compliance in multi-drug resistant tuberculosis (MDR TB). The objective of the current study was to investigate the pharmacokinetics and tissues distribution of ethionamide encapsulated in poly (DL-lactide-co-glycolide) (PLGA) nanoparticles. The drug loaded nanoparticles were 286 ± 26?nm in size with narrow size distribution, and zeta-potential was ?13 ± 2.5 mV. The drug encapsulation efficiency and loading capacity were 35.2 ± 3.1%w/w and 38.6 ± 2.3%w/w, respectively. Ethionamide-loaded nanoparticles were administered orally to mice at two different doses and the control group received free (unencapsulated) ethionamide. Ethionamide-loaded PLGA nanoparticles produced sustained release of ethionamide for 6 days in plasma against 6?h for free ethionamide. The Ethionamide was detected in organs (lung, liver, and spleen) for up to 5–7 days in the case of encapsulated ethionamide, whereas free ethionamide was cleared within 12?h. Ethionamide-loaded PLGA nanoparticles exhibited significant improvement in pharmacokinetic parameters, i.e. C_max, t_max, AUC_0–∞, AUMC_0–∞, and MRT of encapsulated ethionamide as compared with free ethionamide. Drug in nanoparticles also exhibited a dose proportional increase in the AUC_0–∞ values. The pharmacodynamic parameters such as AUC_0–24/MIC, C_max/MIC, and Time > MIC were also improved. PLGA nanoparticles of ethionamide have great potential in reducing dosing frequency of ethionamide in treatment of MDR TB.     

Targeted delivery of monoclonal antibody conjugated docetaxel loaded PLGA nanoparticles into EGFR overexpressed lung tumour cells

The aim of this study was to develop anti-EGFR antibody conjugated poly(lactide-co-glycolide) nanoparticles (NPs) to target epidermal growth factor receptor, highly expressed on non-small cell lung cancer cells to improve cytotoxicity and site specificity. Cetuximab was conjugated to docetaxel (DTX) loaded PLGA NPs by known EDC/NHS chemistry and characterised for size, zeta potential, conjugation efficiency and the results were 128.4?±?3.6?nm, –31.0?±?0.8?mV, and 39.77?±?3.4%, respectively. In vitro release study demonstrated sustained release of drug from NPs with 25% release at pH 5.5 after 48?h. In vitro cytotoxicity studies demonstrated higher anti-proliferative activity of NPs than unconjugated NPs. Cell cycle analysis and apoptosis study were performed to evaluate extent of cell arrest at different phases and apoptotic potential for the formulations, respectively. In vivo efficacy study showed significant reduction in tumour growth and so antibody conjugated NPs present a promising active targeting carrier for tumour selective therapeutic treatment.     

The anti-tumor effect of folate-targeted liposome microbubbles loaded with oridonin as ultrasound-triggered tumor-targeted therapeutic carrier system

In this study, folate receptor (FR) targeted liposome microbubbles loaded with oridonin (ORI) (F-LMB-ORI), liposome loaded with ORI (L-ORI) and liposome microbubbles loaded with ORI (LMB-ORI) were prepared. In vitro release properties, cellular uptake and cytotoxicity in HepG-2 cells as well as in vivo antitumor effects in HepG-2 cells tumor-bearing mice of F-LMB-ORI, L-ORI and LMB-ORI were evaluated upon ultrasound exposure. Results showed cytotoxicity assay on F-LMB-ORI gave IC₅₀ of 0.508?±?0.018?µmol/mL on HepG-2 cells and LMB-ORI; L-ORI gave IC₅₀ of 2.424?±?0.116?µmol/mL, 3.031?±?0.122?µmol/mL in vitro, respectively. These drug delivery carriers were able to control the release of ORI. F-LMB-ORI exhibited higher binding to HepG-2 cells in comparison to LMB-ORI and L-ORI. F-LMB-ORI improved antitumor activity of ORI obviously in comparison to L-ORI, LMB-ORI under in vivo ultrasound. After the treatment for 14 d, the tumor inhibition ratio for F-LMB-ORI (the dose of ORI: 1.5?×?10^?2?g·kg^?1, once a day) was 87.6%, obviously higher than that of LMB-ORI group, L-ORI group and free ORI (the dose of ORI: 1.5?×?10^?2?g·kg^?1, once a day) which were 71.5%, 64.3% and 43.4%, respectively.     

5-Fluorouracil-loaded microspheres prepared by spray-drying poly(D,L-lactide) and poly(lactide-co-glycolide) polymers: Characterization and drug release

5-Fluorouracil (5-FU), a hydrosoluble anti-neoplastic drug, was encapsulated in microspheres of poly(D,L-lactide) (PLA) and poly(lactide-co-glycolide) (PLGA) polymers using the spray-drying technique, in order to obtain small size microspheres with a significant drug entrapment efficiency. Drug-loaded microspheres included between 47?±?11 and 67?±?12?µg 5-FU?mg^?1 microspheres and the percentage of entrapment efficiency was between 52?±?12 and 74?±?13. Microspheres were of small size (average diameter: 0.9?±?0.4–1.4?±?0.8?µm microspheres without drug; 1.1?±?0.5–1.7?±?0.9?µm 5-FU-loaded microspheres) and their surface was smooth and slightly porous, some hollows or deformations were observed in microspheres prepared from polymers with larger T_g. A fractionation process of the raw polymer during the formation of microspheres was observed as an increase of the average molecular weight and also of T_g of the polymer of the microspheres. The presence of 5-FU did not modify the T_g values of the microspheres. Significant interactions between the drug and each one of the polymers did not take place and total release of the included drug was observed in all cases. The time needed for the total drug release (28–129?h) was in the order PLA?>?PLGA 75/25?>?PLGA 50/50. A burst effect (17–20%) was observed during the first hour and then a period of constant release rate (3.52?±?0.82–1.46?±?0.26?µg 5-FU?h^?1 per milligram of microspheres) up to 8 or 13?h, depending on the polymer, was obtained.     

Characterisation,cytotoxicity and apoptosis studies of methotrexate-loaded PLGA and PLGA-PEG nanoparticles

Abstract

Methotrexate (MTX) widely used in the treatments of various types of malignancies, but high toxicity and short plasma half-life have limited its use. This study was aimed at developing a polymeric drug delivery system for improving the therapeutic index of this potent drug. To achieve these goals, PLGA and PLGA-PEG nanoparticles were prepared using the emulsification-solvent diffusion technique and were optimized for particle size and entrapment efficiency. The optimum loaded nanoparticles were evaluated by cytotoxicity and their ability to induce apoptosis compared to free drug by examining of caspase-3 activity. The results showed that optimized particles were 182?±?14?nm and 258?±?10?nm in size for PLGA-PEG and PLGA nanoparticles, respectively, with an entrapment efficiency of more than 51%. The cytotoxicity experiment showed that the nanoparticles were more effective than pure MTX and increase the activity of caspase-3 in MCF7 and AGS and A549 cell lines.     

Encapsulation of low lipophilic and slightly water-soluble dihydroartemisinin in PLGA nanoparticles with phospholipid to enhance encapsulation efficiency and in vitro bioactivity

Context: PLGA nanoparticles have been widely utilised to encapsulate lipophilic drugs for sustained release.

Objective: This study was to enhance encapsulation efficiency and drug loading for the poorly lipophilic drug dihydroartemisinin (DHA) in PLGA nanoparticles, where amphiphilic phospholipid was employed as the intermediate. Materials and methods: DHA-phospholipid complex formulation was optimised using the response surface method. DHA-phospholipid complex-nanoparticles (DHA-PLC-NPs) were prepared using the solvent evaporation method. Results: The particle size, zeta potential, entrapment efficiency and drug loading of the nanoparticles were 265.3?±?7.9?nm, ?21.4?±?6.3?mV, 74.2?±?6.5% and 2.80?±?0.35%, respectively. Compared with the rapidly released free form, DHA underwent sustained release from the nanoparticles. DHA-PLC-NPs presented stronger cell proliferative inhibition than DHA treatment alone and apoptosis was obviously induced after DHA-PLC-NPs treatment. Conclusion: Phospholipid complexes are useful intermediate to improve the lipophilicity of drugs, the interaction with the hydrophobic core of PLGA and the encapsulation efficiency of poorly lipophilic drugs in polymeric nanoparticles.     

Intracellular drug delivery in Leishmania-infected macrophages: Evaluation of saponin-loaded PLGA nanoparticles

Drug delivery systems present an opportunity to potentiate the therapeutic effect of antileishmanial drugs. Colloidal carriers are rapidly cleared by the phagocytic cells of the reticuloendothelial system (RES), rendering them ideal vehicles for passive targeting of antileishmanials. This paper describes the development of poly(D,L-lactide-co-glycolide) (PLGA) nanoparticles (NPs) for the antileishmanial saponin β-aescin. NPs were prepared using the combined emulsification solvent evaporation/salting-out technique. Confocal microscopy was used to visualise the internalisation and intracellular trafficking of fluorescein- and nile red-labelled PLGA NPs in J774A.1 macrophages infected with GFP-transfected Leishmania donovani. The in vitro activity of aescin and aescin-loaded NPs on L. infantum was determined in the axenic model as well as in the ex vivo model. The developed PLGA NPs were monodispersed with Z_ave<300?nm, exhibited negative zeta potentials and had relatively high drug loadings ranging from 5.80 to 8.68% w/w PLGA. The fluorescent NPs were internalised by the macrophages and trafficked towards the lysosomes after 2?h in vitro incubation. Co-localisation of the NPs and the parasite was not shown. A two-fold increase in activity was observed in the ex vivo macrophage model by encapsulating β-aescin in PLGA NPs (IC₅₀, 0.48–0.76 µg/mL vs. 1.55?±?0.32 µg/mL for the free drug).     

Drug release from core-shell type nanoparticles of poly(DL-lactide-co-glycolide)-grafted dextran

This study prepared core-shell type nanoparticles of a poly(DL-lactide-co-glycolide) (PLGA) grafted-dextran. The synthesis of the PLGA-dextran conjugate was confirmed by Fourier transform-infrared (FT-IR) spectroscopy. The PLGA grafted-dextran was able to form nanoparticles in water by self-assembly and their particle size was 245.3?±?95.1?nm. From fluorescence probe study using pyrene as a hydrophobic probe, critical association concentration (CAC) values were determined from the fluorescence excitation spectra and were found to be 0.006?g?l^?1. Morphological observations using a scanning electron microscope (SEM) showed that the polymeric nanoparticles of the PLGA-dextran conjugate have uniformly spherical shapes. Their size and morphology provide them with acceptable properties for use as a drug-targeting carriers. Drug release from core-shell type nanoparticles was faster in the presence of dextranase, indicating that core-shell type nanoparticles of PLGA grafted-dextran can be used as an oral drug carriers.     

Targeted delivery of 5-fluorouracil to HT-29 cells using high efficient folic acid-conjugated nanoparticles

Abstract

The incorporation of a high percentage of targeting molecules into drug delivery system is one of the important methods for improving efficacy of targeting therapeutic drugs to cancer cells. PLGA-based drug delivery carriers with folic acid (FA) as targeting molecule have a low targeting efficiency due to a low FA conjugation ratio. In this work, we fabricated a FA-conjugated PLGA system using a crosslinker 1, 3-diaminopropane and have achieved a high conjugation ratio of 46.7% (mol/mol). The as-prepared PLGA-based biomaterial was used to encapsulate therapeutic drug 5-fluorouracil (5-FU) into nanoparticles. In the in vitro experiments, an IC₅₀ of 5.69?µg/mL has been achieved for 5-FU loaded PLGA-1, 3-diaminopropane-folic acid nanoparticles on HT-29 cancer cells and is significantly lower than that of 5-FU and 5-FU loaded PLGA nanoparticles which only have an IC₅₀ of 22.9 and 14.17?µg/mL, respectively. The fluorescent microscopy images showed that nanoparticles with FA are largely taken up by HT-29 cancer cells and the targeting nanoparticles have more affinity to cancer cells than the pure drugs and untreated nanoparticles. Therefore, the 1, 3-diaminopropane can facilitate the conjugation of FA to PLGA to form a novel polymer and 5-FU loaded PLGA-1, 3-diaminopropane-folic acid nanoparticles can be a highly efficient system for specific delivery of drugs to cancer cells.     

Preparation,characterization, photocytotoxicity assay of PLGA nanoparticles containing zinc (II) phthalocyanine for photodynamic therapy use

Nanoparticles containing Zinc (II) Phthalocyanine (ZnPc) were prepared by a spontaneous emulsification diffusion method utilizing poly-(D,L lactic-co-glycolic acid) (PLGA), characterized and available in cellular culture. The process yield and encapsulation efficiency were 60% and 80%, respectively. The nanoparticles have a mean diameter of 200?nm, a narrow size distribution with polydispersive index of 0.15, smooth surface and spherical shape. ZnPc loaded nanoparticles maintain their photophysical behaviour after the encapsulation process. Photosensitizer released from nanoparticles was sustained with a burst effect of 10% for 3 days. The photocytotoxicity was evaluated on P388-D1 cells. They were incubated with ZnPc loaded Np by 6?h and exposed to light (675?nm) for 120?s, and light dose of 30?J?cm^?2. After 24?h of incubation, the cellular viability was determined, obtaining 60% of cellular death. All the physical-chemical and photobiological measurements performed allowed one conclude that ZnPc loaded PLGA nanoparticles are a promising drug delivery system for PDT.     

Intranasal delivery of tapentadol hydrochloride–loaded chitosan nanoparticles: formulation,characterisation and its in vivo evaluation

The aim of the present investigation was to formulate tapentadol hydrochloride–loaded chitosan nanoparticles (CS-NPs) for nose to brain delivery. Chitosan nanoparticles were prepared using ionotropic gelation technique. Optimisation of the formulation and process parameters was done using Box–Behnken Design. The entrapment efficiency, drug loading, Z-average size and zeta potential of the optimised batch were 63.49?±?1.61%, 17.25?±?1.38%w/w, 201.2?±?1.5?nm and +49.3?mV, respectively. In-vitro release study showed 84.04?±?1.53% drug release after 28?h, while ex vivo studies indicated higher permeation of CS-NPs through nasal mucosa. The nanoparticles exhibited good mucoadhesiveness, haemocompatibility and safety as evidenced by histopathology. The results of the pharmacodynamic study revealed prolongation of the analgesic activity. The intranasal instillation of CS-NPs resulted in the higher concentrations in brain compared to the drug solution and intravenous administration of CS-NPs. In a nutshell, intranasal administration of tapentadol hydrochloride–loaded CS-NPs is a promising approach for effective pain management.