-
[show abstract]
[hide abstract]
ABSTRACT: Etoposide-loaded biodegradable microspheres of poly lactic-co-glycolide (PLGA) 50:50, PLGA 75:25, and polycaprolactone (PCL) were prepared by simple o/w emulsification solvent evaparation method and characterized by size analysis and microscopy. The influence of drug to polymer ratio on the entrapment of etoposide was studied. Of all the three types of microspheres, polycaprolactone microspheres (PCL MS) showed the highest entrapment efficiency (94.64%), followed by PLGA 75:25 microspheres (PLGA 75:25 MS) (88.64%) and PLGA 50:50 microspheres (PLGA 50:50 MS) (79.19%). The drug to polymer ratio of 1:20 gave the highest entrapment efficiency for all the three types of microspheres. The in vitro release of etoposide from the three microsphere formulations were studied in phosphate buffer pH 7.4 (pH 7.4 PB) containing 0.1% Tween 80. The microspheres showed an initial burst release, which was highest from the PLGA 50:50 MS and least from the PCL MS. PCL MS microspheres showed the lower and slow drug release than the remaining formulations. The release of etoposide from all the three microsphere formulations followed Higuchi's diffusion pattern. The microspheres in the dissolution medium for 28 days appeared irregular in shape and slightly fragmented.
Pharmaceutical Development and Technology 02/2007; 12(1):79-88. · 1.36 Impact Factor
-
[show abstract]
[hide abstract]
ABSTRACT: Solid lipid nanoparticles (SLN) were prepared by emulsification and high pressure homogenization technique and characterized by size analysis and differential scanning calorimetry. The influence of experimental factors such as homogenization pressure, time, and surfactant concentration on the nanoparticle size and distribution were investigated to optimize the formulation. Homogenization at 15,000 psi for 3 cycles was found to be optimum and resulted in smaller sized nanoparticles. In case of tristearin SLN (TSSLN), tripalmitin SLN (TPSLN), and glycerol behenate SLN (GBSLN), the relatively smaller sized nanoparticles were obtained with 3% sodium tauroglycocholate. The SLN were loaded with an anticancer agent, tamoxifen citrate (TC). The TC-loaded TSSLN shown lower entrapment efficiency (78.78%) compared to the TPSLN (86.75%) and GBSLN (98.64%). Short term stability studies indicated a significant increase in size of nanoparticles when stored at 500C, compared to those stored at 30 degrees C and 4 degrees C. The particle destabilization upon storage in case of all the types of nanoparticles studied was in the order of day light > artificial light > dark. An ultraviolet (UV) spectrophotometric method of estimation of tamoxifen in rat plasma was developed and validated. The TC-loaded TSSLN was administered to the rats intravenously and the pharmacokinetic parameters in the plasma were determined. The t(1/2) and mean residence time of TC-loaded TSSLN in plasma was about 3.5-fold (p < 0.001) and 3-fold (p < 0.001) higher, respectively, than the free tamoxifen, indicating the potential of TC-loaded TSSLN as a long circulating system in blood. Thus the above mentioned solid lipid nanoparticles can be a beneficial system to deliver tamoxifen to cancer tissues through enhanced permeability and retention (EPR) effect.
Pharmaceutical Development and Technology 01/2006; 11(2):167-77. · 1.36 Impact Factor
-
L Harivardhan Reddy
[show abstract]
[hide abstract]
ABSTRACT: Despite several advancements in chemotherapy, the real therapy of cancer still remains a challenge. The development of new anti-cancer drugs for the treatment of cancer has not kept pace with the progress in cancer therapy, because of the nonspecific drug distribution resulting in low tumour concentrations and systemic toxicity. The main hindrance for the distribution of anti-cancer agents to the tumour site is the highly disorganized tumour vasculature, high blood viscosity in the tumour, and high interstitial pressure within the tumour tissue. Recently, several approaches such as drug modifications and development of new carrier systems for anti-cancer agents have been attempted to enhance their tumour reach. Approaches such as drug delivery through enhanced permeability and retention (EPR) effect have resulted in a significant improvement in concentration in tumours, while approaches such as drug-carrier implants and microparticles have resulted in improvement in local chemotherapy of cancer. This review discusses different strategies employed for the delivery of anti-cancer agents to tumours, such as through EPR effect, local chemotherapeutic approaches using drug delivery systems, and special strategies such as receptor-mediated delivery, pH-based carriers, application of ultrasound and delivery to resistant tumour cells and brain using nanoparticles.
Journal of Pharmacy and Pharmacology 11/2005; 57(10):1231-42. · 2.17 Impact Factor
-
[show abstract]
[hide abstract]
ABSTRACT: The study evaluates the capability of tripalmitin nanoparticles in enhancing the tumor uptake of etoposide, and the influence of administration route on the biodistribution and tumor uptake of etoposide loaded tripalmitin (ETPL) nanoparticles in Dalton's lymphoma tumor bearing mice. ETPL nanoparticles were prepared by melt-emulsification and high pressure homogenization followed by the spray drying of nanodispersion. Characterization of the nanoparticles was done by particle size analysis, zeta potential measurement and scanning electron microscopy. The size of ETPL nanoparticles was 387 nm and possessed negative charge. Etoposide and ETPL nanoparticles were radiolabeled with 99mTc with high labeling efficiency. The labeled complexes showed good in vitro stability in the presence of DTPA/cysteine and serum stability. Etoposide and ETPL nanoparticles were injected by subcutaneous, intravenous or intraperitoneal routes and their biodistribution and tumor uptake were determined. Subcutaneous injection reduced the distribution of ETPL nanoparticles to all the tissues studied whereas after intraperitoneal injection, the distribution of ETPL nanoparticles to tissues was higher than free etoposide. The intravenous injection resulted in lower concentrations of ETPL nanoparticles in the organs of RES compared to free etoposide. ETPL nanoparticles experienced significantly high brain distribution after intraperitoneal injection indicating its potential use in targeting etoposide to brain tumors. After subcutaneous injection, the tissue distribution of ETPL nanoparticles increased with time indicating their accumulation at the injection site for a longer time. The tumor uptake of both etoposide and ETPL nanoparticles was significantly high after subcutaneous injection (P<0.001) compared to the other routes of administration. The tumor concentration of ETPL nanoparticles after subcutaneous injection was 59 folds higher than that obtained after intravenous and 8 folds higher than after intraperitoneal route at 24 h post-injection. The tumor concentration of ETPL nanoparticles increased with time after subcutaneous injection indicating the slower and progressive penetration from the injection site into the tumor. The study signifies the advantage of incorporating etoposide into tripalmitin nanoparticles in controlling its biodistribution and enhancing the tumor uptake by several folds. The study also reveals that, of the three routes investigated, subcutaneous injection is the route of preference for facilitating high tumor uptake and retention and is likely to have greater antitumor effect resulting in tumor regression.
Journal of Controlled Release 07/2005; 105(3):185-98. · 5.73 Impact Factor
-
[show abstract]
[hide abstract]
ABSTRACT: The aim of the study was to prepare etoposide-loaded nanoparticles with glyceride lipids and then characterize and evaluate the in vitro steric stability and drug release characteristics and stability. The nanoparticles were prepared by melt emulsification and homogenization followed by spray drying of nanodispersion. Spray drying created powder nanoparticles with excellent redispersibility and a minimal increase in particle size (20-40 nm). Experimental variables, such as homogenization pressure, number of homogenization cycles, and surfactant concentration, showed a profound influence on the particle size and distribution. Spray drying of Poloxamer 407-stabilized nanodispersion lead to the formation of matrix-like structures surrounding the nanoparticles, resulting in particle growth. The in vitro steric stability test revealed that the lipid nanoparticles stabilized by sodium tauroglycocholate exhibit excellent steric stability compared with Poloxamer 407. All 3 glyceride nanoparticle formulations exhibited sustained release characteristics, and the release pattern followed the Higuchi equation. The spray-dried lipid nanoparticles stored in black polypropylene containers exhibited excellent long-term stability at 25 degrees C and room light conditions. Such stable lipid nanoparticles with in vitro steric stability can be a beneficial delivery system for intravenous administration as long circulating carriers for controlled and targeted drug delivery.
AAPS PharmSciTech 02/2005; 6(2):E158-66. · 1.43 Impact Factor
-
[show abstract]
[hide abstract]
ABSTRACT: The aim of the study is to determine and compare the pharmacokinetics and tissue distribution of Doxorubicin (Dox) delivered as solution or through nanoparticles after intravenous (i.v.) and intraperitoneal (i.p.) injection. Doxorubicin loaded poly(butyl cyanoacrylate) nanoparticles were synthesized by dispersion polymerization (DP) and emulsion polymerization (EP) techniques. The drug loaded DP and EP nanoparticles were administered by i.v. or i.p. routes and the respective pharmacokinetics and tissue distribution were determined. Both types of nanoparticles significantly enhanced the elimination half-life (T(1/2)), mean residence time (MRT) AUC(0-8), AUC(0-infinity) and AUMC(0-8) of Dox in blood after i.v. injection. Dox delivered through DP nanoparticles rapidly disappeared from blood and distributed to the organs of reticuloendothelial system (RES). But, the clearance of Dox delivered through EP nanoparticles from blood was slower than this of the DP nanoparticles and Dox solution. After i.p. injection, the Dox loaded into DP nanoparticles quickly appeared in blood and undergone rapid distribution to the organs of RES, while the Dox loaded into EP nanoparticles absorbed slowly into blood and remained in the circulation for longer time. The absorption into blood of Dox delivered through DP and EP nanoparticles after i.p. injection was relatively rapid and higher than Dox solution. The T(1/2), MRT, AUC(0-8), AUC(0-infinity) and AUMC(0-8) of Dox in blood were significantly higher and the clearance (Cl) was lower than for the Dox solution after i.p. injection. The tissue concentrations of Dox delivered through nanoparticles after i.p. injection were significantly lower than after i.v. injection. The bioavailability (F) of Dox was greatly enhanced by DP (approximately 1.9 fold) and EP nanoparticles (approximately 2.12 fold) compared to Dox solution after i.p. injection. EP nanoparticles significantly enhanced the bioavailability, MRT, T(1/2), AUC(0-8), AUC(0-infinity) and AUMC(0-8) of Dox than DP nanoparticles. This signifies the advantage of EP nanoparticles in increasing the elimination half-life of Dox both after i.v. and i.p. injection and enhanced bioavailability after i.p. injection, which is expected to improve the therapeutic efficacy of Dox and reduce the Dox-associated systemic toxicity. Importantly, both DP and EP nanoparticles greatly reduced the distribution of Dox to heart both after i.v. and i.p. injection, suggesting their potential in reducing Dox-associated cardiotoxicity.
Biomedical papers of the Medical Faculty of the University Palacky, Olomouc, Czechoslovakia 01/2005; 148(2):161-6.
-
[show abstract]
[hide abstract]
ABSTRACT: The emulsion copolymerization of a partially water-soluble monomer, methyl methacrylate (MMA), and a water-soluble polymerizable cosurfactant, hydroxyethyl methacrylate (HEMA), was investigated. The microstructure of the copolymer varied as the HEMA concentration increased. The copolymer microstructure influenced drug entrapment and was studied with respect to the variation in the MMA/HEMA ratio, the crosslinker concentration, and the method of nanoparticle separation from the dispersion. The subsequent release of a lipophilic drug, carbamazepine, from nanoparticles was studied at three different copolymer compositions. © 2004 Wiley Periodicals, Inc. J Appl Polym Sci 92: 402–409, 2004
Journal of Applied Polymer Science 02/2004; 92(1):402 - 409. · 1.29 Impact Factor
-
[show abstract]
[hide abstract]
ABSTRACT: The objective of this study is to enhance the delivery of Doxorubicin hydrochloride to Dalton's lymphoma solid tumour through poly(butyl cyanoacrylate) (PBC) nanoparticles. Doxorubicin loaded PBC (DPBC) nanoparticles were prepared by emulsion polymerization and characterized by particle size analysis, zeta potential and scanning electron microscopy. Doxorubicin HCl (Dox) and DPBC nanoparticles were radiolabeled with 99mTc by reduction method using stannous chloride and optimized the labeling parameters to obtain high labeling efficiency. The in vitro stability of 99mTc-labeled complexes was determined by DTPA and cysteine challenge test. The labeled complexes showed very low transchelation and high in vitro and serum stability. 99mTc labeled complexes of Dox and DPBC nanoparticles were administered subcutaneously below the Dalton's lymphoma tumour and biodistribution was studied. The distribution of DPBC nanoparticles to the blood, heart and organs of RES such as liver, lung and spleen was biphasic with a rapid initial distribution, followed by a significant decrease later at 6 h post-injection. The distribution of Dox to tissues was very low initially and increased significantly at 6 h post-injection indicating its accumulation at the injection site for a longer time. The concentration of DPBC nanoparticles was also found high in tissues at 6 h post-injection indicating their accumulation at the subcutaneous site and consequent disposition to tissues with time. A significantly high tumour uptake of DPBC nanoparticles (approximately 13 fold higher at 48 h post-injection) (P <0.001) was found compared to free Dox. The tumour concentrations of both Dox and DPBC nanoparticles increased with time indicating their slow penetration from the injection site into tumour. The concentration of DPBC nanoparticles in the femur bone in the tumour region was also significantly higher (P <0.001) than free Dox and increased with time. The study signifies the advantage of delivering Dox to Dalton's lymphoma through PBC nanoparticles by facilitating enhanced tumour uptake and prolonged tumour retention, which are expected to lead to greater therapeutic effect in the form of tumour regression.
Journal of Drug Targeting 02/2004; 12(7):443-51. · 2.70 Impact Factor
-
[show abstract]
[hide abstract]
ABSTRACT: The objective of the present work is to study the biodistribution and tumor retention properties of etoposide (anticancer agent) and etoposide loaded tripalmitin nanoparticles (ETPL) after intratumoral administration in Dalton's lymphoma tumor bearing mice. ETPL nanoparticles were prepared by melt-emulsification and high pressure homogenization followed by spray drying technique. The nanoparticles were uniform and possessed 387 nm mean diameter and negative charge with excellent redispersibility in aqueous media. Radiolabeling of etoposide and ETPL nanoparticles with Technetium-99m (99mTc) resulted in complexes with high labeling efficiency and low radiocolloid formation. The labeled complexes showed good in vitro stability as indicated by low transchelation in presence of DTPA and cysteine and stability in human serum. Biodistribution and tumor retention studies were performed for etoposide and ETPL nanoparticles after intratumoral injection in mice bearing Dalton's lymphoma tumor. Etoposide experienced rapid clearance from the tumor, while the disposition of ETPL nanoparticles was slower. The tissue concentrations of ETPL nanoparticles increased with time (i.e. at 6h and 24h post injection) indicating its retention in tumor site for a longer time. Tumor retention of both etoposide and ETPL nanoparticles was studied upto 48h post injection. The tumor concentration of both etoposide and ETPL nanoparticles was high initially (8.57% and 41.8% injected dose at 0.5h post injection) and decreased with time (0.12%and 1.68% injected dose at 48h post injection). The concentration of etoposide rapidly declined from the tumor site while the tumor retention of ETPL nanoparticles was significantly higher than free etoposide (P < 0.001) at all the time points studied. The over all many fold higher tumor retention of ETPL nanoparticles (14 folds even at 48h post injection) compared to etoposide, coupled with lower tissue distribution signifies the advantage of tripalmitin nanoparticles as drug carrier for etoposide in enhancing the antitumor effect and reducing the etoposide associated systemic toxicity.
Alasbimn Journal. 01/2004;
-
[show abstract]
[hide abstract]
ABSTRACT: The study evaluates the capability of tripalmitin nanoparticles in enhancing the tumor uptake of etoposide, and the influence of administration route on the biodistribution and tumor uptake of etoposide loaded tripalmitin (ETPL) nanoparticles in Dalton's lymphoma tumor bearing mice. ETPL nanoparticles were prepared by melt-emulsification and high pressure homogenization followed by the spray drying of nanodispersion. Characterization of the nanoparticles was done by particle size analysis, zeta potential measurement and scanning electron microscopy. The size of ETPL nanoparticles was 387 nm and possessed negative charge. Etoposide and ETPL nanoparticles were radiolabeled with 99mTc with high labeling efficiency. The labeled complexes showed good in vitro stability in the presence of DTPA/cysteine and serum stability. Etoposide and ETPL nanoparticles were injected by subcutaneous, intravenous or intraperitoneal routes and their biodistribution and tumor uptake were determined. Subcutaneous injection reduced the distribution of ETPL nanoparticles to all the tissues studied whereas after intraperitoneal injection, the distribution of ETPL nanoparticles to tissues was higher than free etoposide. The intravenous injection resulted in lower concentrations of ETPL nanoparticles in the organs of RES compared to free etoposide. ETPL nanoparticles experienced significantly high brain distribution after intraperitoneal injection indicating its potential use in targeting etoposide to brain tumors. After subcutaneous injection, the tissue distribution of ETPL nanoparticles increased with time indicating their accumulation at the injection site for a longer time. The tumor uptake of both etoposide and ETPL nanoparticles was significantly high after subcutaneous injection (P < 0.001) compared to the other routes of administration. The tumor concentration of ETPL nanoparticles after subcutaneous injection was 59 folds higher than that obtained after intravenous and 8 folds higher than after intraperitoneal route at 24 h post-injection. The tumor concentration of ETPL nanoparticles increased with time after subcutaneous injection indicating the slower and progressive penetration from the injection site into the tumor. The study signifies the advantage of incorporating etoposide into tripalmitin nanoparticles in controlling its biodistribution and enhancing the tumor uptake by several folds. The study also reveals that, of the three routes investigated, subcutaneous injection is the route of preference for facilitating high tumor uptake and retention and is likely to have greater antitumor effect resulting in tumor regression.
Journal of Controlled Release.
