Effect of Low Molecular Weight Chitosans on Drug Permeation through Mouse Skin: 1. Transdermal Delivery of Baicalin

The aim of this work was to evaluate the low molecular weight chitosans (LMWCs) as enhancers of transdermal administration of baicalin, an useful drug for the treatment of atopic dermatitis, viral hepatitis, and HIV infection. Permeation experiments were performed in vitro through mouse skin by using Franz cells. Improved baicalin skin penetration was obtained with the addition of LMWCs or D-glucosamine (β-D-GlcNH₂) to the donor solutions. Chitosan molecular weight, degree of deacetylation, pH of donor baicalin solutions, and enhancer concentration all affected LMWC enhancement effects. Significant enhancement was observed at pH 7.0 or 7.5 for CS80-1000, and the enhancement factor (EF) in the codelivery method was calculated as 11.7 or 15.9, respectively. Simultaneously, β-D-GlcNH₂ showed greatest enhancement at pH 7.0 with an EF of 11. Moreover, there was an optimal concentration range (0.5–1% by weight for CS80-1000 and 1.0–1.5% for β-D-GlcNH₂) to enhance baicalin transdermal delivery. It was concluded that the effective fractions for the enhancement of LMWCs were β-D-GlcNH₂ oligomers, and the repeated number of β-D-GlcNH₂ was suggested to be in the range 2–6. Enhancement mechanism of LMWCs was also discussed and suggested to be relative to the interactions of LMWC with both baicalin and the lipid of stratum corneum. © 2010 Wiley-Liss, Inc. and the American Pharmacists Association J Pharm Sci 99:2991–2998, 2010     

Effect of acyl chain length and unsaturation on physicochemical properties and transfection efficiency of N-acyl-substituted low-molecular-weight chitosan

The effects of acyl chain length and unsaturation on physicochemical characteristics and transfection efficiency of novel nanomicelles of N-acyl-substituted low-molecular-weight chitosan (N-acyl LMWC) were studied. After transfection optimization, 18-carbon chain length grafts were selected, and N-acyl LMWCs were prepared with increasing unsaturation (18:1-18:3 carbon acyl grafts). N-acyl LMWCs were characterized using infrared spectroscopy and elemental analysis. The effect of DNA addition on size and zeta potential of N-acyl LMWCs was determined by dynamic light scattering. N-acyl LMWC-plasmid DNA (pDNA) polyplex stability was confirmed using gel electrophoresis. Transfection efficiency of the derivative polymers was visualized in human embryonic kidney cells using a plasmid encoding green fluorescent protein by confocal fluorescence microscopy and was quantified using therapeutic plasmids encoding for interleukin-4 and interleukin-10. N-acyl LMWCs could form cationic nanomicelles with average hydrodynamic size between 73 and 132 nm. DNA addition to nanomicelles led to minimal increase in the size. N-acyl LMWC-pDNA polyplexes showed excellent stability on storage and could protect DNA from enzymatic degradation. The transfection efficiencies of N-acyl LMWCs with 18:1 and 18:2 grafts were comparable with FuGENE? HD but were approximately eightfold and 35-fold greater as compared with LMWC and naked DNA, respectively.     

Acidic Microclimate pH Distribution in PLGA Microspheres Monitored by Confocal Laser Scanning Microscopy

PURPOSE: The acidic microclimate pH (micropH) distribution inside poly(lactic-co-glycolic acid) (PLGA) microspheres was monitored quantitatively as a function of several formulation variables. METHODS: A ratiometric method by confocal laser scanning microscopy with Lysosensor yellow/blue dextran was adapted from those previously reported, and micropH distribution kinetics inside microspheres was examined during incubation under physiologic conditions for 4 weeks. Effects of PLGA molecular weight (MW) and lactic/glycolic acid ratio, microspheres size and preparation method, and polymer blending with poly(ethylene glycol) (PEG) were evaluated. RESULTS: micropH kinetics was accurately sensed over a broadly acidic range (2.8 < micropH < 5.8) and was more acidic and variable inside PLGA with lower MW and lactic/glycolic acid ratio. Lower micropH was found in larger microspheres of lower MW polymers, but size effects for lactic-rich polymers were insignificant during 4 weeks. Microspheres prepared by the oil-in-oil emulsion method were less acidic than those prepared by double emulsion, and blending PLGA 50/50 with 20% PEG increased micropH significantly (micropH > 5 throughout incubation). CONCLUSIONS: Coupling this method with that previously developed (SNARF-1 dextran for micropH 5.8-8.0) should provide microclimate pH mapping over the entire useful pH range (2.8-8.0) for optimization of PLGA delivery of pH-sensitive bioactive substances.     

A comparison of the direct and reporter antigen popliteal lymph node assay for the detection of immunomodulation by low molecular weight compounds.

The direct popliteal lymph node assay (PLNA) is a predictive test used to detect the immune-stimulating potential of pharmaceuticals and other low molecular weight compounds (LMWCs) with known autoimmunogenic or sensitizing properties. Two limitations in the PLNA are the existence of false negatives and the inability of the assay to provide mechanistic information. Recently the direct PLNA was modified by incorporating reporter antigens (RA), either TNP-Ficoll or TNP-OVA. In the RA-PLNA, immune stimulation is detected by measuring IgM or IgG TNP-specific antibody-forming cells (AFC) using an enzyme-linked immunospot (ELISPOT) assay. The RA-PLNA, when using potent, known autoimmunogenic compounds, may provide greater sensitivity compared to the direct PLNA and might distinguish LMWCs that have intrinsic adjuvant activity from those that create neo-antigens, using TNP-OVA and TNP-Ficoll, respectively. The purpose of this study was to rigorously compare the two assays. Our first objective was to investigate the interlaboratory reproducibility of the RA-PLNA using four autoimmunogenic LMWC models, plus one negative control LMWC. Subsequently, we tested seven LMWCs with known sensitizing properties and compared the results from the direct and modified assay. The test group included LMWCs thought to be mechanistically distinct and similar to compounds typically encountered in preclinical safety assessment. All control and treatment AFC plaques were collected (76 total), pooled, coded to conceal their source, and counted. The interlaboratory reproducibility of the RA-PLNA was demonstrated with the model autoimmunogenic compounds HgCl2, diphenylhydantoin, D-penicillamine, and the negative control compound phenobarbital, by detecting TNP-specific IgM and polyclonal IgG production to both reporter antigens. Additionally, the sensitizing effects of streptozotocin were identified using an IgG2a ELISPOT with both TNP-OVA and TNP-Ficoll. With the extended test group, the sensitizing effects of aniline, a false negative LMWC in the direct PLNA, was not detected in this study when using the direct PLNA. However, there was an increase of IgG1 AFCs using TNP-OVA, when compared to control (508 +/- 113 vs. 12 +/- 4 respectively). Glafenine, diclofenac, and ibuprofen, all associated with drug-induced anaphylaxis in humans, produced significant increases in IgG1 production to TNP-OVA. Of these three LMWCs, only diclofenac, which has been documented to induce neo-antigen formation, was detected with TNP-Ficoll. Hydralazine immunomodulation could be detected only with the direct PLNA although significant increases in IgM were identified with the co-injection of either reporter antigen. Isoniazid and methyldopa consistently produced negative responses in both assays. In summary, this study has demonstrated acceptable interlaboratory reproducibility of the RA-PLNA, using model autoimmunogenic LMWCs. Additionally, it demonstrated that an advantage of the RA-PLNA was that it identified all anaphylactic-associated LMWCs tested, detected the false negative compound aniline, and revealed what is thought to be the mechanism(s) associated with diclofenac-induced immunostimulation.     

Randomly 50% N-acetylated low molecular weight chitosan as a novel renal targeting carrier

Selective targeting of drugs to kidneys may improve renal effectiveness and reduce extrarenal toxicity. Using fluorescence imaging, we found for the first time that randomly 50% N-acetylated low molecular weight chitosan (LMWC) selectively accumulated in the kidneys, especially in the renal tubules after i.v. injection in mice. To develop and evaluate the novel renal drug carrier, prednisolone, used as a model drug, was covalently coupled with various molecular weight LMWCs via a succinic acid spacer. The mean residence time (MRT) in plasma of prednisolone conjugates increased as the molecular weight increased. The conjugate with molecular weight 19 kD (conjugate-19k) displayed the highest accumulation rate in the kidneys, which was 14.06+/-2.81% of the administered dose 15 min after i.v. injection. The total amount of the conjugate-19k in the kidneys was 13-fold higher than that of controlled prednisolone group. Both conjugate-19k and conjugate-31k had higher retention and about 10% of injected dose was still retained in the kidneys after 120 min. Additionally, MTT assay showed LMWCs were noncytotoxic towards L929 and NRK-52E cells. Conclusion can be drawn that the coupling of prednisolone to the proper molecular weight LMWC results in increased prednisolone concentration in the kidneys. Therefore, LMWC with a proper molecular weight can be applied as a promising carrier for renal targeting.     

Randomly 50% N-acetylated low molecular weight chitosan as a novel renal targeting carrier

Selective targeting of drugs to kidneys may improve renal effectiveness and reduce extrarenal toxicity. Using fluorescence imaging, we found for the first time that randomly 50% N-acetylated low molecular weight chitosan (LMWC) selectively accumulated in the kidneys, especially in the renal tubules after i.v. injection in mice. To develop and evaluate the novel renal drug carrier, prednisolone, used as a model drug, was covalently coupled with various molecular weight LMWCs via a succinic acid spacer. The mean residence time (MRT) in plasma of prednisolone conjugates increased as the molecular weight increased. The conjugate with molecular weight 19 kD (conjugate-19k) displayed the highest accumulation rate in the kidneys, which was 14.06 ± 2.81% of the administered dose 15 min after i.v. injection. The total amount of the conjugate-19k in the kidneys was 13-fold higher than that of controlled prednisolone group. Both conjugate-19k and conjugate-31k had higher retention and about 10% of injected dose was still retained in the kidneys after 120 min. Additionally, MTT assay showed LMWCs were noncytotoxic towards L929 and NRK-52E cells. Conclusion can be drawn that the coupling of prednisolone to the proper molecular weight LMWC results in increased prednisolone concentration in the kidneys. Therefore, LMWC with a proper molecular weight can be applied as a promising carrier for renal targeting.     

Colloidal phase behavior of pH-responsive, amphiphilic PEGylated poly(carboxylic acid)s and effect on kinetic solubility under acidic conditions

PEGylated poly(carboxylic acid)s, PEG-b-PCAs, were evaluated as additives for solubilized oral formulations of weakly acidic compounds. Micelles of poly(ethylene glycol)-block-poly(acrylic acid), PEG-b-PAA, and poly(ethylene glycol)-block-poly(methacrylic acid), PEG-b-PMAA, were prepared. Fluorescence spectroscopy and dynamic light scattering revealed that both polymers assemble into nanoscopic structures (< 200?nm) in acidic media and exhibit pH-sensitive colloidal phase behavior. Using a solvent evaporation technique, the block copolymers and corresponding PCA homopolymers were incorporated into PEG3350-based solid dispersions. The kinetic solubility profile of a BMS compound, BMS-A (Seq ~ 12.5?μg/mL at pH 1.1) in 0.1 N HCl was monitored as a function of polymer composition. While BMS-A precipitated rapidly in 0.1 N HCl in the absence of PEG-b-PCAs, a supersaturated level of ca. 400 μg/mL was maintained for variable lengths of time in the presence of PEG-b-PCAs. Although the kinetic solubility of BMS-A was also enhanced in the presence of the PCA homopolymers, the relative magnitude and duration of supersaturation as a function of polymer composition suggests that micellar solubilization, rather than specific interaction, contributes to enhanced solubility of BMS-A in 0.1 N HCl. Under acidic conditions, pH-responsive PEG-b-PCAs may offer the kinetic supersaturation necessary to minimize precipitation of compounds which have limited solubility in acidic milieu.     

Enhanced transfection of tumor cells in vivo using "Smart" pH-sensitive TAT-modified pegylated liposomes

Liposomes have been prepared loaded with DNA (plasmid encoding for the green fluorescent protein, GFP) and additionally modified with TATp and PEG, with PEG being attached to the liposome surface via both pH-sensitive hydrazone and non-pH-sensitive bonds. The pGFP-loaded liposomal preparations have been administered intratumorarly in tumor-bearing mice and the efficacy of tumor cell transfection was followed after 72 h. The administration of pGFP-TATp-liposomes with non-pH-sensitive PEG coating has resulted in only minimal transfection of tumor cells because of steric hindrances for the liposome-to-cell interaction created by the PEG coat, which shielded the surface-attached TATp. At the same time, the administration of pGFP-TATp-liposomes with the low pH-detachable PEG resulted in at least three times more efficient transfection since the removal of PEG under the action of the decreased intratumoral pH leads to the exposure of the liposome-attached TATp residues, enhanced penetration of the liposomes inside tumor cells and more effective intracellular delivery of the pGFP. This result can be considered as an important step in the development of tumor-specific stimuli-sensitive drug and gene delivery systems.     

Surface Modification of Poly(lactide-co-glycolide) Nanospheres by Biodegradable Poly(lactide)-Poly(ethylene glycol) Copolymers

The modification of surface properties of biodegradable poly(lactide-co-glycolide) (PLGA) and model polystyrene nanospheres by poly(lactide)-poly(ethlene glycol) (PLA:PEG) copolymers has been assessed using a range of in vitro characterization methods followed by in vivo studies of the nanospheres biodistribution after intravenous injection into rats. Coating polymers with PLA:PEG ratio of 2:5 and 3:4 (PEG chains of 5000 and 2000 Da, respectively) were studied. The results reveal the formation of a PLA: PEG coating layer on the particle surface resulting in an increase in the surface hydrophilicity and decrease in the surface charge of the nanospheres. The effects of addition of electrolyte and changes in pH on stability of the nanosphere dispersions confirm that uncoated particles are electrostatically stabilized, while in the presence of the copolymers, steric repulsions are responsible for the stability. The PLA:PEG coating also prevented albumin adsorption onto the colloid surface. The evidence that this effect was observed for the PLA:PEG 3:4 coated nanospheres may indicate that a poly(ethylene glycol) chain of 2000 Da can provide an effective repulsive barrier to albumin adsorption. The in vivo results reveal that coating of PLGA nanospheres with PLA:PEG copolymers can alter the biodistribution in comparison to uncoated PLGA nanospheres. Coating of the model polystyrene nanospheres with PLA:PEG copolymers resulted in an initial high circulation level, but after 3 hours the organ deposition data showed values similar to uncoated polystyrene spheres. The difference in the biological behaviour of coated PLGA and polystyrene nanospheres may suggest a different stability of the adsorbed layers on these two systems. A similar biodistribution pattern of PLA:PEG 3:4 to PEG 2:5 coated particles may indicate that poly(ethylene glycol) chains in the range of 2000 to 5000 can produce a comparable effect on in vivo behaviour.     

On the formulation of pH-sensitive liposomes with long circulation times

Strategies used to enhance liposome-mediated drug delivery in vivo include the enhancement of stability and circulation time in the bloodstream, targeting to specific tissues or cells, and facilitation of intracytoplasmic delivery. pH-sensitive liposomes have been developed to mediate the introduction of highly hydrophilic molecules or macromolecules into the cytoplasm. These liposomes destabilize under acidic conditions found in the endocytotic pathway, and usually contain phosphatidylethanolamine (PE) and titratable stabilizing amphiphiles. Formulations without PE have also been developed. Encapsulated compounds are thought to be transported into the cytoplasm through destabilization of or fusion with the endosome membrane. Incorporation of a low mole percentage of poly(ethylene glycol) (PEG)-conjugated lipids into pH-sensitive liposomes confers prolonged circulation times to these liposomes, which are otherwise cleared rapidly. While the incorporation of PEG-lipids reduces the pH-dependent release of encapsulated fluorescent markers in vitro, it does not hinder the cytoplasmic delivery of the markers per cell-associated liposome. This suggests that intracellular delivery is not dictated simply by the destabilization of the liposomes. Antibodies or ligands to cell surface receptors can be coupled to pH-sensitive or sterically stabilized pH-sensitive liposomes for targeting. pH-sensitive liposomes have been used to deliver anticancer drugs, antibiotics, antisense oligonucleotides, ribozymes, plasmids, proteins and peptides to cells in culture or in vivo.     

Polymer based pH-sensitive carriers as a means to improve the cytoplasmic delivery of drugs

pH-sensitive niosomal and liposomal formulations bearing alkylated N-isopropylacrylamide (NIPAM) copolymers were characterized with regard to vesicle-polymer interaction, pH-responsiveness and stability in human serum. The interactions between the pH-sensitive NIPAM copolymer and the vesicles were studied by spectrofluorimetry, using covalently-attached pyrene as a probe. In contrast to liposomes, where complexation of copolymer to the lipid bilayer is essentially mediated by hydrophobic interactions, the binding between niosomes and PNIPAM was mainly driven by hydrogen bonding. Both formulations were found to rapidly release their contents under mildly acidic conditions. However, the niosomes lost their pH-sensitivity after incubation in serum, whereas liposomes maintained their ability to respond to pH only when complexed with a copolymer containing a high proportion of hydrophobic anchor. The ability of pH-sensitive liposome/polymer complexes to enhance the cytotoxicity of cytosine arabinofuranoside (ara-C) was evaluated in vitro using macrophage-like J774 cells. Ara-C encapsulated in pH-sensitive liposomes exhibited a higher cytotoxicity than the control formulation. This study showed that both niosomes and liposomes can be rendered pH-sensitive by anchoring a randomly-alkylated NIPAM copolymer to their surface. The interactions that take place between the polymer and the vesicles strongly depend on the vesicle nature. pH-sensitive PNIPAM-based liposomes can improve the in vitro efficiency of ara-C.     

Enhanced transfection of tumor cells in vivo using “Smart” pH-sensitive TAT-modified pegylated liposomes

Liposomes have been prepared loaded with DNA (plasmid encoding for the green fluorescent protein, GFP) and additionally modified with TATp and PEG, with PEG being attached to the liposome surface via both pH-sensitive hydrazone and non-pH-sensitive bonds. The pGFP-loaded liposomal preparations have been administered intratumorarly in tumor-bearing mice and the efficacy of tumor cell transfection was followed after 72 h. The administration of pGFP–TATp–liposomes with non-pH-sensitive PEG coating has resulted in only minimal transfection of tumor cells because of steric hindrances for the liposome-to-cell interaction created by the PEG coat, which shielded the surface-attached TATp. At the same time, the administration of pGFP–TATp–liposomes with the low pH-detachable PEG resulted in at least three times more efficient transfection since the removal of PEG under the action of the decreased intratumoral pH leads to the exposure of the liposome-attached TATp residues, enhanced penetration of the liposomes inside tumor cells and more effective intracellular delivery of the pGFP. This result can be considered as an important step in the development of tumor-specific stimuli-sensitive drug and gene delivery systems.     

pH-Sensitive PEGylated liposomes functionalized with a fibronectin-mimetic peptide show enhanced intracellular delivery to colon cancer cell

pH-sensitive liposomes undergo rapid destabilization under mildly acidic conditions such as those found in endocytotic vesicles. Though this makes them promising drug carriers, their application is limited due to their rapid clearance from circulation by the reticulo-endothelial system. Researchers have therefore used pH-sensitive liposomes that are sterically stabilized by polyethylene glycol (PEG) molecules (stealth liposomes) on the liposome surface. The goal of this study is to bring bio-functionality to pH-sensitive PEGylated liposomes in order to facilitate their potential use as a targeted drug delivery agent. To improve the selectivity of these nanoparticles, we included a targeting moiety, PR_b which specifically recognizes and binds to integrin α(5)β(1) expressing cells. PR_b (KSSPHSRN(SG)(5)RGDSP) is a novel fibronectin-mimetic peptide sequence that mimics the cell adhesion domain of fibronectin. Integrin α(5)β(1) is expressed on several types of cancer cells, including colon cancer, and plays an important role in tumor growth and metastasis. We have thoroughly studied the release of calcein from pH-sensitive PEGylated liposomes by varying the lipid composition of the liposomes in the absence and presence of the targeting peptide, PR_b, and accounting for the first time for the effect of both pH and time (photo-bleaching effect) on the fluorescence signal of calcein. We have demonstrated that we can design PR_b-targeted pH-sensitive PEGylated liposomes, which can undergo destabilization under mildly acidic conditions and have shown that incorporating the PR_b peptide does not significantly affect the pH-sensitivity of the liposomes. PR_b-targeted pH-sensitive PEGylated liposomes bind to CT26.WT colon carcinoma cells that express integrin α(5)β(1), undergo cellular internalization, and release their load intracellularly in a short period of time as compared to other formulations. Our studies demonstrate that PR_b-functionalized pH-sensitive targeted delivery systems have the potential to deliver a payload directly to cancer cells in an efficient and specific manner.     

pH-Sensitive PEGylated Liposomal Silybin: Synthesis,In Vitro and In Vivo Anti-Tumor Evaluation

The drug delivery systems improve the efficacy of chemotherapeutics through enhanced targeting and controlled release however, biological barriers of tumor microenvironment greatly impede the penetration of nanomedicine within the tumor. We report herein the fabrication of a PEG-detachable silybin (SLB) pH-sensitive liposome decorated with TAT-peptide. For this, Acyl hydrazide-activated PEG₂₀₀₀ was prepared and linked with ketone-derivatized DPPE via an acid-labile hydrazone bond to form mPEG₂₀₀₀-HZ-DPPE. TAT peptide was conjugated with a shorter -PEG₁₀₀₀-DSPE spacer and post-inserted into PEGylated liposome (DPPC: mPEG₂₀₀₀–DSPE: Chol). To prepare nanoliposomes (around 100 nm), first, a novel method was used to prepare SLB-Soya PC (SLB-SPC) complex, then this complex was incorporated into nanoliposomes. The pH-sensitivity and shielding effect of long PEG chain on TAT peptide was investigated using DiI liposome and FACS analysis. Pre-treatment to the lowered pH enhanced cellular association of TAT-modified pH-sensitive liposome due to the cleavage of hydrazone bond and TAT exposure. Besides, TAT-modified pH-sensitive liposomes significantly reduced cell viability compared to the plain liposome. In vivo results were very promising with pH-sensitive liposome by detaching PEG moieties upon exposure to the acidic tumor microenvironment, enhancing cellular uptake, retarding tumor growth, and prolonging the survival of 4T1 breast tumor-bearing BALB/c mice. TAT modification of pH-sensitive liposome improved cancer cell association and cytotoxicity and demonstrated potential intracellular delivery upon exposure to acidic pH. However, in in vivo studies, TAT as a targeting ligand significantly decreased the therapeutic efficacy of the formulation attributed to an inefficient tumor accumulation and higher release rate in the circulation. The results of this study indicated that pH-sensitive liposome containing SLB, which was prepared with a novel method with a significant SLB loading efficiency, is very effective in the treatment of 4T1 breast tumor-bearing BALB/c mice and merits further investigation.     

聚乙二醇POPA磷脂衍生物构建的酶敏脂质体

以磷酰胺键将聚乙二醇高分子MePEG2000-NH₂与磷脂POPA连接在一起, 合成聚乙二醇磷脂衍生物, 以聚乙二醇磷脂衍生物为主要膜材构建酸敏脂质体。采用荧光分析法系统研究了聚乙二醇磷脂衍生物脂质体在酸性条件下对荧光染料的释药特性。以聚乙二醇磷脂衍生物构建的酸敏脂质体,在pH 6.5～7.5时稳定,其稳定性与制备脂质体的磷脂种类及胆固醇含量密切相关,在pH 5.0时发生显著的荧光泄漏,泄漏率与环境酸性的强度及处于酸性的时间呈正相关。聚乙二醇磷脂衍生物构建的脂质体具有开发成酸敏释药脂质体的前景。
     

Doxorubicin loaded pH-sensitive micelle targeting acidic extracellular pH of human ovarian A2780 tumor in mice

The purpose of this study was to examine the efficacy of a chemotherapeutic drug, doxorubicin (DOX), loaded in pH-sensitive micelles poly(l-histidine) (M(n):5K)-b-PEG (M(n):5K) micelles. The micelles were designed to target the acidic extracellular pH of solid tumors. Studies of pH-dependent cytotoxicity, growth rate of the tumor, pharmacokinetics and biodistribution were conducted. In vitro DOX uptake upon A2780 cells by incubating the cells in a pH 6.8 complete medium at a concentration of 20 microg DOX/ml in the micelle formulation was more than five times that of pH 7.4 condition for initial 20 min. In vivo pharmacokinetic data showed that AUC (area under concentration curve) and half life time (t(1/2)) (plasma half life) of DOX in the pH sensitive micelles increased about 5.8- and 5.2-fold of free DOX in phosphate buffered saline (PBS), respectively. It appeared that DOX in the pH-sensitive micelles preferentially accumulated in the tumor site. The distributions at 12 h post injection in other organs including liver, kidney, spleen, lung and heart were not significantly different from those of DOX in PBS at a 6 mg DOX/kg dose. The in vivo test of anti-tumor activity was performed with human ovarian carcinoma A2780 which was subcutaneously xenografted in female nu/nu athymic mice. The pH-sensitive micelle formulation significantly retarded tumor growth rate without serious body weight loss. The triggered drug release by the reduced tumor pH is believed to be a major mechanism of the observed efficacy after passive accumulation of the micelles by EPR effect. This may have resulted in a local high dose of drug in the tested solid tumor.     

Poly(ethylene oxide)-modified poly(beta-amino ester) nanoparticles as a pH-sensitive system for tumor-targeted delivery of hydrophobic drugs. 1. In vitro evaluations

A representative poly(beta-amino ester) (PbAE) with biodegradable and pH-sensitive properties was used to formulate a nanoparticle-based dosage form for tumor-targeted paclitaxel delivery. The polymer undergoes rapid dissolution when the pH of the medium is less than 6.5 and hence is expected to release its contents at once within the acidic tumor microenvironment and endo/lysosome compartments of cells. PbAE nanoparticles were prepared by solvent displacement method and characterized for particle size, charge, and surface morphology. Pluronic F-108, a triblock copolymer of poly(ethylene oxide) (PEO) and poly(propylene oxide) (PPO), was blended with PbAE to induce surface modification of the nanoparticles. In vitro cellular uptake of tritiated [(3)H]-paclitaxel in solution form and as a nanoparticulate formulation was studied in MDA-MB-231 human breast adenocarcinoma cells grown in 12-well plates. We also examined the intracellular degradation pattern of the formulations within the cells by estimating the drug release profile. Cytotoxicity assay was performed on the formulations at different doses and time intervals. Nanoparticles prepared from poly(epsilon-caprolactone) (PCL) that do not display pH-sensitive release behavior were used as control. Spherical nanoparticles having positive zeta potential ( approximately 40 mV) were obtained in the size range of 150-200 nm with PbAE. The PEO chains of the Pluronic were well-anchored within the nanomatrix as determined by electron spectroscopy for chemical analysis (ESCA). The intracellular accumulation of paclitaxel within tumor cells was significantly higher when administered in the nanoparticle formulations as compared to aqueous solution. Qualitative fluorescent microscopy confirmed the rapid release of the payload into the cytosol in the case of PbAE nanoparticles, while the integrity of the PCL nanoparticles remained intact. The cytotoxicity assay results showed significantly higher tumoricidal activity of paclitaxel when administered in the nanoparticle formulations. The cell-kill effect was maximal for paclitaxel-loaded PbAE nanoparticles when normalized with respect to intracellular drug concentrations. Thus, PEO-modified PbAE nanoparticles show tremendous potential as novel carriers of cytotoxic agents for achieving improved drug disposition and enhanced efficacy.     

Enzymatic triggered release of an HIV-1 entry inhibitor from prostate specific antigen degradable microparticles

To achieve sustained release of 3-ethyl-4-(4-methylisoxazol-5-yl)-5-(methylthio) thiophene-2-carboxamide (BFB0261), a new potent osteogenic compound for treating bone disorders, we prepared film formulations containing BFB0261 and the following newly synthesized biodegradable polymers by a solvent casting technique: poly(D,L-lactic acid) (PLA), poly(D,L-lactic acid-co-glycolic acid) (PLGA), poly(D,L-lactic acid)-block-poly(ethylene glycol) (PLA-PEG), and poly(D,L-lactic acid-co-trimethylene carbonate) (PLA-TMC) polymers or copolymers. Powder X-ray diffractometry (PXRD), differential thermal analysis (DTA), scanning electron microscopy (SEM), and tensile testing were performed to examine the physicochemical properties of these films. Almost all the films exhibited a smooth and homogeneous surface, as observed by SEM. In addition, PXRD and DTA revealed that BFB0261 existed in an amorphous state in the films. The in vitro release of BFB0261 from PLA100 (M(w): 251 kDa), PLAPEG9604H (PLA/PEG ratio: 96:4; M(w): 181 kDa), PLAPEG8515H (PLA/PEG ratio: 85:15; M(w): 51.5 kDa), or PLAPEG8020 (PLA/PEG ratio: 80:20; M(w): 33.7 kDa) films followed zero-order kinetics with slow release up to 12 weeks following incubation. Although release of BFB0261 from PLA-TMC films followed first-order kinetics, sustained release of BFB0261 for 12 weeks was still observed for PLATMC8416 (PLA/TMC ratio: 84:16; M(w): 170 kDa) films. Furthermore, when the BFB0261-loaded films constructed from various polymers were implanted subcutaneously on rat backs, the PLAPEG8515H and PLATMC8416 films were capable of achieving sustained release of BFB0261 at the administrated site for 12 weeks. Therefore, the present data indicate that films constructed from PLAPEG8515H or PLATMC8416 may be applicable to bone or tissue engineering.     

Transfer of protons from bulk solution to the surface of poly(L-lactide) microcapsules

Excessive proton transfer from bulk solution to the surface of poly(L-lactide) microcapsules was observed. In acidic solutions of pH less than 3.0, the zeta potential of the microcapsules became slightly positive, although poly(L-lactide) has only carbonyl groups and alcoholic hydroxyl groups which can be charged. In an NMR study, the signal of the water protons shifted towards a higher applied field with increasing interaction of water with the poly(L-lactide) microcapsule surface when the microcapsules were dispersed at low concentrations (up to 4 x 10(-3) per cent). In solutions of pH 3.2-7.6, the observed values of the zeta potential were in good accordance with theoretical values calculated assuming that the charged groups distribute uniformly in the microcapsule wall. In this pH range, the average density of charged groups in the wall was estimated to be 0.04 M. The average volume occupied by one polymer unit (one poly(L-lactide) molecule) in the microcapsule membrane was estimated to be (35 A)3, suggesting a rather tight polymer network in the poly(L-lactide) microcapsule membrane.