Development of Sustained Release System Based on High Water-Absorbable Gel Formation Using Croscarmellose Sodium, Alkaline Excipients and HPMC (ACSH SR System); Novel Application of Croscarmellose Sodium as a Gel Former.

PURPOSE: Croscarmellose sodium, generally used as a superdisintegrant in pharmaceutical formulations, is hydrolyzed to form the gel structure under basic pH conditions. Utilizing this property of croscarmellose sodium, we developed a novel sustained release (SR) system. METHODS: Immediate release (IR) and SR tablets containing croscarmellose sodium, alkaline excipients and/or hydroxypropyl methylcellulose (HPMC) were prepared and examined for wet strength and in vitro drug release behavior. In vivo oral drug absorption was evaluated for IR tablets, HPMC tablets and our novel SR tablets in fasted Beagle dogs. RESULTS: To form the gel structure even under the physiological condition, alkaline excipients were added into the formulation containing croscarmellose sodium. Furthermore, HPMC was used to make the gel structure strong enough against mechanical destructive forces. The novel alkalized croscarmellose sodium-HPMC (ACSH) SR tablet, consisting of croscarmellose sodium, alkaline excipients, and HPMC, successfully sustained the release of acetaminophen, ibuprofen, or nicardipine hydrochloride, compared with the IR tablets. The ACSH SR system provided a better release of acetaminophen than the HPMC tablet without croscarmellose sodium in the release study using a small volume of liquid, suggesting that substantial release and subsequent absorption would be expected in the distal intestinal segments after oral dosing. The in vivo oral absorption study revealed that the ACSH SR system successfully suppressed and prolonged the plasma concentrations of acetaminophen. CONCLUSION: This novel ACSH SR system prepared with croscarmellose sodium, alkaline excipients, and HPMC, would be a promising SR formulation for enabling substantial drug absorption in the distal intestinal segments.

Characterization and Interconversion of Two Crystal Forms of NEt-3IB, a Retinoid X Receptor Agonist.

Retinoid X receptor (RXR) agonist NEt-3IB (1) is a candidate for the treatment of inflammatory bowel disease (IBD), and we have established a process synthesis of 1 in which the final product is obtained by recrystallization from 70% EtOH. However, we found that there are two crystal forms of 1. Here, to characterize and clarify the relationship between them, we conducted thermogravimetry, powder X-ray diffraction, and single crystal X-ray diffraction. The crystal forms were identified as the monohydrate form I and anhydrate form II. The crystal form I, obtained as a stable form by our established synthesis, was easily dehydrated simply by drying to afford the form II', which was similar to the crystal form II obtained by recrystallization from anhydrous EtOH. Storage of the form II' in air regenerated the form I. The molecular conformations of 1 in the crystals of the two forms are similar, and they can be reversibly interconverted. The solubility of the monohydrate form I and anhydrate form II was examined and the former was found to be less soluble than the latter. Thus, form I may be superior to form II for targeting IBD, because of higher delivery to the lower gastrointestinal tract and reduction of systemic side effects associated with lower absorption due to lower water solubility.

Effect of Excessive Serotonin on Pharmacokinetics of Cephalexin after Oral Administration: Studies with Serotonin-Excessive Model Rats.

PURPOSE: Serotonin (5-HT) is important for gastrointestinal functions, but its role in drug absorption remains to be clarified. Therefore, the pharmacokinetics and oral absorption of cephalexin (CEX) were examined under 5-HT-excessive condition to understand the role of 5-HT. METHODS: 5-HT-excessive rats were prepared by multiple intraperitoneal dosing of 5-HT and clorgyline, an inhibitor for 5-HT metabolism, and utilized to examine the pharmacokinetics, absorption behavior and the intestinal permeability for CEX. RESULTS: Higher levels of 5-HT in brain, plasma and small intestines were recognized in 5-HT-excessive rats, where the oral bioavailability of CEX was significantly enhanced. The intestinal mucosal transport via passive diffusion of CEX was significantly increased, while its transport via PEPT1 was markedly decreased specifically in the jejunal segment, which was supported by the decrease in PEPT1 expression on brush border membrane (BBM) of intestinal epithelial cells. Since no change in antipyrine permeability and significant increase in FITC dextran-4 permeability were observed in 5-HT-excessive rats, the enhanced permeability for CEX would be attributed to the opening of tight junction, which was supported by the significant decrease in transmucosal electrical resistance. In 5-HT-excessive rats, furthermore, total body clearance of CEX tended to be larger and the decrease in PEPT2 expression on BBM in kidneys was suggested to be one of the reasons for it. CONCLUSIONS: 5-HT-excessive condition enhanced the oral bioavailability of CEX in rats, which would be attributed to the enhanced permeability across the intestinal mucosa via passive diffusion through the paracellular route even though the transport via PEPT1 was decreased.

Efficient Evaluation of In Vivo Performance in Human for Generic Formulation by Novel Dissolution-Absorption Prediction (DAP) Workflow.

PURPOSE: The pharmaceutical bioequivalence of generic medicines must be confirmed with corresponding original drugs. Although the in vitro dissolution tests are required, results of the mandatory in vitro study do not necessarily reflect the in vivo performance after oral administration. Then, we have tried to develop the novel "Dissolution-Absorption Prediction (DAP) workflow" to evaluate the in vivo performance of generic medicines. METHODS: The DAP workflow consists of an "In vitro two-cell connected dissolution (TCCD) system" mimicking the changes in the luminal pH associated with gastrointestinal transit of medicines, "Evaluation of pharmacokinetics of active pharmaceutical ingredient (API)" and "Prediction of plasma concentration-time profile". TCCD system-evaluated dissolution kinetics of APIs from generic formulations and pharmacokinetic parameters based on human data regarding the original drugs were used to calculate the plasma concentration-time profiles of APIs after the oral administration of generic medicines. RESULTS: The mandatory in vitro dissolution tests indicated that the dissolution properties of valsartan (BCS class II) and fexofenadine (BCS class III/IV) in generic formulations did not coincide with those in the corresponding original formulations. The TCCD system provided the very similar dissolution kinetics for the generic and original formulations for the two APIs. Plasma concentration-time profiles evaluated utilizing the dissolution profiles obtained by the TCCD system were in good agreement with the observed profiles for both the generic and original formulations for each API. CONCLUSIONS: The DAP workflow would be valuable for estimating the in vivo performance of generic formulation and deducing their bioequivalence with the original formulation.

Quantitative Estimation of the Effect of Nasal Mucociliary Function on in Vivo Absorption of Norfloxacin after Intranasal Administration to Rats.

Nasal drug delivery has attracted significant attention as an alternative route to deliver drugs having poor bioavailability. Large-molecule drugs, such as peptides and central nervous system drugs, would benefit from intranasal delivery. Drug absorption after intranasal application depends on the nasal retention of the drug, which is determined by the nasal mucociliary clearance. Mucociliary clearance (MC) is an important determinant of the rate and extent of nasal drug absorption. The aim of the present study was to clarify the effect of the changes in MC on in vivo drug absorption after nasal application, and to justify the pharmacokinetic model to which the MC parameter was introduced, to enable prediction of bioavailability after intranasal administration. The pharmacokinetics of norfloxacin (NFX) after intranasal administration were evaluated following the modification of nasal MC by pretreatment with the MC inhibitors propranolol and atropine and the MC enhancers terbutaline and acetylcholine chloride. From the relationship between nasal MC and bioavailability after nasal application, prediction of drug absorption was attempted on the basis of our pharmacokinetic model. Propranolol and atropine enhanced the bioavailability of NFX by 90 and 40%, respectively, while the bioavailability decreased by 30% following terbutaline and 40% following acetylcholine chloride. As a result of changes in the MC function, nasal drug absorption was changed depending on the nasal residence time of the drug. On the basis of our pharmacokinetic model, the nasal drug absorption can be precisely predicted, even when the MC is changed. This prediction system allows the quantitative evaluation of changes in drug absorption due to changes in nasal MC and is expected to contribute greatly to the development of nasal formulations.

Biomarker discovery for drug-induced phospholipidosis: phenylacetylglycine to hippuric acid ratio in urine and plasma as potential markers.

CONTEXT: Drug-induced phospholipidosis is one of the significant concerns in drug development, especially in safety assessment and noninvasive diagnostic tool is highly desirable. OBJECTIVE: The objective of this study is to explored novel biomarkers for phospholipidosis using a metabolomic approach. METHOD: NMR spectrometry and LC/MS/MS analyses were applied to urine and plasma of rats administrated cationic amphiphilic drugs. RESULTS: The phenylacetylglycine to hippuric acid ratio in plasma was increased in time and dose-dependent manners; and it was well correlated with histopathological observation. CONCLUSION: The plasma phenylacetylglycine to hippuric acid ratio is a potential marker in monitoring drug-induced phospholipidosis.

Nanoparticle-Based Photodynamic Therapy: Current Status and Future Application to Improve Outcomes of Cancer Treatment.

Photodynamic therapy (PDT) is an emerging cancer treatment that uses photosensitizers (PS), along with light to activate them, resulting in oxidation of various biological components in cancer tissues. However, since most potential PS are solubilized and given as aqueous solution, PS is non-specifically distributed in the body, leading to the induction of various side effects in normal tissues that are exposed to daylight such as skin and eyes. To overcome the problem associated with non-specific in vivo disposition of PS, various approaches have been applied to develop safer dosage forms for PS with more efficient tumor delivery and lower disposition to normal tissues. Passive drug targeting to tumors with nanoparticulate formulations has been recognized as one of the potentially useful approaches to improve the poor tissue specificity of conventional cancer chemotherapy and this approach should also be applicable for more efficient tumor delivery of PS. In this review article, several issues concerning the efficacy of PDT using nanoparticle-based formulations are discussed and our recent attempts to temporally enhance the vascular permeability within tumors with photodynamic treatment for the better therapeutic outcome of nanoparticle-based therapy are introduced.

Analysis of Intra- and Intersubject Variability in Oral Drug Absorption in Human Bioequivalence Studies of 113 Generic Products.

In this study, the data of 113 human bioequivalence (BE) studies of immediate release (IR) formulations of 74 active pharmaceutical ingredients (APIs) conducted at Sawai Pharmaceutical Co., Ltd., was analyzed to understand the factors affecting intra- and intersubject variabilities in oral drug absorption. The ANOVA CV (%) calculated from area under the time-concentration curve (AUC) in each BE study was used as an index of intrasubject variability (Vintra), and the relative standard deviation (%) in AUC was used as that of intersubject variability (Vinter). Although no significant correlation was observed between Vintra and Vinter of all drugs, Vintra of class 3 drugs was found to increase in association with a decrease in drug permeability (P(eff)). Since the absorption of class 3 drugs was rate-limited by the permeability, it was suggested that, for such drugs, the low P(eff) might be a risk factor to cause a large intrasubject variability. To consider the impact of poor water solubility on the variability in BE study, a parameter of P(eff)/Do (Do; dose number) was defined to discriminate the solubility-limited and dissolution-rate-limited absorption of class 2 drugs. It was found that the class 2 drugs with a solubility-limited absorption (P(eff)/Do < 0.149 × 10(-4) cm/s) showed high intrasubject variability. Furthermore, as a reason for high intra- or intersubject variability in AUC for class 1 drugs, effects of drug metabolizing enzymes were investigated. It was demonstrated that intrasubject variability was high for drugs metabolized by CYP3A4 while intersubject variability was high for drugs metabolized by CYP2D6. For CYP3A4 substrate drugs, the Km value showed the significant relation with Vintra, indicating that the affinity to the enzyme can be a parameter to predict the risk of high intrasubject variability. In conclusion, by analyzing the in house data of human BE study, low permeability, solubility-limited absorption, and high affinity to CYP3A4 are identified as risk factors for high intrasubject variability in oral drug absorption. This information is of importance to design the human BE study for oral drug products containing APIs with a risk of large intrasubject variability in oral absorption.

Improvement of Oral Bioavailability of N-251, a Novel Antimalarial Drug, by Increasing Lymphatic Transport with Long-Chain Fatty Acid-Based Self-Nanoemulsifying Drug Delivery System.

PURPOSE: The objective of this study was to improve the absorption behavior of N-251, a novel antimalarial drug, by preparing an appropriate self-nanoemulsifying drug delivery system (SNEDDS). METHODS: Two different types of SNEDDS formulations, medium-chain fatty acid-based SNEDDS (MC-SNEDDS) and long-chain fatty acid-based SNEDDS (LC-SNEDDS), were prepared based on pseudo-ternary phase diagram, and examined for their in vivo oral absorption behavior in rats. RESULTS: Oral dosing of MC-SNEDDS formulations significantly improved the bioavailability (BA) of N-251 compared with N-251 powders. However, its high hepatic extraction limited the BA of N-251 to only 0.49 for MC-SNEDDS B, the best formulation of MC-SNEDDS. LC-SNEDDS formulations, especially LC-SNEDDS F provided the highest BA, 0.65, and successfully attenuated the inter-individual difference in the absorption behavior. Furthermore, it was confirmed that lymphatic transport of N-251 for LC-SNEDDS F was significantly increased up to around 3.19 times larger than that for MC-SNEDDS B. Simulation study suggested that 20 to 39% of N-251 uptaken by the small intestine would be delivered to lymphatic system after oral administration of LC-SNEDDS F. CONCLUSIONS: SNEDDS formulations significantly improved the absorption behavior of N-251 and long-chain fatty acid-based lipid further improved it by avoiding the hepatic first-pass elimination.

Effects of temperature, growth phase and luxO-disruption on regulation systems of toxin production in Vibrio vulnificus strain L-180, a human clinical isolate.

Vibrio vulnificus is a halophilic estuarine bacterium while it causes fatal septicemia or necrotizing wound infections in humans. This pathogen secretes the metalloprotease (V. vulnificus protease: VVP) and the cytolysin (V. vulnificus hemolysin: VVH) as protein toxins; however, their production was coordinated in response to the bacterial cell density. This regulation is termed quorum sensing (QS) and is mediated by the small diffusible molecule called autoinducer 2 (AI-2). In the present study, we investigated effects of disruption of luxO encoding a central response regulator of the QS circuit, as well as effects of temperature and growth phase, on the toxin production by V. vulnificus. Disruption of luxO was found to increase VVP production and expression of its gene vvpE. The expression of smcR, crp and rpoS, of which products positively regulate vvpE expression, and luxS encoding the AI-2 synthetase were also significantly increased. On the other hand, the luxO disruption resulted in reduction of VVH production and expression of its gene vvhA. Expression of other two genes affecting the QS circuit, luxT and rpoN, were also significantly decreased. The regulation systems of VVP production were found to exert their action during the stationary phase of the bacterial growth and to be operated strongly at 26 °C. By contrast, those of VVH production apparently started at the log phase and were operated more effectively at 37 °C.

Combination of co-amorphization with SNEDDS outperforms Ofev® in the oral absorption of nintedanib.

Nintedanib (NTD), approved for the treatment of idiopathic pulmonary fibrosis and advanced non-small cell lung cancer, is one of brick dusts with high melting point. Although NTD has been marketed as Ofev®, a soft capsule of NTD ethanesulfonate (NTD-ESA) suspended in oil components, the oral bioavailability is quite low and highly variable. To improve the oral absorption behavior of NTD, we prepared SNEDDS formulation containing NTD-(+)-10-camphorsulfonic acid (CSA) complex with 2% HPMCP-50. CSA disrupted the high crystallinity of NTD-ESA and the formed complex, NTD-CSA, was found to be amorphous by DSC and XRPD. NTD-CSA provided solubilities in various vehicles much higher than NTD-ESA. Under the gastric luminal condition, NTD-CSA SNEDDS with or without 2% HPMCP-50 and NTD-CSA powder indicated very good dissolution of NTD from early time periods, while NTD was gradually dissolved until around 60 min from NTD-ESA and Ofev®. Under the small intestinal luminal condition, in contrast, both NTD-CSA SNEDDS formulations almost completely dissolved NTD throughout the experiments, while Ofev®, NTD-CSA, and NTD-ESA exhibited a very poor dissolution of NTD. In the in vivo absorption study, NTD-CSA SNEDDS with 2% HPMCP-50 significantly improved NTD absorption and reduced the inter-individual variation in oral absorption behavior compared with Ofev®.

Possible Regulation of P-Glycoprotein Function by Adrenergic Agonists II: Study with Isolated Rat Jejunal Sheets and Caco-2 Cell monolayers.

To clarify the regulation of drug absorption by the enteric nervous system, we investigated how adrenergic agonists (adrenaline (ADR), clonidine (CLO), dobutamine (DOB)) and dibutyryl cAMP (DBcAMP) affected P-glycoprotein (P-gp) function by utilizing isolated rat jejunal sheets and Caco-2 cell monolayers. ADR and CLO significantly decreased the secretory transport (Papptotal) of rhodamine-123 and tended to decrease the transport via P-gp (PappP-gp) and passive transport (Papppassive). In contrast, DBcAMP significantly increased and DOB tended to increase Papptotal and both tended to increase PappP-gpand Papppassive. Changes in P-gp expression on brush border membrane by adrenergic agonists and DBcAMP were significantly correlated with PappP-gp, while P-gp expression was not changed in whole cell homogenates, suggesting that the trafficking of P-gp would be responsible for its functional changes. Papppassive was inversely correlated with transmucosal or transepithelial electrical resistance, indicating that adrenergic agonists affected the paracellular permeability. Adrenergic agonists also changed cAMP levels, which were significantly correlated with PappP-gp. Furthermore, protein kinase A (PKA) or PKC inhibitor significantly decreased PappP-gp in Caco-2 cell monolayers, suggesting that they would partly contribute to the changes in P-gp activity. In conclusion, adrenergic agonists regulated P-gp function and paracellular permeability, which would be caused via adrenoceptor stimulation.

Nanoparticle-based passive drug targeting to tumors: considerations and implications for optimization.

There are many potential barriers to the effective delivery of small-molecule drugs to solid tumors. Most small-molecule chemotherapeutic drugs have a large volume of distribution upon intravenous administration, which is often associated with a narrow therapeutic index due to their high level of toxicity in healthy tissues. Nanoparticle-based therapeutics for tumor targeting have emerged as one of the promising approaches to overcome the lack of tissue specificity of conventional chemotherapeutic drugs. Various different concepts have been envisioned for nanoparticle-mediated drug targeting. Among them, the passive drug targeting strategy has been the most widely investigated, and numerous preclinical studies have provided insights into the validity of the strategy. This review article briefly introduces our recent findings related to the passive drug targeting strategy including its application in anti-angiogenic therapy, along with considerations to be taken into account and implications for the rational design of a passive drug targeting strategy.

In vitro evaluation of the ciliary beat frequency of the rat nasal epithelium using a high-speed digital imaging system.

Mucociliary clearance (MC) is an important factor in determining nasal drug absorption and the ciliary beat of ciliated epithelial cells of the nasal mucosa is the driving force of MC. However, the relationship between MC and ciliary beat frequency (CBF) is still ambiguous. The purpose of this study was to establish an evaluation method of CBF as an index of mucociliary function and examine the relationship between MC and CBF. A sequence of images of ciliary beating of an excised rat nasal septum was captured using a high-speed digital video camera. CBF (beats per second, Hz) was determined from periodic changes in the contrast value of a specific location in a sequence of images. CBF under control conditions was 8.49±0.38 Hz, which is similar to values reported for cultured human nasal epithelial cells and rat tracheal cells. ß-Adrenergic and cholinergic antagonists decreased CBF, while ß-adrenergic agonists and acetylcholine increased CBF. These results were similar with those observed for MC in our previous study. It was found that CBFs were significantly and linearly correlated with MC, indicating that MC is directly regulated by CBF and that this evaluation system allows the quantitative determination of nasal mucociliary function.

Establishment of a novel in vitro co-culture system of enteric neurons and Caco-2 cells for evaluating the effect of enteric nervous system on transepithelial transport of drugs.

The gastrointestinal tract is innervated by extrinsic autonomic nerves and intrinsic enteric nervous system (ENS). However, the role of ENS in drug absorption has remained to be clarified. To investigate the effect of ENS on drug transport across the intestinal epithelial cells, we established a novel co-culture system of Caco-2 cells and enteric neurons differentiated from neural crest stem (NCS)-like cells isolated from mouse longitudinal muscle/myenteric plexus (LMMP). Immunostaining analysis revealed that the proportions of neuron, glia, and NCS-like cells were only <5 % at population in the primary culture of LMMP cells. Therefore, we proliferated NCS-like cells and differentiated them into neuronal cells and successfully increased the neuronal cell population upto about 40 %. Then, the differentiated neuronal cells were co-cultured with Caco-2 cell monolayers, and we found that the co-culture significantly decreased the transepithelial electrical resistance and enhanced the transport of fluorescein isothiocyanate-labeled dextran-4 across Caco-2 cell monolayers, suggesting that the enteric neurons would function to open the tight junction and facilitate the drug transport via the paracellular route. On the other hand, no changes in the permeability of antipyrine were observed, suggesting that the enteric neurons would not affect the passive transport via the transcellular pathway.

Improvement and characterization of oral absorption behavior of clofazimine by SNEDDS: Quantitative evaluation of extensive lymphatic transport.

Clofazimine, an anti-leprosy drug, has been anticipated for a candidate to treat tuberculosis, cryptosporidiosis, and coronavirus infection, but its low oral bioavailability is considered a reason for its limited activity. In the current study, we have tried to improve the oral bioavailability of clofazimine by several SNEDDS formulations and characterized the absorption behavior from various aspects. Among four SNEDDS formulations prepared, SNEDDS A, prepared with castor oil as an oil component, provided the highest bioavailability (around 61%) and SNEDDS D, prepared with Capryol 90, gave the second highest bioavailability. SNEDDS A formed the finest nanoparticles, which were maintained under gastric and intestinal luminal conditions. The comparison in oral bioavailability between the SNEDDS formulation and its corresponding preformed nanoemulsion suggested that SNEDDS A would efficiently form nanoemulsion in the gastrointestinal tract after oral administration. AUC of mesenteric lymph node concentration was the highest for SNEDDS A, which would be one of the reasons for SNEDDS A to reveal the highest oral bioavailability. A cycloheximide-treated oral absorption study and single-pass perfusion study by utilizing a vascular-luminal perfused small intestine-liver preparation clearly indicated that over 90% of clofazimine absorbed to systemic circulation should be derived from lymphatic transport for both SNEDDS A and D. Furthermore, the fraction of dose absorbed was around 65% for SNEDDS D, but SNEDDS A achieved around 94%, indicating the excellent performance of SNEDDS A.

Deeper penetration into tumor tissues and enhanced in vivo antitumor activity of liposomal paclitaxel by pretreatment with angiogenesis inhibitor SU5416.

The recently emerged concept of "vessel normalization" implies that judicious blockade of vascular endothelial growth factor (VEGF) signaling may transiently "normalize" the tumor vasculature, making it more suitable for tumor disposition of subsequently administered drugs. In this study, therefore, the effect of pretreatment with SU5416, a selective VEGF receptor-2 inhibitor, on tumor disposition and in vivo antitumor activity of polyethylene glycol (PEG)-modified liposomal paclitaxel (PL-PTX) was evaluated in Colon-26 solid tumor-bearing mice. To improve the solubility and in vivo disposition characteristics of SU5416, the inhibitor was formulated in PEGylated O/W emulsion (PE-SU5416). Pretreatment with PE-SU5416 significantly enhanced the in vivo antitumor effect of PL-PTX, although PE-SU5416 administration alone did not show any antitumor effect. Immunostaining for endothelial cells and pericytes demonstrated that the pretreatment with PE-SU5416 enhanced the pericyte coverage of the tumor vasculature. In addition, tumors treated with PE-SU5416 contained significantly smaller hypoxic regions compared with the nontreated control group, demonstrating that structural normalization of the tumor vasculature resulted in an improvement in tumor vessel functions, including oxygen supply. Furthermore, the pretreatment with PE-SU5416 increased the distribution of PEG liposomes and included PTX in the core region of the tumor, as well as conversely decreasing the ratio of their peripheral distribution. These results suggest that the structural and functional normalization of the tumor vasculature by the pretreatment with PE-SU5416 enabled liposomes to reach the deeper regions within tumor tissues, leading to more potent antitumor activity of PL-PTX.

Novel comb-shaped PEG modification enhances the osteoclastic inhibitory effect and bone delivery of osteoprotegerin after intravenous administration in ovariectomized rats.

PURPOSE: Recombinant osteoprotegerin (OPG) has been proven to be useful for treating various bone disorders such as osteoporosis. To improve its in vivo pharmacological effect, OPG was conjugated to novel comb-shaped co-polymers of polyethylene glycol (PEG) allylmethylether and maleamic acid (poly(PEG), 5 kDa). Biodistribution and bioactivity were evaluated. METHODS: OPG was conjugated via lysine to poly(PEG) and to linear PEG (0.5 kDa and 5 kDa). Poly(PEG)-OPG was compared with linear PEG0.5k-OPG and PEG5k-OPG in terms of in vitro and in vivo efficacy and bone distribution. RESULTS: The in vitro receptor binding study showed that poly(PEG)-OPG could be the most bioactive among the three PEG-OPG derivatives. Pharmacokinetic studies in ovariectomized (OVX) rats showed that serum half-life and AUC of poly(PEG)-OPG were comparable with those of linear PEG-OPG derivatives. For in vivo pharmacological effect, poly(PEG)-OPG showed the strongest inhibitory effect on bone resorption activity in OVX rats. Poly(PEG)-OPG demonstrated enhanced bone marrow distribution with higher selectivity than linear PEG5k-OPG. CONCLUSION: Poly(PEG) modification could provide longer residence time in serum and higher bone-marrow specific delivery of OPG, leading to a higher in vivo pharmacological effect.

Development of transdermal therapeutic formulation of CNS5161, a novel N-methyl-D-aspartate receptor antagonist, by utilizing pressure-sensitive adhesives I.

The aim of this study was to investigate the feasibility of percutaneous absorption of CNS5161, a novel N-methyl-D-aspartate (NMDA) receptor antagonist developed as a potential treatment for neuropathic pain and other neurological disorders. Six pressure-sensitive adhesives (PSA) with different physicochemical properties, namely, styrene-isoprene-styrene (1) (SIS(1)), styrene-isoprene-styrene (2) (SIS(2)), silicone, acrylate with a hydroxyl group (acrylate(OH)), acrylate without a functional group (acrylate(none)) and acrylate with a carboxyl group (acrylate(COOH)), were investigated for their release of CNS5161 and its subsequent skin permeability. Among the adhesives examined, silicone PSA provided the highest value of transdermal flux of CNS5161, which could be attributable to the highest release rate from it due to its very high thermodynamic activity. Although CNS5161 was also in the supersaturated state in SIS(1) and SIS(2) PSAs, the release and transdermal permeation from these adhesives were slower than those from silicone PSA. As for the acrylic PSAs, the highest release rate and permeability of CNS5161 were observed for acrylate(OH) PSA, followed by acrylate(none) and acrylate(COOH) PSAs, but none of them was better in terms of either the release or the permeability of CNS5161 than silicone PSA. These results clearly indicated that silicone PSA would be the most suitable for transdermal delivery of CNS5161 and silicone PSA containing 10% CNS5161 would be suitable for clinical use in humans.

Formulation and evaluation of paclitaxel-loaded polymeric nanoparticles composed of polyethylene glycol and polylactic acid block copolymer.

To develop potent paclitaxel (PTX) formulations for cancer chemotherapy, we formulated PTX into polymeric nanoparticles composed of polyethylene glycol (PEG) and polylactic acid (PLA) block copolymer (PN-PTX). First, the physicochemical properties of PN-PTX prepared were assessed; the mean particle size was around 80 nm and the zeta potential was found to be almost neutral. Next, the in vitro PTX release property was assessed by a dialysis method. Although rapid release of PTX was observed just after dosing, around 70% of PTX was stably incorporated in polymeric nanoparticles for a long time in the presence of serum. Then, the in vivo pharmacokinetics of PN-PTX after intravenous administration was investigated in Colon-26 (C26) tumor-bearing mice. Both polymeric nanoparticles and PTX incorporated exhibited a long blood circulating property, leading to enhanced permeability and retention (EPR) effect-driven, time-dependent tumor disposition of PTX. Tumor distribution increased gradually for 24 h, and tissue uptake clearance of polymeric nanoparticles in the liver and spleen was lower than that of PEG liposomes. Since these results indicated that the in vivo disposition characteristics of PN-PTX were very favorable, we then evaluated the anti-tumor effect of PN-PTX in C26 tumor-bearing mice. However, PN-PTX did not exhibit any significant anti-tumor effect, presumably due to the poor PTX release from polymeric nanoparticles. From these results, it is considered that the favorable pharmacokinetic properties of nanoparticles and the drug incorporated do not always lead to its potent in vivo pharmacological activity, suggesting the importance of PTX release properties within tumor tissues.