Nanostructured porous silicon microparticles enable sustained peptide (Melanotan II) delivery

Peptide molecules can improve the treatment of a number of pathological conditions, but due to their physicochemical properties, their delivery is very challenging. The study aim was to determine whether nanostructured porous silicon could sustain the release and prolong the duration of action of a model peptide Melanotan II (MTII). Thermally hydrocarbonized nanoporous silicon (THCPSi) microparticles (38-53 μm) were loaded with MTII. The pore diameter, volume, specific surface area and loading degree of the microparticles were analyzed, and the peptide release was evaluated in vitro. The effects of MTII on heart rate and water consumption were investigated in vivo after subcutaneous administration of the MTII loaded microparticles. A peptide loading degree of 15% w/w was obtained. In vitro studies (PBS, pH 7.4, 37 °C) indicated sustained release of MTII from the THCPSi microparticles. In vivo, MTII loaded THCPSi induced an increase in the heart rate 2 h later than MTII solution, and the effect lasted 1 h longer. In addition, MTII loaded THCPSi changed the water consumption after 150 min, when the immediate effect of MTII solution was already diminished. The present study demonstrates that MTII loading into nanosized PSi pore structure enables sustained delivery of an active peptide.     

Physicochemical Characterization and Cytotoxicity Screening of a Novel Colloidal Nanogold-Based Phenytoin Conjugate

A novel, colloidal nanogold-based drug delivery system for phenytoin, a well-known anti-epileptic drug with an enhanced efflux via P-glycoprotein, has been proposed in this study. The vital physical properties that would aid in predicting the biological interaction of this system were profiled using various techniques such as UV-Vis, DLS, and TEM in corroboration with theoretical calculations. It was significant to note that the binding of phenytoin to colloidal nanogold was strongly pH-dependent with the optimum at pH 5.5 and a consistently reproducible spectral shift. Analysis of the conjugate by FTIR revealed that the imide functional group of phenytoin mediated a dative coordinate bond to colloidal nanogold at the optimum pH. The amount of the drug bound to the gold was quantified to be 85.8±2.5% (w/v) by HPLC. Hypothetically, the surface charge of the conjugate could possibly imply charge-mediated uptake across the cell membrane. Further, the novel conjugate was screened for its cytotoxicity in two cell lines and the dosage range was identified. Subsequent development, thorough evaluations in suitable model systems, and the potential for bioimaging to track the payload would validate our hypothesis on the conjugate for better intracellular retention at the site of action, and thereby achieve the targeted delivery.     

Sodium alginate based mucoadhesive system for gatifloxacin and its in vitro antibacterial activity

The objective of this study was to formulate sodium alginate based ophthalmic mucoadhesive system of gatifloxacin and its in vitro antibacterial potential on pathogenic microorganisms, Staphylococcus aureus and Escherichia coli. Sodium carboxymethylcellulose (NaCMC) was added to the formulations to enhance the gel bioadhesion properties. The prepared formulations were evaluated for their in vitro drug release, gelation behaviour, rheological behavior, and mucoadhesion force. All formulations in non-physiological and physiological condition showed pseudo plastic behavior. Increase in the concentration of sodium alginate and sodium CMC enhanced the mucoadhesive force significantly. In vitro release of gatifloxacin from the system in simulated tear fluid (STF, pH a 7.4), was influenced significantly by the properties and concentration of sodium alginate, NaCMC. Significant reduction in total bacterial count was observed between control and treatment groups with both the test organisms.     

Composite microparticles with in vivo reduction of the burst release effect

The aim of this study was to develop microparticles containing nanoparticles (composite microparticles) for prolonged drug delivery with reduced burst effect in vitro and in vivo. Such composite microparticles were prepared with hydrophobic and biodegradable polymers [poly(ε-caprolactone), poly(lactic-co-glycolic) acid]. Ibuprofen was chosen as the model drug, and microparticles were prepared by the extraction technique with ethyl acetate as the solvent. Nanoparticles and microparticles and an ibuprofen solution (Pedea^®) were administered subcutaneously at the dose of 1 mg of ibuprofen per kg to overnight-fasted rats (male Wistar). Composite microparticles showed prolonged ibuprofen release and less burst effect when compared to simple microparticles (without nanoparticles inside) or nanoparticles both in vitro (PBS buffer) and in vivo. Moreover, ibuprofen was still detected in the plasma after 96 h with composite microparticles. Consequently, it has been demonstrated that composite microparticles were able to reduce burst release and prolong the release of ibuprofen for a long period of time.     

Feasibility, stability and release performance of a time-dependent insulin delivery system intended for oral colon release

The aim of the present work was to evaluate the viability of a time-dependent delivery platform (Chronotopic^TM) in preparing an insulin-based system intended for oral colon delivery. The main objectives were to assess the influence of the manufacturing process and storage conditions on the protein stability. Insulin-loaded cores were manufactured by direct compression and were subsequently coated with hydroxypropyl methylcellulose (HPMC) in a top-spray fluid bed up to increasing weight gains, namely 20%, 60% and 100%. In order to evaluate the impact the operating conditions may have on the protein integrity, insulin and its main degradation products (A21-desamido insulin - A21, Other Insulin-Related Compounds - OIRCs, and High-Molecular Weight Proteins - HMWPs) were assayed on samples collected after each process step by chromatographic methods. Furthermore, long-term (4 °C) and accelerated (25 °C-60% RH) stability studies were carried out on tablet cores and coated systems by assessing insulin, A21, OIRC and HMWP percentages throughout a one-year storage period. In addition, the in vitro release behaviour was investigated during the same study period. The overall results indicated that the manufacturing process is not detrimental for insulin integrity and that 4 °C storage temperature alters neither the protein content nor the release performances of the device.It was therefore concluded that insulin-containing systems intended for oral colon delivery can be obtained by the Chronotopic^TM technology.     

Application of toxicogenomic tools in the drug research and development process

The cost for the development of new active and safe drugs is higher than ever and continues to increase. At the same time, both the pharmaceutical industry and the Regulatory Authorities are, despite the increasing effort to develop safer drugs, concerned by the risk of unexpected side effects observed in the late steps of the development of new drugs, either in late clinical development or after marketing approval. Then, the early knowledge of any potential toxic effect of a new drug is a key issue to allow adequate decision making. This means that current approaches based on the determination of the No-Adverse-Effect-Level and the Human-Equivalent-Dose are far from being perfect, and fail mainly to detect toxic phenomena of low intensity and/or low frequency. To improve the predictability of the existing experimental models, Toxicogenomics could be included into the in vitro candidate-selection steps and/or during the regulatory preclinical (or clinical) studies.     

Preparation and characterization of chitosan nanopores membranes for the transport of drugs

In this paper, a novel chitosan nanopores membrane was developed by selective dissolution of its composition. Polyethylene glycol (PEG) as the porogen was selected to generate the nanopores structure of chitosan membrane. As the observation with scanning electron microscopy (SEM), we could find that the PEG content was greatly influenced on the structure of chitosan membrane. As the PEG content was larger than 50%, the chitosan nanopores membrane could successfully developed. Differential scanning calorimeter (DSC) measurement revealed that the PEG component could not be completely dissolved from the membrane and there was presence the possible interaction (hydrogen bond) between two components. Water adsorption test suggested that the obtained membranes have the great capacity of water adsorption ranging from 162.4 ± 22.5% to 321.5 ± 6.5%. In vitro degradation experiment showed that the obtained chitosan membranes have good biodegradability in the lysozyme solution. The permeability test was performed with two model drugs: vitamin B12 (non-ionic water-soluble drug) and sodium sulfamerazine (ionic water-soluble drug). And the results showed that these two drugs have significant differences in the permeability, indicating that chitosan nanopores membranes can potentially be used to the transport of drugs with controlled diffusion manner.     

Soyabean powder as a novel diluent in tablet formulation of simvastatin

The present research paper introduces soyabean nuggets powder, as a novel excipient with nutraceutical value for tablets containing cholesterol lowering drug, simvastatin. Experiments were carried out to evaluate the suitability of soyabean nuggets powder as a diluent by incorporating in tablet formulation of simvastatin. The formulation was compared with the marketed product to determine its relative efficacy. Soyabean nuggets powder was found to be a promising diluent for tablets for both pharmaceutical and nutraceutical purposes. Simavastatin soya tablet showed acceptable pharmacotechnical properties and assay requirement.     

两亲性壳聚糖包覆紫杉醇脂质体的制备及体外释放研究

目的:制备两亲性壳聚糖N-辛基-N,O-羧甲基壳聚糖包覆紫杉醇脂质体(PTX-LP-OCC),并考察其理化性质及体外释放行为。方法:采用基于乙醇的前体脂质体法制备紫杉醇脂质体并以OCC包覆,并以普通脂质体(PTX-LP)为对照,测定其包封率、粒径大小、电位,观测其形态及稳定性,然后采用全体液平衡反向透析法研究体外释放行为。结果:紫杉醇脂质体包封率为89.5%,粒径为236.5 nm,Zeta电位为-31.4 mV,多糖包覆修饰后药物包封率无显著变化,粒径及Zeta电位显著增加,脂质体稳定性显著提高,药物释放呈缓释特征,且突释显著降低。结论:两亲性壳聚糖包覆脂质体是一个有前景的抗肿瘤药物递送载体     

Preparation of a novel floating ring capsule-type dosage form for stomach specific delivery

Study objectives were to develop a unique floating ring capsule dosage form which combines gastric soluble and insoluble portions, and to evaluate its suitability for stomach specific drug delivery. New floating ring capsules were developed using different polymers and were compared for various parameters. The formulation with HPMC and sodium CMC has better floating properties. The effects of polymers concentration on drug release were studies by in vitro release studies. The interaction studies of combined drug with polymers were determined using FT-IR spectroscopy. The entrapped air within the gel barrier and lower densities of HPMC and sodium CMC resulted in better floating behavior. Steady slow gel formations showed prolonged drug release. The in vitro release rates were generally found to be faster with low concentration of carbopol showing release within 2 h, while formulations containing high amount of HPMC showed release in 8 h. In particular, the higher concentration of HPMC formulation shows the best drug release performance. A very low change in peak shift was observed only with sodium alginate formulations. Further, FT-IR measurements confirmed the absence of any chemical interactions. Results indicate that new floating ring capsule is a promise dosage form for stomach specific delivery.     

Challenges of using pluripotent stem cells for safety assessments of substances

Various European Union (EU) legislations request the use of in vitro tests for toxicological evaluations in order to increase the safety of consumer and patients but also to reduce the number vertebrates. The review provides a brief overview on EU legislations in place but without further interpretation. At present several ongoing EU projects address the need of developing predictive in vitro tests including projects assessing the potential of human embryonic stem cell (hESC) lines as basis for a range of toxicity tests. Tests based on human cells would avoid interspecies variations and as such predict more precisely adverse effects to the human body.     

Prediction of the contact sensitizing potential of chemicals using analysis of gene expression changes in human THP-1 monocytes

The aim of this study was to find differentially regulated genes in THP-1 monocytic cells exposed to sensitizers and nonsensitizers and to investigate if such genes could be reliable markers for an in vitro predictive method for the identification of skin sensitizing chemicals. Changes in expression of 35 genes in the THP-1 cell line following treatment with chemicals of different sensitizing potential (from nonsensitizers to extreme sensitizers) were assessed using real-time PCR. Verification of 13 candidate genes by testing a large number of chemicals (an additional 22 sensitizers and 8 nonsensitizers) revealed that prediction of contact sensitization potential was possible based on evaluation of changes in three genes: IL8, HMOX1 and PAIMP1. In total, changes in expression of these genes allowed correct detection of sensitization potential of 21 out of 27 (78%) test sensitizers. The gene expression levels inside potency groups varied and did not allow estimation of sensitization potency of test chemicals. Results of this study indicate that evaluation of changes in expression of proposed biomarkers in THP-1 cells could be a valuable model for preliminary screening of chemicals to discriminate an appreciable majority of sensitizers from nonsensitizers.     

In vitro sensitivity of granulo-monocytic progenitors as a new toxicological cell system and endpoint in the ACuteTox Project

The ACuteTox Project (part of the EU 6th Framework Programme) was started up in January 2005. The aim of this project is to develop a simple and robust in vitro strategy for prediction of human acute systemic toxicity, which could replace animal tests used for regulatory purposes. Our group is responsible for the characterization of the effect of the reference chemicals on the hematopoietic tissue. CFU-GM assay based on the culture of human mononuclear cord blood cells has been used to characterize the effects of the selected compounds on the myeloid progenitors. Previous results have shown the relevance of the CFU-GM assay for the prediction of human acute neutropenia after treatment of antitumoral compounds, and this assay has been recently approved by the ECVAM's Scientific Advisory Committee. Among the compounds included in the study there were pharmaceuticals, environmental pollutants and industrial chemicals. Eleven out of 55 chemicals did not show any cytotoxic effect at the maximum concentration tested. The correlation coefficients of CFU-GM IC50, IC70 and IC90 values with human LC50 values (50% lethal concentration calculated from time-related sublethal and lethal human blood concentrations) were 0.4965, 0.5106 and 0.5142 respectively. Although this correlation is not improve respect to classical in vitro basal cytotoxicity tests such as 3T3 Neutral Red Uptake, chemicals which deviate substantially in the correlation with these assays (colchicine, digoxin, 5-Fluorouracil and thallium sulfate) fitted very well in the linear regression analysis of the CFU-GM progenitors. The results shown in the present study indicate that the sensitivity of CFU-GM progenitors correlates better than the sensitivity of HL-60 cells with human LC50 values and could help to refine the predictability for human acute systemic toxicity when a given chemical may affect to the hematopoietic myeloid system.     

First insights in the metabolism of phosphate flame retardants and plasticizers using human liver fractions

Phosphate flame retardants and plasticizers (PFRs) are additives used in a wide range of polymers. Important representatives, such as tris(2-butoxyethyl) phosphate (TBOEP), triphenyl phosphate (TPHP), tris(2-chloroethyl) phosphate (TCEP), tris(1-chloro-2-propyl) phosphate (TCIPP), tris(1,3-dichloro-2-propyl) phosphate (TDCIPP), have been found in the indoor environment at high levels. Biotransformation of these PFRs needs to be investigated because it can be a major determinant of their bioavailability and toxicity in humans. TBOEP, TPHP, TCEP, TCIPP and TDCIPP were incubated with human liver S9 fraction and microsomes. Supernatants were analyzed using a liquid chromatography coupled to a quadrupole-time-of-flight mass spectrometer. Chromatograms were scanned for the presence of Phase-I and Phase-II metabolites and tentatively identified based on mass accuracy of the molecular formula, isotopic pattern, and MS/MS spectra. The two major metabolites of TBOEP were products of O-dealkylation and of hydroxylation, respectively. TPHP was mainly transformed to its diester metabolite by O-dearylation and to a hydroxylated metabolite. TCEP was poorly metabolized into its diester and a product of oxidative dehalogenation. The major metabolite of TCIPP was a product of oxidative dehalogenation. TDCIPP was mainly transformed into its diester and a glutathione S-conjugate. The metabolites identified in the present study are candidate biomarkers for future human biomonitoring studies.     

Replacement of in vivo acute oral toxicity studies by in vitro cytotoxicity methods: opportunities, limits and regulatory status

The development of a new medicinal product is a long and costly process in particular due to the regulatory requirements for quality, safety and efficacy. There is a common interest to increase the efficiency of drug development and to provide new, better quality medicinal products much faster to the public. One possible way to economize time and costs, as well as to consider animal protection issues, is to introduce new alternative methods into non-clinical toxicity testing. Currently, animal tests are mandatory for the evaluation of acute toxicity of chemicals and new drugs. The replacement of the in vivo tests by alternative in vitro assays would offer the opportunity to screen and assess numerous compounds at the same time, to predict acute oral toxicity and thus accelerate drug development. Moreover, the substitution of in vivo tests by in vitro methods shows a proactive pursuit of ethical and animal welfare issues. Importantly, the implementation of in vitro assays for acute oral toxicity would require the establishment of common test guidelines across the EU, USA and Japan, i.e., the regions of ICH (International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use). Presently, alternative in vitro tests are being investigated internationally. Yet, in order to achieve regulatory acceptance and implementation of in vitro assays, convincing results from validation studies are required. In this review, we discuss the current regulatory status of acute oral toxicity testing and point out achievements of alternative methods. We describe the application of in vitro tests, correlating in vitro with in vivo data. The use of in vitro data to predict in vivo acute oral toxicity is analyzed using the Registry of Cytotoxicity, an official independent database. We have then analyzed opportunities and drawbacks for future implementation of in vitro test methods, with particular focus on industrial use.     

Transungual delivery of ketoconazole using novel lacquer formulation

Onychomycosis, a common fungal infection of the nail, can have a substantial impact on quality of life. The success of topical therapy for onychomycosis depends on effective penetration, which can be enhanced using an appropriate delivery method. This study evaluated the effectiveness of a novel topical lacquer on enhancing [¹⁴C]-ketoconazole penetration by comparing nail absorption, nail distribution, and nail penetration of [¹⁴C]-ketoconazole dissolved in the novel lacquer versus a commercial ketoconazole cream. Using the in vitro finite dose model, the formulations were applied daily to human nail plates for 7 days. Drug absorption was measured by monitoring rate of appearance in each nail layer and the supporting bed. After the multiple day treatment, cumulative concentrations of ketoconazole formulated in novel lacquer in the deep nail layer and the nail bed were significantly greater than cumulative concentrations of commercial ketoconazole (p < 0.05), as well as several orders of magnitude greater than the minimal inhibitory concentration (MIC) deemed necessary to inhibit the growth of causative dermatophytic and yeast species. These results suggest that this novel ketoconazole lacquer has the potential to be an effective topical treatment for onychomycosis.     

Cane toad toxicity: An assessment of extracts from early developmental stages and adult tissues using MDCK cell culture

Extracts of the cane toad (Bufo [Chaunus] marinus) adversely affected the growth of Mardin-Darby canine kidney (MDCK) cells during culture. In a similar manner to ouabain treatment, application of toad extracts over a 24 h period resulted in high levels of cytotoxicity, as indicated by cell detachment, increased membrane permeability and loss of mitochondrial function. Cell viability and growth were unchanged for controls (PBS) and increased with the application of Limnodynastes peronii tadpole and adult frog extracts. We investigated the general cytotoxicity of cane toad developmental stages (e.g. eggs, embryonic hatchlings, tadpoles and post-metamorphic toadlets) as well as selected adult tissues (e.g. skin, gut, liver). Our results showed that pre-metamorphic cane toad aqueous extracts used at 1 mg/ml on MDCK cells generated cytotoxicity levels comparable to ouabain treatment (3 μM). After normalisation, extracts from 2-3-month-old toadlets appeared less toxic than pre- and early metamorphic stages. Adult tissues revealed a gradient of cytotoxicity levels ranging from non-toxic brain to highly toxic dorsal skin extracts.     

Development of mesophasic microreservoir-based transdermal drug delivery system of propranolol

The mesophasic microreservoir comprises lyotrophic liquid crystals. The liquid crystals were prepared of Brij-35, cetosteryl alcohol and propranolol and evaluated for parameters viz. anisotropy, size and size distribution and drug entrapment efficiency. Subsequent to this liquid crystals based transdermal drug delivery system (TDS) was prepared by incorporating liquid crystals in previously prepared matrix based transdermal patch and evaluated for stability studies like temperature, humidity and aging. The system was also studied for tensile strength, moisture content, water vapor transmission, drug content, anisotropy and In vitro drug release studies.     

Development and evaluation of cefadroxil drug loaded biopolymeric films based on chitosan-furfural schiff base

Cefadroxil drug loaded biopolymeric films of chitosan-furfural schiff base were prepared by reacting chitosan with furfural in presence of acetic acid and perchloric acid respectively for the external use. Prepared films were evaluated for their strength, swelling index, thickness, drug content, uniformity, tensile strength, percent elongation, FTIR spectral analysis and SEM. The results of in vitro diffusion studies revealed that the films exhibited enhanced drug diffusion as compared to the films prepared using untreated chitosan. The films also demonstrated good to moderate antibacterial activities against selective gram positive and gram negative bacteria.