Valentina Bergamante

Fast dispersible/slow releasing ibuprofen tablets

Eight formulations were developed containing ibuprofen in the form of orally disintegrating tablets. To prevent bitter taste and side effects of the drug, the drug was associated with Phospholipon 80H, a saturated lecithin, by wet granulation. The granules were then coated using different film forming agents (Kollicoat SR 30, Amprac 01, Kollidon 90F, Eudragit RD 100) obtaining four lots 1-4. Coated granules were then formulated with a sweetener (Aspartame), a mannitol-based diluent (Pearlitol SD 200) and Kollidon CL (1-4K) or Explotab (1-4E) were added as superdisintegrants and compacted under low compression force. The eight lots of tablets, 1-4K and 1-4E, were assessed if suitable as oral disintegrating tablets by determination of a range of technological parameters. Wetting and disintegregation time matched with the requirements of EP IV Ed., for almost all these formulations. Dissolution profiles suggested that the combined action of the hydrophobic lecithin and the coating delay the release of the drug from tablets with respect to when it is free or in the form of simple granules. By an appropriate combination of excipients it was thus possible to obtain orally disintegrating tablets and a delayed release of ibuprofen using simple and conventional techniques.

Design and evaluation in vitro of controlled release mucoadhesive tablets containing chlorhexidine.

ABSTRACT This investigation deals with the development of buccal tablets containing chlorhexidine (CHX), a bis-bis-guanide with antimicrobial and antiseptic effects in the oral cavity, and able to adhere to the buccal mucosa to give local controlled release of drug. A mucoadhesive formulation was designed to swell and form a gel adhering to the mucosa and controlling the drug release into the oral cavity. Some batches of tablets were developed by direct compression, containing different amounts of hydroxypropylmethylcellulose (HPMC) and carbomer; changing the amount ratio of these excipients in formulations, it is possible easily modulate the mucoadhesive effect and release of drug. The in vitro tests were performed using the USP 26/NF paddle apparatus, a specifically developed apparatus, and a modified Franz diffusion cells apparatus. This last method allows a simultaneous study of drug release rate from the tablets and drug permeation through the buccal mucosa. Similar tests have also been carried out on a commercial product, Corsodyl gel®, in order to compare the drug release control of gel with respect to that of the mucoadhesive tablet, as a formulation for buccal delivery of CHX. While the commercial formulation does not appear to control the release, the formulation containing 15% w/w methocel behaves the best, ensuring the most rapid and complete release of the drug, together with a negligible absorption of the active agent as required for a local antiseptic action in the oral cavity.

Solubility and Transdermal Permeation Properties of a Dehydroepiandrosterone Cyclodextrin Complex from Hydrophilic and Lipophilic Vehicles

The permeation ability of a compound is due principally to its concentration in the vehicle and to its aptitude to cross the stratum corneum of the skin. In this work ex-vivo permeation studies on newly developed formulations containing dehydroepiandrosterone (DHEA) were carried out to investigate vehicles that increase drug permeation through the skin. To enhance the solubility of DHEA, its complex form with α-cyclodextrin was used. In addition, the two forms (pure drug and complex form) were introduced in hydrophilic (water), lipophilic (paraffin oil), and microemulsion vehicles to evaluate the synergic effect of cyclodextrins and microemulsion vehicles on solubility and permeation. From the results, DHEA solubility is notably conditioned by the type of the vehicle used: the highest solubilities (both for pure and complex drug forms) were obtained with microemulsion, followed by paraffin oil and water. Moreover, in all the studied vehicles, the c-DHEA was more soluble than DHEA. Permeation profile fluxes showed very interesting differences. That reflect the varying drug forms (pure drug and complex form), vehicles used, and drug concentrations in the vehicles. The major flux was obtained in complex of DHEA with α-cyclodextrins in the microemulsion vehicle. Therefore, this type of vehicle and drug form would be very useful in the development of a topical formulation containing DHEA.

Mucoadhesive Gels Designed for the Controlled Release of Chlorhexidine in the Oral Cavity

This study describes the in vitro/ex vivo buccal release of chlorhexidine (CHX) from nine mucoadhesive aqueous gels, as well as their physicochemical and mucoadhesive properties: CHX was present at a constant 1% w/v concentration in the chemical form of digluconate salt. The mucoadhesive/gel forming materials were carboxymethyl- (CMC), hydroxypropylmethyl- (HPMC) and hydroxypropyl- (HPC) cellulose, alone (3% w/w) or in binary mixtures (5% w/w); gels were tested for their mucoadhesion using the mucin method at 1, 2 and 3% w/w concentrations. CHX release from different formulations was assessed using a USP method and newly developed apparatus, combining release/permeation process in which porcine mucosa was placed in a Franz cell. The combination of HPMC or HPC with CMC showed slower drug release when compared to each of the individual polymers. All the systems proved suitable for CHX buccal delivery, being able to guarantee both prolonged release and reduced transmucosal permeation. Gels were compared for the release of previously studied tablets that contained Carbopol and HPMC, alone or in mixture. An accurate selection and combination of the materials allow the design of different pharmaceutical forms suitable for different purposes, by simply modifying the formulation compositions.

Mucoadhesive Tablets for Buccal Administration Containing Sodium Nimesulide

The possibility of improving the flux of nimesulide across the buccal mucosa using the drug in the form of a sodium salt was investigated in our study. The salt form may increase to flux across buccal membrane, starting from a suspension; its lower permeation coefficient is compensated by a higher concentration gradient. The salt was inserted into a mucoadhesive tablet for buccal administration. The tablets were designed to prevent the loss of the drug into the saliva by means of a protective layer and placed on the area not in contact with the mucosa. Ten volunteers were used. The in vitro release from mucoadhesive tablets was examined through a porcine buccal mucosa, using a standard Franz cell, modified for present purposes. The advantages of a higher concentration gradient for the flux, related to a higher solubility of the salt, and to a sufficiently high permeation coefficient of the drug, despite the ionized form, could not be completely exploited, because the composition of the formulation destroys the chemical form of the drug.

Effect of Vehicles on Topical Application of Aloe Vera and Arnica Montana Components

In this study two types of gels and microemulsions are investigated for their ability to dissolve, release, and induce the permeation of helenalin, a flavonoid responsible for the anti-inflammatory activity of arnica montana extract, and aloin, an anthrone-C-glucosyls with antibacterial activity present in aloe vera extract. The release of these agents from each vehicle was followed by HPLC, and transcutaneous permeation was examined using a modified Franz cell and a porcine skin membrane. The study showed that a microemulsion can be a good vehicle to increase the permeation of helenalin, while the gel formulation, containing Sepigel 305, proved able to reduce the release and permeation of aloin, with a consequent activity limited to the surface of application, without any permeation. This is in accordance with the necessity to avoid this process, since human skin fibroblasts can metabolize absorbed aloin into a structurally related compound that increases the sensitivity of skin to ultraviolet light.

The role of excipients in the control of dehydroepiandrosterone inclusion complex delivery

AimThe aim of this study was to develop systems containing dehydroepiandrosterone (DHEA), in the form of an inclusion complex with α-cyclodestrin (c-DHEA), which are able to change the release profile of the hormone according to time and excipient composition.MethodTwenty-five formulations were prepared containing DHEA (prasterone) in the chemical form of an inclusion complex with α-cyclodextrin (57.3% w/w). The drug was mixed with three different excipient systems: the first ‘fast’ one was a mixture of two disintegrants (microcrystalline cellulose and sodium carboxymethyl starch at prefixed 4.15 weight ratio); the second ‘gelling’ excipient contained two gel-forming agents (high viscosity hydroxypropyl methylcellulose and cross-linked polyvinyl pyrrolidone) at three weight ratios: 0.31, 1.00, and 2.45; and the third type of ‘binary’ mixture was prepared by combining ‘fast’ and ‘gelling’ systems at three weight ratios: 1:2, 1:1, and 2:1. Tablets were prepared by direct compression or after wet granulation of these formulations.Results’Fast’ tablets induced a rapid release of the drug while ‘gelling’ tablets were found to modify the release, according to composition. A profile, characterized by an initial phase of rapid drug release, followed by a period of slower release is achieved with series 1:1 tablets. Series 1:2 tablets provide linear release of the drug; while an undifferentiated profile was found for series 2:1 tablets.ConclusionDifferent release mechanisms and the control of drug release were obtained by using DHEA in its inclusion complex and varying the weight ratios of the excipients.

Enhancement of Oleyl Alcohol Anti Tumor Activity through Complexation in Polyvinylalcohol Amphiphilic Derivatives

Oleyl alcohol was complexed with new amphiphilic polyvinylalcohol derivatives with the aim of increasing its aqueous solubility, thus improving bioavailability and favoring its antitumor activity. Water-soluble amphiphilic polymers were prepared by polyvinyl alcohol (PVA) substitution with oleyl chains through a succinyl spacer at 2% and 3% substitution degree. The complexes were obtained by spray-drying hydroalcoholic solutions of the substituted polymers and free oleyl alcohol at different weight ratios (3:1; 5:1; 10:1 w/w). The main physicochemical characteristics of the complexes were analyzed and correlated to the cytotoxic activity of oleyl alcohol toward tumor cell lines. The complexes strongly increased the aqueous solubility of oleyl alcohol and provided oleyl alcohol release in the presence of extractive conditions (simulating in vivo absorption). The complexes obtained by 10:1 polymer:fatty alcohol weight ratio offered higher release rates than the 5:1 and 3:1 ratios, respectively. Complexation also increased oleyl alcohol cytotoxicity toward tumor cells due to increased availability of the active molecule in the aqueous phase. Pure polymers were found to be biocompatible and no toxic effect was detected up to the highest concentration used in the present study (500 μ g/ml). The complexation of oleyl alcohol with the polymers analyzed here efficiently increased the availability of the fatty alcohol in aqueous environment. The enhanced cytotoxicity toward tumor cells of the complexed oleyl alcohol and the polymer biocompatibility make these amphiphilic PVA derivatives interesting candidates for soluble pharmaceutical formulations containing hydrophobic drugs whose therapeutic potential is often underestimated due to unsuitable levels of their aqueous solubilization.

Micellar complexes of all-trans retinoic acid with polyvinylalcohol-nicotinoyl esters as new parenteral formulations in neuroblastoma

All-trans-retinoic acid (ATRA) is now included in many antitumor therapeutic schemes for the treatment of acute promyelocytic leukemia, Kaposi’s sarcoma, head and neck squamous cell carcinoma, ovarian carcinoma, bladder cancer, and neuroblastoma. Unfortunately, its poor aqueous solubility hampers its parenteral formulation, whereas oral administration of ATRA is associated with progressively diminishing drug levels in plasma, which is related to induction of retinoic acid-binding proteins and increased drug catabolism by cytochrome P450-mediated reactions. An ATRA formulation, obtained by complexation of the drug into polymeric micelles, might be suitable for parenteral administration overcoming these unwanted effects. To this purpose, amphiphilic polymers were prepared by polyvinylalcohol (PVA) partial esterification with nicotinoyl moieties and their functional properties evaluated with regard to ATRA complexation. The physicochemical characteristics of the polymers and the complexes were analyzed by 1H-NMR, Dynamic Light Scattering (DLS), Capillary Electophoresis (CE), and were correlated with the complex ability to improve the drug solubilization and release the free drug in an aqueous environment. Subsequently, the best complex, providing the highest ATRA solubilization and release, was evaluated in vitro to test its citotoxicity towards neuroblastoma cell lines. The PVA substitution degree calculated from 1H-NMR was found to be 5.0%, 8.2%, 15.3% (nicotinoyl moiety:PVA monomer molar ratio), while capillary electrophoresis analysis on the complexes revealed that the drug loadings were 0.95%, 1.20%, 4.76% (ATRA:polymer w:w) for PVA substitution degrees of 5.0%, 8.2%, and 15.3%, respectively. Complexation strongly increased ATRA aqueous solubility, which reached 1.20 ± 0.25 mg/mL. The DLS measurements of the polymers and the complexes in aqueous solutions revealed mean sizes always below 400 nm, low polydispersity (min 0.202 ± 0.013, max 0.450 ± 0.032), and size almost unaffected by concentration. Drug fractional release did not exceed 8% after 48 h. The cytotoxicity studies against neuroblastoma cell lines outlined a significant growth inhibition effect of complexed ATRA with respect to free ATRA. These data suggest that the systems analyzed may be suitable carriers for parenteral administration of ATRA and other hydrophobic antitumor drugs, where the carriers are required to improve drug aqueous solubility and delay drug release almost after their accumulation in solid tumors.