Your search keyword '"Methoxsalen chemistry"' showing total 7 results

1. Enhancing the solubility of natural compound xanthotoxin by modulating stability via cocrystallization engineering.

Author

Chen JY, Wu H, Guo CY, Zhu B, and Ren GB

Subjects

4-Aminobenzoic Acid chemistry, Crystallization methods, Crystallography, X-Ray methods, Drug Stability, Hydrogen Bonding, Oxalic Acid chemistry, Powder Diffraction methods, Powders chemistry, X-Ray Diffraction methods, Methoxsalen chemistry, Solubility drug effects

Abstract

A comprehensive cocrystal study for the insoluble natural pharmaceutical compound xanthotoxin (XT) was conducted, in which xanthotoxin-para aminobenzoic acid (XT-PABA) and xanthotoxin-oxalic acid (XT-OA) cocrystals were obtained. The xanthotoxin cocrystals were characterized by powder X-ray diffraction, thermal analysis, and FT-IR spectra, and the crystal structures were determined by single-crystal X-ray diffraction. Crystal structures and thermal analysis showed that XT-OA was more stable than XT-PABA. Energy framework calculation indicated that H-bond and π···π interactions generated in XT-OA were stronger than that in XT-PABA and xanthotoxin. The powder dissolution experiments of xanthotoxin and its cocrystals suggested the XT-OA cocrystal might be applied as an alternative formulation of API, on account of its enhanced solubility and stability in the hydrochloric acid buffer solution (pH 1.2). The cocrystallization engineering can prolong the enhanced apparent solubility via modulating the stability., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

2. Nanoemulsion containing 8-methoxypsoralen for topical treatment of dermatoses: Development, characterization and ex vivo permeation in porcine skin.

Author

Oliveira CA, Gouvêa MM, Antunes GR, Freitas ZMF, Marques FFC, and Ricci-Junior E

Subjects

Administration, Cutaneous, Animals, Clove Oil administration & dosage, Clove Oil chemistry, Clove Oil pharmacokinetics, Drug Compounding, Drug Delivery Systems, Drug Stability, Emulsions, Methoxsalen chemistry, Methoxsalen pharmacokinetics, Nanoparticles chemistry, Permeability, Photosensitizing Agents chemistry, Photosensitizing Agents pharmacokinetics, Poloxamer administration & dosage, Poloxamer chemistry, Poloxamer pharmacokinetics, Skin Absorption, Solubility, Swine, Methoxsalen administration & dosage, Nanoparticles administration & dosage, Photosensitizing Agents administration & dosage, Skin metabolism

Abstract

Oral therapy with 8-methoxypsoralen (8-MOP) may cause major side effects, whereas the topical treatment might not be much effective due to the low penetration induced by typical formulations. Therefore, the objectives of this work are the development and characterization of a nanoemulsion (NE) containing 8-MOP together with an ex vivo permeation study, monitored by a validated HPLC-Fluo method, to determine the amount of drug retained in viable skin (epidermis (E) and dermis (D)) and in stratum corneum (SC). The optimized conditions for NE formulation were achieved by full factorial designs (2 5 and 3 2 ): 60 s and 60% of ultrasound time and potency, respectively; 10 mL of final volume; 2% v/v of oil phase (clove essential oil); and 10% m/v of Poloxamer 407. The NE showed mean droplet diameter of 24.98 ± 0.49 nm, polydispersity index (PDI) of 0.091 ± 0.23, pH values of 6.54 ± 0.06, refractive index of 1.3525 ± 0.0001 and apparent viscosity of 51.15 ± 3.66 mPa at 20 °C. Droplets with nanospherical diameters were also observed by transmission electron microscopy (TEM). Ex vivo permeation study showed that 8.5% of the applied 8-MOP dose permeated through the biological membranes, with flux (J) of 1.35 μg cm -2  h -1 . The drug retention in E + D and in SC was 10.15 ± 1.36 and 1.95 ± 0.71 µg cm -2 , respectively. Retention in viable skin induced by the NE was almost two-fold higher than a compounded cream (5.04 ± 0.30 μg cm -2 ). These results suggested that the developed NE is a promising alternative for 8-MOP topical therapy when compared to commercial formulations., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

3. Enhancement of 8-methoxypsoralen topical delivery via nanosized niosomal vesicles: Formulation development, in vitro and in vivo evaluation of skin deposition.

Author

Kassem AA, Abd El-Alim SH, and Asfour MH

Subjects

Animals, Drug Carriers chemistry, Drug Delivery Systems, Drug Liberation, Drug Stability, Hydrogel, Polyethylene Glycol Dimethacrylate chemistry, Hydrogen-Ion Concentration, Liposomes administration & dosage, Liposomes pharmacokinetics, Liposomes ultrastructure, Male, Methoxsalen administration & dosage, Particle Size, Rats, Rheology, Liposomes chemistry, Methoxsalen chemistry, Methoxsalen pharmacokinetics, Skin Absorption

Abstract

The aim of the present study is to enhance the skin penetration and deposition of 8-methoxypsoraln (8-MOP) via niosomal vesicles to increase its local efficacy and safety. 8-MOP niosomes were prepared by the thin film hydration method using Span 60 or Span 40 along with cholesterol at five different molar ratios. The obtained vesicles revealed high entrapment efficiencies (83.04-89.90%) with nanometric vesicle diameters (111.1-198.8nm) of monodisperse distribution (PDI=0.145-0.216), zeta potential values <-48.3mV and spherical morphology under transmission electron microscopy. Optimized niosomal formulations depicted a biphasic in vitro release pattern in phosphate buffer (pH 5.5)/ethanol (7:3v/v) and displayed good physical stability after storage for 6 months at room (20-25°C) and refrigeration (4-8°C) temperatures. The two optimized formulations were incorporated in 5% sodium carboxy methylcellulose based hydrogel matrix which showed optimum pH values (7.37-7.39), pseudoplastic with thixotropic rheological behavior and more retarded 8-MOP release, by 23.82 and 14.89%, compared to niosomal vesicles after 24h. In vitro drug permeation and deposition studies, using rat skins, revealed promoted penetration and accumulation of 8-MOP after 8h. The skin penetration was further confirmed in vivo by confocal laser scanning microscopy, after 2h application period using rhodamine-loaded niosomal hydrogels compared to plain rhodamine hydrogel, as a florescence marker. Therefore, enhanced permeation and skin deposition of 8-MOP delivered by niosomes may help in improving the efficacy and safety of long-term treatment with 8-MOP., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2017

4. Transdermal delivery of 8-methoxypsoralene mediated by polyamidoamine dendrimer G2.5 and G3.5--in vitro and in vivo study.

Author

Borowska K, Wołowiec S, Głowniak K, Sieniawska E, and Radej S

Subjects

Administration, Cutaneous, Animals, Dendrimers chemistry, Dendrimers metabolism, Drug Carriers chemistry, Drug Carriers metabolism, In Vitro Techniques, Male, Membranes, Artificial, Methoxsalen chemistry, Methoxsalen metabolism, Permeability, Photosensitizing Agents chemistry, Photosensitizing Agents metabolism, Polyvinyls chemistry, Rats, Rats, Hairless, Rats, Wistar, Skin metabolism, Skin Absorption, Swine, Dendrimers administration & dosage, Drug Carriers administration & dosage, Methoxsalen administration & dosage, Photosensitizing Agents administration & dosage

Abstract

In this work, we have focused on 8-methoxypsoralene (8-MOP) complexed with G2.5 and G3.5 poly(amido amine) (PAMAM) dendrimers. The purpose of this study was to investigate the efficacy of half-generation G2.5 and G3.5 PAMAM dendrimers conjugated with 8-MOP for delivery of 8-MOP in vitro study through polivinyldifluoride membrane (PVDE) and prepared pig ear skin (PES) using Franz diffusion and in vivo study through the skin of experimental animals (hairless rat skin). The tissue concentration of 8-MOP in hairless rat skin was analyzed by high performance liquid chromatography (HPLC) after 1 and 2 h. Detailed distribution of 8-MOP in skin layers and cellular structures were analyzed using laser scanning microscopy (CLSM). In vitro and in vivo studies showed that half-generation G2.5 and G3.5 PAMAM dendrimers are able to facilitate transdermal delivery of 8-MOP. G2.5 PAMAM dendrimer appeared to be more effective 8-MOP penetration enhancer than G3.5 PAMAM dendrimer, but in vivo the differences are not statistically significant. The concept of using G2.5 and G3.5 PAMAM dendrimers as carriers seems to be a promising method for the delivery of 8-MOP for PUVA (psoralen-UV-A) therapy., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

5. Effect of polyamidoamine dendrimer G3 and G4 on skin permeation of 8-methoxypsoralene--in vivo study.

Author

Borowska K, Wołowiec S, Rubaj A, Głowniak K, Sieniawska E, and Radej S

Subjects

Administration, Cutaneous, Animals, Chemistry, Pharmaceutical, Chromatography, High Pressure Liquid, Dendrimers administration & dosage, Dendrimers chemistry, Drug Compounding, Male, Methoxsalen administration & dosage, Methoxsalen chemistry, Microscopy, Confocal, Nanotechnology, PUVA Therapy, Permeability, Photosensitizing Agents administration & dosage, Photosensitizing Agents chemistry, Rats, Rats, Wistar, Skin metabolism, Technology, Pharmaceutical methods, Dendrimers pharmacology, Drug Carriers, Methoxsalen pharmacokinetics, Photosensitizing Agents pharmacokinetics, Skin drug effects, Skin Absorption drug effects

Abstract

In the present study we have assessed the ability of (PAMAM) dendrimers G3 and G4 to facilitate transdermal delivery of 8-methoxypsoralen (8-MOP) in vivo. In vitro study using Franz diffusion cell revealed an enhanced transdermal flux for 8-MOP in complex with G3 and G4 dendrimer in relation to standard 8-MOP solution. In present study in vivo skin permeation potential of 8-MOP complex with G3 and G4 PAMAM dendrimer was assessed using confocal laser scanning microscopy (CLSM), which revealed an enhanced permeation of the 8-MOP to the deeper layers of the skin and significantly higher concentration in comparison with standard 8-MOP solution. Skin tissue 8-MOP concentration, evaluated by HPLC indicates that G3 and G4 PAMAM application significantly increase 8-MOP skin deposition in comparison with standard 8-MOP solutions after 1 and 2h. G4 appeared to be a more effective 8-MOP penetration enhancer than G3 PAMAM. Our results suggest the feasibility of G3 and G4 PAMAM dendrimers for transdermal delivery of 8-MOP resulting in better skin permeation and higher concentration of 8-MOP in epidermis and dermis of the drug that could help to improve effectiveness and safety of PUVA therapy., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

6. PAMAM dendrimers as solubilizers and hosts for 8-methoxypsoralene enabling transdermal diffusion of the guest.

Author

Borowska K, Laskowska B, Magoń A, Mysliwiec B, Pyda M, and Wołowiec S

Subjects

Administration, Cutaneous, Animals, Dendrimers administration & dosage, Dendrimers chemistry, Diffusion drug effects, Drug Carriers administration & dosage, Drug Carriers chemistry, Methoxsalen administration & dosage, Methoxsalen chemistry, Permeability, Solubility, Swine, Dendrimers pharmacokinetics, Drug Carriers pharmacokinetics, Methoxsalen pharmacokinetics, Skin Absorption physiology

Abstract

PAMAM dendrimers form host-guest complexes with 8-methoxypsoralene (8-MOP) - the photosensitizer for PUVA therapy. The stoichiometry of complexes was studied by (1)H NMR spectroscopy in solution and by differential scanning calorimetry in neat mixtures containing 8-MOP and dendrimers of generations G2.5, G3, G3.5, and G4. The dendrimers showed solubilization effect for 8-MOP resulting in increase of 8-MOP concentration in methanol up to 15 molecules of 8-MOP per G2.5 and G3 and 30 molecules of 8-MOP per G3.5, and G4. Isolation of oily host-guest complexes containing 3 or 7 molecules of 8-MOP per G3 and G4, respectively corroborate well with DSC results; glass transition temperature of neat host-guest complexes increases with number of host molecules in comparison with G3 or G4, until the capacity of host is exceeded. The oily host-guest complexes of stoichiometry 3:1 and 7:1 of 8-MOP to G3 and G4, respectively are well soluble in water. The 3:1 host-guest complexes diffused slowly through polyvinyldifluoride and pig ear skin membranes, when released from o/w emulsion. The host-guest complex 8-MOP-G3 was proposed as convenient formulation for psoralene skin administration in PUVA therapy., (Copyright 2010 Elsevier B.V. All rights reserved.)

Published

2010

7. Studies on mechanism of 8-methoxypsoralen-DNA interaction in the dark.

Author

Arabzadeh A, Bathaie SZ, Farsam H, Amanlou M, Saboury AA, Shockravi A, and Moosavi-Movahedi AA

Subjects

Animals, Binding Sites physiology, Calorimetry methods, Cattle, Dose-Response Relationship, Drug, Methoxsalen chemistry, Thermodynamics, DNA metabolism, Darkness, Methoxsalen metabolism

Abstract

The interaction of 8-methoxypsoralen (8-MOP) with calf thymus DNA was studied in darkness at 25 degrees C and pH 7.4. The enthalpy curve for 8-MOP-DNA interaction was obtained by isothermal titration calorimetry and showed a two-step process for the interaction. According to the spectrophotometric data, it was suggested that some compaction may occur in the DNA structure at higher [8-MOP](t)/[DNA] ratio. Using the fluorescence quenching data, the Scatchard analysis was performed for 8-MOP-DNA interaction at the extended ranges of drug concentration. The results indicated that the first set of binding sites was occupied by 1 mol of drug bound per near eight base pairs of DNA. Also 8-MOP caused the quenching of the fluorescence emission of DNA-ethidium bromide complex. The Scatchard analysis of these data indicated the non-competitive manner for quenching. A non-displacement based quenching mechanism has been suggested for this behavior. The circular dichroism spectra also confirmed the non-intercalative binding of 8-MOP at higher concentrations accompanied by some conformational changes in DNA structure. It has been suggested that at low drug load, 8-MOP binds to DNA as an intercalator, which is an endothermic process, whereas at higher ratios of [8-MOP](t)/[DNA], it binds to the outside of DNA, probably in the minor groove and causes some compaction in DNA, which is the exothermic process.

Published

2002