Humans ; Nanoparticles ; toxicity ; Skin ; drug effects ; Skin Absorption

OBJECTIVETo study the factors that affect mucosal absorption of gardenia extract.

METHODTake vitro frog skin as a model to study the vitro mucosal permeation. The impacts of the osmotic pressure and the pH value of permeation medium on the Papp of the Jasminoidin were studied, and the effect of frog skin on the stability of Jasminoidin was investigated also.

RESULTThe Papp of Jasminoidin were (0.53 +/- 0.01), (0.21 +/- 0.05), (0.44 +/- 0.12), (0.42 +/- 0.13), (0.26 +/- 0.03) cm x min(-1) by using the normal saline (pH 6.88), pure water, 1.8 % NaCl solution, normal saline (pH 4.05) and normal saline (pH 10.05) as permeation medium for each. The accumulated permeation rate was (55.69 +/- 9.81)% by 12 h, using normal saline as permeation medium respectively, and there was no obvious time lag. Jasminoidin began to degrade around 8 h by affectedof frog skin, the constant of degradation rate (K) was 1.999, and the t1/2 was 0.347 h.

CONCLUSIONThe mucosal permeability of gardenia extract by using the vitro model of frog skin is good, and consistent with zero level absorption process. The osmotic pressure and pH value significantly affected the permeation and the isotonic and partial neutral permeation medium are more conducive to the permeation and absorption of Jasminoidin. The degradation effect of frog skin to the Jasminoidin will not affect mucosal permeation research. In vitro model of frog skin is a suitable way to simulate mucosal permeation process of the gardenia extract.

Gardenia ; chemistry ; Hydrogen-Ion Concentration ; Mucous Membrane ; drug effects ; physiology ; Permeability ; drug effects ; Plant Extracts ; chemistry ; pharmacology ; Skin ; drug effects ; Skin Absorption ; drug effects ; physiology ; Solubility

L_9(3~4) orthogonal experiment design was used to optimize the preparation of the patches,and investigate its affecting factors and skin irritation. Eugenol was taken as the index component to study the release behavior in vitro and percutaneous penetration of Cangai oil transfersomes patches by HPLC.The results showed that the optimal prescription for preparing Cangai oil transfersomes patches were Eudragit E100 0.6 g, succinic acid 0.08 g,triethyl citrate 0.25 g,glycerol 0.2 g.Patches prepared by the preferred preparation had a flat appearance without obvious bubbles.The initial adhesion was 18.33±2.52, the stickiness was(30.01±2.45) min,and the peel strength was(5.62±0.95) kN·m~(-1).The results of affecting factors experiment showed the order of factors affecting its adhesion was humidity>temperature>lighting,and the skin irritation test results showed no significant skin irritation after 24 h of single administration. The results of drug release behavior in vitro showed that the release and the percutaneous penetration of both Cangai oil patches and Cangai oil transfersomes patches conformed to the Higuchi equation.The release amount of eugenol were 80.66% and 82.25% at 72 h, with no significant difference. The cumulative permeation area of eugenol per unit area reached(0.195 6±0.065 9),(0.131 0±0.045 5) mg·cm~(-2) at 72 h, with significant differences(P<0.05).The experiment results proved that the preparation process of Cangai oil transfersomes patches was stable,and the prepared patches had a good adhesion. At the same time,the preparation of transfersomes patches could alleviate and control the release of the drug to a certain extent, and provide a certain experimental basis for clinical pediatric drug safety.
Administration, Cutaneous ; Drug Carriers ; Drug Liberation ; Humans ; Plant Oils/pharmacology* ; Polymethacrylic Acids ; Skin/drug effects* ; Skin Absorption ; Transdermal Patch

OBJECTIVETo prepare berberine microemulsion, and to investigate its properities and the absorption character in rat intestine in situ.

METHODThe optimum formulation of the blank microemulsion selected by pseudo tertiary phase diagrams and the berberine microemulsion was prepared based on the blank microemulsion. The viscosity, conductance, refraction rate and particle size of berberine microemulsion were surveyed. An in situ rat perfusion method was used to investigate the intestinal absorption of berberine microemulsion. A UV method for determination of berberine in the intestinal flux was established.

RESULTThe viscosity, conductance, refraction rate and particle size of berberine microemulsion were 2.11 cPas, 125.5 microomega, 1.363 and 24.0 nm, respectively. The absorption rate of berberine at the ileum was the best. The absorption of berberine microemulsion at the ileum was significantly higher than that of raw medicine (P < 0.01).

CONCLUSIONThe microemulsion system might improve the absorption of berberine in the intestinal tract.

Absorption ; Administration, Cutaneous ; Animals ; Berberine ; administration & dosage ; pharmacokinetics ; Drug Delivery Systems ; Drug Stability ; Female ; Ileum ; metabolism ; Intestinal Absorption ; drug effects ; Intestines ; metabolism ; Male ; Particle Size ; Rats ; Rats, Wistar ; Skin ; metabolism ; Skin Absorption ; drug effects ; physiology ; Solubility ; Technology, Pharmaceutical ; methods

OBJECTIVETo study the permeability of intact mouse abdominal skin to aniline and the protective capability of two typical lab gloves against aniline.

METHODSA Franz diffusion cell was used to perform in vitro transdermal absorption test and glove permeation test for aniline (0.102 mg/ml and 0.010 mg/ml). The permeabilities of intact mouse abdominal skin and gloves to aniline were measured by high performance liquid chromatography-diode array detection.

RESULTSThe transdermal penetration of the two concentrations of aniline followed zero order kinetics within 12 h, exhibiting total aniline permeabilities within 24 h of 51.71% and 48.31%, respectively. The absorption liquid had an aniline concentration of at least 18 µg/L. The medical disposable latex glove could not stop the penetration of 0.010 mg/ml aniline, but the industrial natural latex glove could.

CONCLUSIONThe penetration of 0.102 mg/ml and 0.010 mg/ml aniline through the mouse abdominal skin follows zero order kinetics within 12 h. The medical disposable latex glove cannot stop the penetration of 0.010 mg/ml aniline, but the industrial natural latex glove can.

Aniline Compounds ; pharmacokinetics ; toxicity ; Animals ; Gloves, Protective ; Mice ; Skin Absorption ; drug effects

The aim of this paper was to investigate the effect of terpene penetration enhancers on membrane fluidity and membrane potential using HaCaT keratinocytes, and study the potential mechanisms of these terpene compounds using as natural transdermal penetration enhancer. Six terpene compounds, namely menthol, limonene, 1,8-cineole, menthone, terpinen-4-ol and pulegone, were chosen in this study on account of their good penetration-enhancement activities. The cytotoxicity of these terpene compounds was measured using an MTT assay. The fluorescence recovery after photobleaching (FRAP) technique was employed to measure the change of membrane fluidity of HaCaT cells. The flow cytometer was used to study the alteration of membrane fluidity of HaCaT cells, and investigate the effect of terpene compounds on intracellular Ca2+. It was found that 6 terpene compounds possessed low cytotoxicity in comparison to the well-established and standard penetration enhancer azone. Those terpene compounds could significantly enhance HaCaT cells membrane fluidity and decrease HaCaT cells membrane potentials. Meanwhile, after treated with various terpene compounds, the Ca2(+)-ATPase activity and intracellular Ca2+ of HaCaT cells was decreased significantly. Terpene penetration enhancers perhaps changed the membrane fluidity and potentials of HaCaT cells by altering the Ca2+ balance of the cell inside and outside, resulting in the low skin permeability to increase the drug transdermal absorption.
Cell Line ; Drugs, Chinese Herbal ; pharmacokinetics ; Humans ; Keratinocytes ; drug effects ; metabolism ; Membrane Fluidity ; drug effects ; Skin Absorption ; drug effects ; Terpenes ; pharmacokinetics

The recent fast development in biotechnology has resulted in a large number of therapeutic biologicals coming in the foreground for clinical application. Transdermal drug delivery (TDD) is designed for patching the drug on the skin, and then the drug molecules permeate through the skin into the subcutaneous capillary vessels. However,very few drugs can be administered transdermally at the therapeutic levels to pass through the barrier of stratum corneum. Several physical and chemical methods are applied to improve the permeability of skin. Research result shows that the low-frequency ultrasonic technique can extraordinarily increase the rate of permeation. As a result, it is becoming one of the potential methods that serve as the substitutes for traditional methods. In this paper is presented a type of equipment based on MSP430. The principle of design, the structure of hardware, and the applied function in this area are described.
Administration, Cutaneous ; Drug Delivery Systems ; instrumentation ; methods ; Equipment Design ; Humans ; Pharmaceutical Preparations ; administration & dosage ; Skin Absorption ; radiation effects ; Ultrasonics

OBJECTIVETo evaluate the transdermal permeability of glucosamine sulfate solution across ex vivo rabbit dermis under ultrasound and optimize the ultrasound conditions.

METHODSThe ultrasound-assisted transdermal permeation of glucosamine sulfate solution across ex vivo rabbit dermis was tested using a simple Franz diffuse. The transdermal permeation volume and rate were calculated by measuring the concentration of glucosamine sulfate in the receptor fluid with ultraviolet spectrophotometry, and the impact of different sound intensities, irradiation time and solution concentration on solution permeation was analyzed.

RESULTSAt the ultrasound intensity of 0.2 W/cm(2), the permeation volume and rate of glucosamine sulfate both reached the maximum; no glucosamine sulfate was detected in the receptor fluid after a 5-min ultrasound irradiation. The permeation volume and rate of glucosamine sulfate increased as the irradiation time prolonged and also with increased glucosamine sulfate concentration. The dorsal and lateral skin thickness (2.0∓0.1 and 1.2∓0.1 mm, respectively) did not significantly affect the transdermal permeation of glucosamine sulfate (P>0.05).

CONCLUSIONUltrasound irradiation at 1.0 MHz for over 5 min allows glucosamine sulfate to permeate rabbit dermis, and the volume and rate of permeation increase with the irradiation time and concentration of the solution and are not affected by variations of the dermal thickness.

Administration, Cutaneous ; Animals ; Dermis ; diagnostic imaging ; drug effects ; Glucosamine ; metabolism ; In Vitro Techniques ; Permeability ; Rabbits ; Skin Absorption ; Ultrasonics ; Ultrasonography

The purpose of this study is to investigate the enantioselectivity of norgestrel (NG) transdermal permeation and the potential influence of linalool and lipids on the enantioselectivity. In vitro skin permeation studies of NG across the excised rat skins were performed with Valia-Chien diffusion cells, and the permeation samples were analyzed by enantioselective HPLC. The possible enantioselective permeation of NG across intact rat back skin and lipids extracted rat back skin and the influence of linalool were evaluated. The skin permeation rate of dl-NG was two times higher than that of l-NG when donor solutions (EtOH/H2O 2 : 8, v/v) containing l-NG or dl-NG. It may be mainly attributed to the solubility discrepancy between enantiomer and racemate. The enantioselective permeation of dl-NG across intact rat skin was observed when the donor solutions containing dl-linalool. The permeation flux of l-NG was 22% higher than that of d-NG. But interestingly, the enantioselective permeation of dl-NG disappeared under the same experimental condition except that the lipid extracted rat skin was used. Attenuated total reflection-fourier transform infrared spectroscopy analysis of stratum corneum showed that the wave number for asymmetric CH2 stretching vibrations of lipids treated with dl-linalool was greater than that of the control. The results indicated that the enantioselective permeation of NG may be contributed by the interaction between dl-linalool and lipids. More than half of lipids were composed of ceramides. The stereospecific interaction maybe existed among chiral enhancer (linalool), lipids (ceramides) and/or chiral drugs (NG).
Administration, Cutaneous ; Animals ; Lipids ; pharmacology ; Monoterpenes ; pharmacology ; Norgestrel ; pharmacokinetics ; Rats ; Skin Absorption ; drug effects ; Spectroscopy, Fourier Transform Infrared ; Stereoisomerism

OBJECTIVETo study the effect of different penetration enhancers on the in vitro transdermal permeation of 1-tethrahydropalmatine (L-THP) through rat skin.

METHODBoth natural and chemical synthesis penetration enhancers were applied singly or jointly to investigate the skin permeation rates of l-THP. The skin permeation profiles were evaluated by Valian-Chien permeation cells with isolated rat skin. HPLC-UV method was established to determine the concentration of l-THP in samples.

RESULTAs chemical synthesis penetration enhancer was used alone, 8% azone was observed to be the optimal penetration enhancer with the maximal penetration rate of 21.153 microg x cm(-20 x h(-1). Although 2% menthol crystal or 5% eucalyptus oil was effective as a natural penetration enhancer when used alone, the average penetration rate reached only half of that of 8% azone. The penetration potency of either menthol oil or menthol crystal combined with 8% azone was more effective than that of azone alone (P < 0.05).

CONCLUSIONEither menthol oil or menthol crystal combined with 8% azone is effective on transdermal penetration of l-THP in vitro. There is significant synergistic effect when natural penetration enhancers combined with chemical synthesis penetration enhancers.

Administration, Cutaneous ; Animals ; Azepines ; pharmacology ; Berberine Alkaloids ; analysis ; pharmacokinetics ; Drug Synergism ; Eucalyptus ; chemistry ; Male ; Menthol ; pharmacology ; Oils, Volatile ; pharmacology ; Permeability ; drug effects ; Rats ; Rats, Sprague-Dawley ; Skin ; drug effects ; metabolism ; Skin Absorption ; drug effects