Effects of different absorption enhancers on the permeation of ebiratide, an ACTH analogue, across intestinal membranes

The permeation of ebiratide (H-Met(O2)-Glu-His-Phe-D-Lys-Phe-NH(CH2)8NH2), a novel ACTH analogue, across the intestinal mucosae has been examined by use of isolated intestinal membranes from rats in a modified Ussing chamber. Regional differences were observed in the permeation of ebiratide across intestinal membranes; the order of membrane permeability was jejunum > ileum > duodenum > colon. Overall, the permeation of ebiratide was relatively poor. The effects of various absorption enhancers were examined to increase the intestinal permeability to ebiratide. Sodium glycocholate and sodium caprate had no significant enhancing effect on the permeability of the jejunal membrane, but significantly enhanced the permeation of ebiratide through the colonic membrane. On the other hand, N-dodecyl-beta-D-maltopyramoside (LM) significantly enhanced the permeation of ebiratide through both jejunal and colonic membranes. In general, the absorption-enhancing effects of these agents were more predominant in the colon than in the jejunum. Membrane damage by the absorption enhancers was evaluated by measuring the amount of protein released from the intestinal membrane. It was found that all the absorption enhancers slightly increased the amount of protein released, but that the amounts of protein released in the presence of these enhancers were much less than in the presence of ethylenediaminetetraacetic acid (EDTA), used as a positive control. These findings suggest that the absorption enhancers, especially LM might be useful adjuvants for improving the intestinal absorption of peptide and protein drugs, including ebiratide.     

In situ ocular absorption of tilisolol through ocular membranes in albino rabbits

The purpose of this study is to characterize the in situ absorption properties of ocular membranes using a cylindrical cell. Drug disappearance in the cell was determined as in situ absorption after an application of drug solution into the cell on the comea, sclera (bulbar conjunctiva and sclera layer), or palpebral conjunctiva. Tilisolol was used as a model of an ophthalmic beta-blocker. Tilisolol disappeared from the conjunctival and scleral surfaces although hardly any disappearance of tilisolol from the corneal surface was observed. Depletion of drug from the precorneal space was much faster in situ than extrapolated from permeability measurements (in vitro) of the separate tissues. This may arise from an influence of blood flow. The in situ apparent permeability coefficient of tilisolol through the conjunctiva was almost constant at various concentrations of drug (5-100 mM), suggesting a passive diffusion of tilisolol that was affected by medium pH. A high concentration of tilisolol in the aqueous humor was observed in the corneal application although the scleral and conjunctival applications showed a slight concentration of tilisolol. The corneal route was a dominant route of access to the aqueous humor. Access to the vitreous body for tilisolol was 4 times more effective through the sclera than through the cornea. On the other hand, the corneal application showed an extremely low concentration of tilisolol in plasma compared to the scleral and conjunctival applications. Thus, the in situ method using a cylindrical cell is a useful method for investigation of the ocular absorption of ophthalmic drugs.     

High penetrance and pronounced variation in expressivity of GCH1 mutations in five families with dopa-responsive dystonia

A mathematical model is presented which examines the extent to which the intestinal epithelium is accessed by drug molecules. Morphological information from the literature for the jejunum, ileum, and colon of the rat and for human jejunum was incorporated. Perturbation theory was used to derive the limiting cases for total access to the entire epithelial surface, for transport by diffusion and by diffusion with convection, respectively. A parameter gamma = square root of (Ph2)/(Db) was identified to provide a measure of the ability of drug molecules to access the entire epithelial surface down to the crypt wells, where P is the cell permeability, D the aqueous diffusion coefficient, h the channel depth between the villi, and b is half the width of the idealized intervillous channel. When gamma < 1, diffusion is not a limitation and the entire surface is fully utilized for absorption of drug. This condition arises with drugs of low permeability and is more likely to be met with colonic than small intestinal epithelium. When gamma >/= 1, diffusion becomes a limitation and then not all of the epithelial surface is functionally accessible to drug molecules, a condition most likely to prevail with drugs of high permeability traversing the jejunum. Furthermore, water flux per se is predicted to have relatively little influence on enhancing surface accessibility. This simple, but quantitative approach showed that the ranking order of permeability jejunum >ileum> colon for low permeable drugs can at least in part be explained by the differences in surface amplification between these different epithelial regions. The analysis also indicates that for highly permeable drugs extreme caution should be exercised in extrapolating permeability measurements in vitro across various preparations and to events in vivo.     

Permeability characteristics of novel mydriatic agents using an in vitro cell culture model that utilizes SIRC rabbit corneal cells

The purpose of this study was to evaluate the permeability characteristics of a previously reported in vitro corneal model that utilizes SIRC rabbbit corneal cells and to investigate the permeability of three novel esters of phenylephrone chemical delivery systems (CDS) under different pH conditions using this in vitro model. The SIRC rabbit corneal cell line was grown on transwell polycarbonate membranes, and the barrier properties were assessed by measuring transepithelial electrical resistance (TEER) using a voltohmmeter. The permeabilities of esters of phenylephrone CDS across the SIRC cell layers were measured over a pH range 4.0-7. 4. The esters tested include phenylacetyl (1), isovaleryl (2), and pivalyl (3). The SIRC rabbit corneal cell line, when grown on permeable filters, formed tight monolayers of high electrical resistance with TEER values increasing from 71.6 +/- 20.8 Omega.cm2 at day 3 in culture to 2233.42 +/- 15.2 Omega.cm2 at day 8 in culture and remained constant through day 14 in culture. The transepithelial permeability coefficients (Papp) at pH 7.4 ranged from 0.58 x 10(-6) cm/s for the hydrophilic marker, mannitol, to 43. 5 x 10(-6) cm/s for the most lipophilic molecule, testosterone. The Papp at pH 7.4 for phenylephrine was 4.21 x 10(-6) cm/s. The Papp values and the lag times of the three esters of phenylephrone were pH dependent. The Papp for 1, 2, and 3 at pH 7.4 were 14.76 x 10(-6), 13.19 x 10(-6), and 12.86 x 10(-6) cm/s, respectively and the permeabilities decreased at conditions below pH 7.4. The lag times at pH 7.4 were 0.10, 0.17, and 0.12 h for 1, 2, and 3, respectively, and the values increased at lower pH conditions. The TEER values of SIRC cell line observed at day 8 to day 14 in the present investigation are similar to the resistance value reported for rabbit cornea (2 kOmega.cm2). All the esters showed significantly (p < 0.05) higher permeabilities than phenylephrine at pH 7.4. The rate and extent of transport of the drugs across the cell layers were influenced by the fraction of ionized and un-ionized species and the intrinsic partition coefficient of the drug. The results indicate that the permeability of ophthalmic drugs through ocular membranes may be predicted by measuring the permeability through the new in vitro cell culture model.     

Effect of ultrasound on the permeability of D2O through cellulose membranes

The effect of ultrasound energy on the permeability of water through cellulose membranes was studied using deuterium oxide (D2O) as a tracer. The same membrane was used for control (no ultrasound) and ultrasound experiments in a sequential reversal design. Transfer of D2O to a 2% albumin solution was measured in a glass dializing cell with membrane area of 11 cm2. Ultrasonic energy was supplied for 45 min by a hydrosonic bath (Linden Laboratories) at an intensity of 0.18 watt/cm2, an energy level commonly used for therapeutic purposes. Statistical analysis showed a significant increase in water transfer due to the ultrasound treatment irrespective of the sequence of application of ultrasound. It was concluded that ultrasound energy increases water permeability through cellulose dializing membranes. Whether or not increased water permeability is the operating mechanism underlying the beneficial effects of ultrasonic bath therapy remains unanswered.     

Role of oxidative stress in health and disease

BACKGROUND: Radiation therapy can cause corneal and conjunctival abnormalities that sometimes require surgical treatment. Corneal stem cell dysfunction is described, which recovered after the cessation of radiation. METHODS: A 44-year-old man developed a corneal epithelial abnormality associated with conjunctival and corneal inflammation following radiation therapy for maxillary cancer. He experienced ocular pain and loss of vision followed by conjunctival epithelialisation of the upper and lower parts of the cornea. RESULTS: Examination of brush cytology samples showed goblet cells in the upper and lower parts of the cornea, which showed increased fluorescein permeability, and intraepithelial lymphocytes. Impression cytology showed goblet cells in the same part of the cornea. Specular microscopy revealed spindle type epithelial cells. Patient follow up included artificial tears and an antibiotic ophthalmic ointment. The corneal abnormalities resolved after 4 months with improved visual acuity without any surgical intervention, but the disappearance of the palisades of Vogt did not recover at 1 year after radiation. CONCLUSION: Radiation therapy in this patient caused temporary stem cell dysfunction which resulted in conjunctivalisation in a part of the cornea. Although limbal stem cell function did not fully recover, this rare case suggested that medical options should be considered before surgery.     

In vitro corneal permeability of diclofenac sodium in formulations containing cyclodextrins compared to the commercial product voltaren ophtha

The influence of different cyclodextrin derivatives on the in vitro permeability of diclofenac sodium through pig cornea was investigated and compared to the commercial product Voltaren ophtha. (Hydroxypropyl)-beta-cyclodextrin (HP beta CD) and two amorphous methylated cyclodextrins with different degrees of substitution were used. In hemolysis studies on human erythrocytes, the hemolytic activity of the different cyclodextrins and the drug was assessed. It was shown that HP beta CD reveals the most favorable toxicological properties. A decrease in the hemolytic activity of diclofenac was yielded by adding HP beta CD. In the permeability experiments the dependency of the permeability coefficients and lag times on the type of cyclodextrin and pH of the solutions were examined. A solution containing HP beta CD buffered in the pH range 6.5 to 7 is proposed as a useful eye drop formulation. All cyclodextrin formulations showed advantages as compared to Voltaren ophtha.     

Correlation of lethal doses of industrial chemicals between oral or intraperitoneal administration and inhalation exposure

To further explore barrier properties of the sclera, the diffusion of 3H-hydrocortisone and 14C-mannitol was measured across isolated rabbit scleral membrane. In vitro permeability studies were performed using side by side diffusion cells. Bicarbonated Ringer Solution with oxidized glutathione (GBR) at pH 7.4 was the perfusion medium, and the temperature was kept at 37 degrees C. Diffusion of hydrocortisone through the cornea was also measured to compare scleral and corneal permeation. Scleral permeability was found to be five times greater than corneal permeability. Drug analyses were performed by radionuclide counting (LSC), and permeability coefficients were obtained. In vitro metabolism of hydrocortisone was examined by incubation of tissue in hydrocortisone solution in GBR for 5 hours and 37 degrees C. Permeability coefficients of hydrocortisone diffusion through the sclera were also obtained at 25 degrees C, 15 degrees C, and 5 degrees C. Activation energy of scleral transport of hydrocortisone was calculated from an Arrhenius plot. The low activation energy suggests an aqueous pore pathway unlike permeation of the drug across the cornea which uses a transcellular pathway.     

Epithelial transport of drugs in cell culture. VIII: Effects of sodium dodecyl sulfate on cell membrane and tight junction permeability in human intestinal epithelial (Caco-2) cells

This study demonstrates how the common pharmaceutical wetting agent sodium dodecyl sulfate (SDS) increases the absorption of drugs and peptides across the human intestinal epithelium. First, an assay that could follow the reversible and irreversible time-dependent effects of SDS on the permeability of Caco-2 cell monolayers with high reproducibility was developed. SDS (0.40 mM) exposure for 20 min resulted in reversible absorption enhancement of mannitol (M(r), 182 g/mol), 1-deamino-8-D-arginine-vasopressin (M(r), 1071 g/mol), and polyethylene glycol (M(r), 4000 g/mol). A longer (2 h) exposure to SDS resulted in irreversible absorption enhancement. Second, transepithelial electrical resistance measurements (TEER) together with fluorescence and transmission electron microscopy were used to study the effects of SDS on epithelial integrity, cell membranes, intracellular calcium concentration, cytoskeleton, and tight junctions. The effect of SDS (0.40 mM) on epithelial integrity was immediate. A significant decrease in transepithelial electrical resistance measurements was obtained with 1 min after exposure to SDS that was concomitant with increases in the permeability of the apical cell membranes and intracellular calcium concentration. SDS shortened the microvilli of the cells and produced apical (but not basolateral) membrane wounds, actin disbandment, disorganization of the terminal web, and structural separation of the tight junctions. The absorption enhancement was not reduced after repair of the apical cell membranes, indicating that SDS enhances drug and peptide absorption across the intestinal epithelium by the paracellular pathway.     

A surface glycoprotein modulating drug permeability in Chinese hamster ovary cell mutants

Chinese hamster ovary cells selected for resistance to colchicine display pleiotropic cross-resistance to a wide range of amphiphilic drugs. The drug-resistant phenotype is due to a membrane alteration which reduces the rate of drug permeation. Surface labelling studies reveal that drug-resistant Chinese hamster ovary cell membranes possess a carbohydrate-containing component of 170 000 daltons apparent molecular weight which is not observed in wild type cells. Through studies of the metabolic incorporation of carbohydrate and protein precursors, and through the use of selective proteolysis, this component is shown to be a cell surface glycoprotein. Since this glycoprotein appears unique to mutant cells displaying altered drug permeability, we have designated it the P glycoprotein. The relative amount of surface labelled P glycoprotein correlates with the degree of drug resistance in a number of independent mutant and revertant clones. A similar high molecular weight glycoprotein is also present in drug-resistant mutants from another hamster cell line. Observations on the molecular basis of pleiotropic drug resistance are interpreted in terms of a model wherein certain surface glycoproteins control drug permeation by modulating the properties of hydrophobic membrane regions...     

High permeability of the intercellular contact

The mechanism of the intercellular contact (gap junction) high permeability is proposed on the following basis: 1) cell membranes are depolarized in the junction zone and 2) during depolarization a sharp increase of membrane permeability results from the formerly proposed [1--3] relationship between the trans-membrane potential and membrane surface potential (boundary jump), owing to the fact that the latter determines both the membranes conductance and conformation.     

In vitro diffusion of 5-fluorourcil and tegafur through excized pig cornea

Permeability kinetics of 5-fluorouracil (5-FU), tegafur (TGF) and ftorafur (FT) through synthetic, lipophilic membranes and the pig excised cornea were studied. During the dialysis process, the drugs were dissolved in Ringer's solutions of either pH 6.89 or 7.98 and the drug concentrations were measured vs time by UV spectrophotometry at 37 degrees C. The diffusion processes of 5-FU, TGF and FT through the synthetic membranes were pH dependent and could be interpreted according to pseudo-first-order kinetics. However, the drug diffusion through the pig excised cornea was a zero-order process. The permeability rate of FT (TGF) across the pig cornea was greater if compared to that of 5-FU, whose partition coefficient (ko/w) was higher than those of the former drugs.     

Concentration- and region-dependent intestinal permeability of fluvastatin in the rat

The purpose of this study was to investigate the mechanisms of transport of fluvastatin across the intestinal mucosa in various regions of the intestine in the rat. In-situ single-pass perfusions of the jejunum, ileum and colon were performed and the effective permeability (Peff) of fluvastatin, antipyrine and D-glucose were assessed in each region, at three different perfusate fluvastatin concentrations (1.6, 16 and 160 microM). The effect of lovastatin acid on the bi-directional transport of fluvastatin across the ileal mucosa was also studied. The Peff of fluvastatin was found to be dependent both on the intestinal region and on the concentration in the intestinal lumen (P < 0.001). Fluvastatin had the lowest Peff (0.55 +/- 0.10 x 10(-4) cm s(-1)) in the jejunum at 1.6 microM, and the highest Peff (1.0 +/- 0.16 x 10(-4) cm s(-1)) in the colon at 160 microM. The highest concentration of fluvastatin increased the average absorption of water from the intestine by 209% (P < 0.05), and the average Peff of D-glucose by 29% (P < 0.05). The presence of excess lovastatin acid (100 microM, compared with fluvastatin 1.6 microM) at the luminal side increased the average absorption of water by 218% (P < 0.001), and the Peff of fluvastatin in the ileum and the colon by 44 and 50%, respectively (P < 0.05). The presence of lovastatin acid on the luminal side in the ileum also increased the blood-to-lumen transport (exsorption) of fluvastatin by 43% (P < 0.001). The increased intestinal absorption of fluvastatin at higher concentrations does not suggest that substantial absorption occurs by any carrier-mediated process in the absorptive direction. The increased bi-directional transport when lovastatin acid was added to the lumen suggests that fluvastatin is not a P-glycoprotein substrate. Instead, the concentration-dependent increase in the absorption of fluvastatin, water and D-glucose suggests a direct effect of fluvastatin on the transcellular passive transport.     

Induced mutagenesis in Ustilago maydis. II. An in vivo biochemical assay

Cholinesterase (ChE) activities of the rat cornea were demonstrated histochemically by using both light and electron microscopes. Acetylcholinesterase (AChE) reaction was localized in the axolemma of the nerves in the corneal stroma. The epithelial cell membranes and the intraepithelial nerve endings also showed AChE reaction. Non-specific cholinesterase (NsChE) activity was observed only in the endothelial cell membranes. Cervical sympathectomy, ciliary ganglionectomy and stereotactic coagulation of the ophthalmic division of the trigeminal nerve were performed in order to study the routes of the AChE-containing nerves to the cornea. The disappearance of AChE-containing nerves was observed only after ophthalmic neurotomy. It is suggested that the AChE-containing nerves are distributed to the rat cornea exclusively via the ophthalamic nerve. They seem to be sensory nerves.     

A potentiostatic study of oxygen transmissibility and permeability through hydrogel membranes

The permeability characteristics of membranes prepared from hydrogels of poly(2-hydroxyethylmethacrylate) (PHEMA) and poly(2-hydroxyethylmethacrylate-co-N,N-dimethylacrylamide) (PHNDA) are described. True values of the permeability and transmissibility coefficients of oxygen in the membranes are determined by using electrochemical procedures involving the measurement of the steady state current either in membranes with different thickness or in a single membrane in which its thickness is varied with layers of moistened paper. Comparison of the results obtained for the transport properties in these hydrogels with others obtained in other hydrogels permit to conclude that the degree of swelling rather than the chemical nature of the hydrogels affects the permeation properties. The chemical structure presumably only affects in high degree the chemical stability and flexibility of the hydrogel membranes.     

Reduction in water permeability of the rabbit conjunctival epithelium by hypotonicity

The effects of unilateral exposure to hypotonic media on the diffusional water permeability of the isolated rabbit conjunctiva were determined. For these experiments, a segment of the bulbar-palpebral conjunctiva was mounted between Ussing-type hemichambers under short-circuited conditions. Unidirectional diffusional water fluxes (Jdw) were measured in either direction by adding 3H2O to one hemichamber and sampling from the other. Electrical parameters were measured simultaneously. Jdw were determined in control isosmotic conditions and after dilution of one of the bathing solutions from 290 to 108 mOsMolar. This hypotonic condition reduced Jdw by 25-30% (n = 17) when applied basolaterally and by 25% (n = 6) apically. The effects were reversible and were also obtained when the opposite bathing solution contained amphotericin B, selectively permeabilizing the contralateral cell surface. From concomitant changes in transepithelial electrical resistance as well as 14C-mannitol fluxes completed under identical conditions, arguments are presented that the above effect is best explained as a cell regulated reduction in membrane water permeability. Presumably both apical and basolateral membranes can down-regulate their water permeabilities. This response, suggesting a protective mechanism to help maintain cell volume from hypotonicity, was also seen in other studies using the amphibian bladder and the frog cornea, in which the effect was only obtained basolaterally. Thus, regulation of epithelial water permeability appears to be a basic trait common to both amphibians and mammals, although tissue differences exist.     

Retinoid permeability and uptake in corneas of normal and vitamin A-deficient rabbits

In vitro perfusion of corneas of normal and vitamin A-deficient rabbits provided a model in which to study the pharmacokinetics of corneal permeability and uptake of retinoic acid and retinol. The permeability coefficients of retinoic acid and retinol were 1.49 x 10(-5) and 0.61 x 10(-5) cm/s, respectively. Removal of the corneal epithelium did not affect the permeability of these lipid-soluble retinoids; however, diffusion through xerophthalmic, vitamin A-deficient corneas was significantly reduced. The corneal uptake of retinoic acid and retinol was reduced by 50% on removal of the epithelium, was nonspecific, and was not affected by xerophthalmia. High-performance liquid chromatography indicated that these retinoids were not metabolized during diffusion through the cornea. These results show that topical application of retinoids is a rational approach to the treatment of such corneal diseases as xerophthalmia and epithelial defects.     

In vitro transcorneal permeation of ketorolac from oil based ocular drops and ophthalmic ointment

Transcorneal permeation of ketorolac from oil based ocular drops and ophthalmic ointments was studied in vitro, using goat cornea. Cumulative (%) permeation of ketorolac through cornea, was found to be maximum with 0.2% (w/v) ketorolac drops in sesame oil followed by formulations in corn oil and soyabean oil. Ketorolac 1% (w/v) drops in castor oil increased the quantity permeated but cumulative (%) permeation was less. Permeation profiles of ketorolac were in consistence with the partition characteristic of drug between oil and aqueous phase. Formulations favouring corneal permeation of ketorolac increased corneal hydration. Addition of benzyl alcohol, a preservative, to oil drops reduced permeation of ketorolac and corneal hydration indicating possible protective effect of benzyl alcohol against corneal damage. Permeation studies on ointment formulations containing either ketorolac acid or ketorolac tromethamine salt indicated better permeation for formulation containing ketorolac tromethamine aqueous solution. Thus for better transcorneal permeation, ketorolac 0.2% (w/v) drops, formulated in sesame oil, containing 0.5% v/v benzyl alcohol and ophthalmic ointment containing 0.5% (w/w) ketorolac tromethamine in dissolved state appear suitable.     

Permeabilities of alkyl p-aminobenzoates through living skin equivalent and cadaver skin

The in vitro permeabilities of alkyl p-aminobenzoates through living skin equivalent (LSE) and cadaver skin were compared. Methyl, ethyl, and butyl p-aminobenzoates were used as model compounds. The permeabilities of these compounds through LSE and cadaver skin from an aqueous drug suspension were determined with a flow-through diffusion cell. The permeability coefficients of these esters in LSE were an order of magnitude higher than in cadaver skin. This was primarily because of low resistances offered by the outermost layer (i.e., stratum corneum) of LSE. In the case of cadaver skin, the permeability coefficient increased as the carbon chain length increased, whereas no appreciable change in the permeability coefficients of these esters in LSE was observed. These results clearly suggest that the LSE membrane offered very little resistance as opposed to cadaver skin. Therefore, the LSE membrane may not quantitatively represent a good human skin model for evaluating skin permeation of a drug from topical or transdermal formulations.