Physicochemical characteristics of triacyl lipid A partial structure OM-174 in relation to biological activity.

The triacylated lipid A partial structure OM-174 was characterized in detail using a variety of physical and biological techniques. OM-174 aggregates adopt the micellar HI structure. The temperature (Tc) of the gel to liquid-crystalline phase transition of the hydrocarbon chains is 0 degrees C, from which high fluidity of the acyl chains at 37 degrees C can be deduced. The molecular area of a single OM-174 molecule at a surface pressure of 30 mN x m-1 is 0.78 +/- 0.04 nm2. Conformational analyses, using IR spectroscopy, of the behavior of the various functional groups of OM-174 as compared with hexa-acyl lipid A suggest altered hydration of the phosphate charges and unusually strong hydration of the ester groups, which is probably related to the high accessibility of these groups to water in the micellar aggregate structure. OM-174 was shown to intercalate into a phospholipid membrane corresponding to the macrophage membrane within seconds in the presence, and within minutes to hours in the absence, of LPS-binding protein. In the Limulus amebocyte lysate assay, the triacyl lipid A is more than 105-fold less active than hexa-acyl lipid A, but only 10-fold less active in inducing IL-6 in human mononuclear cells, and equally active in inducing NO production in murine macrophages. These findings are used to explain the mechanism of the lipid A-induced cell activation.

Production of diosgenin by hairy root cultures ofTrigonella foenum-graecum L.

Hairy root cultures ofTrigonella foenum-graecum L. were established withAgrobacterium rhizogenes strain A4. The hairy roots produce diosgenin, an important spirostanol for the semi-synthesis of steroid hormones. Fourteen different liquid media were investigated. The fastest growth was obtained in McCown's woody plant (WP) medium supplemented with 3% sucrose; the highest diosgenin content was observed in half-strength WP medium with 1% sucrose (0.040% dry weight), which represents almost twice the amount detected in the 8-month-old non-transformed roots (0.024%). A time-course study in WP liquid media supplemented with 3% sucrose was undertaken. In these conditions, 17 µg diosgenin/g fresh weight were produced. The influence of cholesterol, medium pH and chitosan on diosgenin production was tested. The addition of 40 mg/l chitosan elevated the diosgenin content to three times that found in non-elicited hairy roots.

Purity and stability assessment of a semi-solid poly(ortho ester) used in drug delivery systems.

The research work carried out for developing bioerodible drug delivery devices in which the erosion process was to be confined to the polymer-water interface is at the origin of the discovery of a class of polymers known as poly(ortho esters) (POEs). Thus far, three POE systems have been described. The latest POE was prepared by a transesterification reaction between a triol and an ortho ester, followed by a self-condensation of the reaction product. This polymer, which exhibits viscous characteristics at room temperature, was investigated for use as a drug delivery system in glaucoma filtering surgery. The assessment of POE purity and stability was carried out by a detailed analysis of the influence of the purification procedure and storage conditions. This bioerodible semi-solid POE was purified by a repeated precipitation procedure. Elimination of the small molecular weight oligomers and monomers and of the catalysts and stabilizers used in the synthesis, as well as a decrease of the polydispersity, were obtained with this method. Fourier transform infrared analysis also verified the disappearance of degradation products after the first precipitation. Drying of the precipitated polymer was performed at 40 degrees C in order to avoid thermal degradation of the POE at higher temperatures and to facilitate solvent evaporation through the polymer network by a reduction of polymer viscosity. Water vapour uptake of the polymers stored at different relative humidities has demonstrated the high moisture sensitivity of these semi-solid POEs. The average molecular weight of the polymer and hence its viscosity, as well as the solubility characteristics of the incorporated drug, were found to have a considerable influence on the rate of water vapour absorption and on polymer degradation. The use of inert gas or vacuum to maintain the polymer under anhydrous conditions has been studied. Storage of the semi-solid POE under argon in sealed glass bottles provides good protection of the polymer over time.

Gamma sterilization of a semi-solid poly(ortho ester) designed for controlled drug delivery--validation and radiation effects.

Radiation sterilization is becoming increasingly popular for the sterilization of many pharmaceutical products. Although this technique is not limited to the sterilization of polymers, it is probably the most suitable method for such materials. This method however suffers several drawbacks. The sterilization of a product must lead to a safety level of 10(-6), i.e. one chance in a million to find a contaminated sample. In many cases, this assurance of sterility can be achieved by using a uniform treatment dose of 2.5 Mrad, recommended by the pharmacopeia. We investigated the possibility of using doses of radiation inferior to 2.5 Mrad to sterilize a semi-solid poly(ortho ester) (POE) developed for use as carrier in controlled drug delivery. After determination of the initial bioburden, the polymer was intentionally contaminated with the bioindicator Bacillus pumilus E 601. Following exposure to gamma irradiation, the D10 value of the radio resistant bioindicator was determined. Using the initial contamination value, the reduction factor D10 and the safety level, it is possible to calculate an optimal sterilizing dose for POE. All polymers are affected by ionizing radiation and the amount of radiation which produces a significant change in properties may vary from one polymer to the other. A molecular weight and dynamic viscosity decrease resulting from backbone cleavage was observed for this POE at a dose lower than 2.0 Mrad. Evaluation of the structure using 1H-NMR, 13C-NMR and IR analysis shows that for doses higher than 2.0 Mrad, another degredation process takes place.(ABSTRACT TRUNCATED AT 250 WORDS)

Biocompatibility of a new semisolid bioerodible poly(ortho ester) intended for the ocular delivery of 5-fluorouracil.

The biocompatibility of a new semisolid, hydrophobic poly(ortho ester) (POE) intended for controlled drug delivery to the eye was evaluated. The polymer was injected subconjunctivally in rabbits, and clinical and histologic examinations were performed 3, 10, 15, and 21 days after injection. Polymers injected as controls were an aqueous gel of sodium hyaluronate (SH), 1% in phosphate buffer, and medical grade silicone oil. After injection, the POE emulsified into small droplets and a focal eosinophilic reaction was noted at 3 days' implantation. At 10 days' implantation, the POE was not identified in the implantation site and the inflammatory reaction had resolved, with fibroblasts being the predominant cell type. At 15 and 21 days, no POE was identified and normal appearing tissue was present in the injection site. Sodium hyaluronate was not inflammatory over the period of the implantations. Silicone oil induced a slight inflammation at 3 days, with the presence of eosinophils and limited necrosis with cellular debris. Silicone oil was present in the implantation site at 3, 10, 15, and 21 days. The inflammatory response to the respective polymers was evaluated in the subconjunctival tissue. The inflammatory reaction was quantified at the implant site, adjacent subconjunctival tissues, and scleral and corneal stroma. The inflammatory cell densities in these respective tissue zones were determined, and the ratio of eosinophils over total inflammatory cells was calculated. POE did not become encapsulated with fibrous tissue, but biodegraded in a short time, indicating its potential for use after glaucoma filtration surgery.

Biotolerance of a semisolid hydrophobic biodegradable poly(ortho ester) for controlled drug delivery.

We evaluated the biotolerance of a new semisolid poly(ortho ester) (POE) intended for controlled drug delivery. Two different investigations were carried out in rats: subcutaneous injections and the cage-implant system. Sodium hyaluronate (SH), 1%, in phosphate buffer was used as a noninflammatory control. When injected subcutaneously in rats, the POE induced a mild and local inflammation at 3 and 7 days followed by a minimal chronic inflammation at 14 and 21 days. When using the cage-implant system, we quantified the inflammatory components of the exudate surrounding the implanted material within the cage system at 3, 7, 14, and 21 days. The total leukocyte and macrophage concentrations were higher only at 7 days for both SH and POE compared to the control (empty cage). The other parameters were not significantly different from the control. These results show that POE is well-tolerated by rats when used subcutaneously.

Synthesis and characterization of a new biodegradable semi-solid poly(ortho ester) for drug delivery systems.

Since the late 1970s, three families of poly(ortho esters) (POE) were synthesized to provide bioerodible carriers for drug delivery devices. The most recent POE is a semi-solid polymer with a viscous behavior at room temperature. Polymer synthesis by a transesterification reaction between a triol and a trialkyl ortho ester is described. The structure of the polymer was confirmed by conventional methods such as 1H-NMR, 13C-NMR and FT-IR. Information concerning average molecular weight and intrinsic viscosity was obtained respectively by GPC and viscosimetry. Residual solvents in the polymer were determined using gas chromatography. The chromatographic conditions were optimized to enable the quantification of the solvents in concentrations of a few percent. The mechanical behavior of the semi-solid POE was determined by rheometric measurements. Hydrolysis of the polymer leads to the formation of the original triol and the carboxylic acid derived from the trialkyl ortho ester used in the transesterification step. No toxicological problems associated with these compounds are anticipated.