Omathanu Pillai

Polymers in drug delivery

Advances in polymer science have led to the development of several novel drug-delivery systems. A proper consideration of surface and bulk properties can aid in the designing of polymers for various drug-delivery applications. Biodegradable polymers find widespread use in drug delivery as they can be degraded to non-toxic monomers inside the body. Novel supramolecular structures based on polyethylene oxide copolymers and dendrimers are being intensively researched for delivery of genes and macromolecules. Hydrogels that can respond to a variety of physical, chemical and biological stimuli hold enormous potential for design of closed-loop drug-delivery systems. Design and synthesis of novel combinations of polymers will expand the scope of new drug-delivery systems in the future.

Transdermal delivery of insulin from poloxamer gel: ex vivo and in vivo skin permeation studies in rat using iontophoresis and chemical enhancers.

Gels are considered to be the most suitable delivery vehicle for iontophoresis, as they can be easily amalgamated with the iontophoretic delivery system and can also match the contours of the skin. Insulin was used as a model peptide for large peptides in the molecular weight range of 3-7 kDa. A gel formulation of insulin was formulated using poloxamer 407 and was evaluated by ex vivo and in vivo skin permeation studies in rat with chemical enhancer and/or iontophoresis. The poloxamer gel was physically and chemically stable during the storage period. In ex vivo studies, both linoleic acid and menthone in combination with iontophoresis showed a synergistic enhancement of insulin permeation. The plasma insulin concentration (PIC) was highest with linoleic acid pre-treatment, in agreement with ex vivo permeation studies, but the reduction in plasma glucose levels (PGL) was comparable to iontophoresis. Menthone pre-treatment resulted in rapid attainment of peak PIC, but the reduction in PGL was less than other treatment groups. There was no direct relation between PIC and PGL and is attributed to the fact that the action of insulin in mediated by a cascade of cellular mechanisms, before a reduction in PGL is observed. However, iontophoresis either alone or in combination with linoleic acid produced a reduction in PGL to the extent of 36-40%. A combination of chemical enhancers and iontophoresis caused greater skin irritation than when either of them was used alone.

Insulin therapies - past, present and future

The discovery of insulin is one of the greatest milestones in medical history. This discovery revolutionized the use of peptides and proteins as therapeutic agents. For more than six decades, insulin from different animal sources was used, until the breakthrough in biotechnology made it possible to produce human insulin in sufficient amounts. The evolution of the biotechnological era gave rise to modified insulins to solve some of the bottlenecks in insulin therapy. Efforts are currently focused towards developing non-invasive insulin delivery systems, and there are several competing technologies in different stages of development. The next few years will see several novel approaches to mimic the endogenous release and kinetics of insulin, and also many improved analogues designed to achieve better control and effective treatment of diabetes.

Transdermal iontophoresis of insulin: V. Effect of terpenes

To increase the skin permeation of large peptides like insulin, it is necessary to utilize a combination of enhancement strategies. In this regard, this study investigated the effect of terpenes/EtOH combination in comparison to EtOH and neat terpene on transdermal iontophoretic permeation of insulin. Ex-vivo experiments were conducted using full thickness rat skin after pre-treatment for 2 h with 5% of menthol, menthone, cineole and pulegone in EtOH; EtOH alone; neat menthone with and without iontophoresis (0.5 mA/cm(2); 6 h). FT-IR studies were carried out using rat epidermal sheets after pre-treatment with enhancer solution for 2 h and tritiated water permeation studies was used to investigate the alteration in skin barrier property after enhancer or current treatment. The lag time was significantly reduced (P<0.05) with terpene/EtOH pre-treatment in comparison to passive control and EtOH pre-treatment, although there was no significant difference (P>0.05) among the terpenes. Synergistic enhancement in flux was observed with terpene/EtOH, and menthone/EtOH showed highest enhancement among the terpene/EtOH combinations. On the other hand, enhancement with neat menthone was higher than with menthone/EtOH. FT-IR studies showed that terpene/EtOH, EtOH and neat terpene act at the intercellular lipids. The skin barrier property was significantly (P<0.05) compromised with neat menthone treatment. Iontophoresis had a lesser effect on skin barrier property compared to chemical enhancer pre-treatment. Terpene/EtOH caused synergistic enhancement of insulin permeation when combined with iontophoresis and was influenced by the type and concentration of terpene.

Transdermal iontophoresis revisited

Iontophoresis evolved as a transdermal enhancement technique in the 20th century, primarily for the delivery of large and charged molecules. Significant achievements have been made in the understanding of underlying mechanisms of iontophoresis and these have contributed to the rational development of iontophoretic delivery systems. The major challenges in this area are the development of portable, cost effective devices and suitable semi-solid formulations that are compatible with the device and the skin. Some of the obstacles in transdermal iontophoresis can be overcome by combining iontophoresis with other physical and chemical enhancement techniques for the delivery of macromolecules. Iontophoresis also offers an avenue for extracting information from the body through the use of reverse iontophoresis, which has potential application in diagnosis and monitoring. The current research is focussed towards resolving the skin toxicity issues and other problems in order to make this technology a commercial reality.

Characterization of Azithromycin hydrates

Azithromycin (AZI) is a macrolide antibiotic with an expanded spectrum of activity that is commercially available as a dihydrate. This study was carried out to characterize hydrates of azithromycin. A commercial dihydrate sample was used to prepare monohydrate from water/ethanol (1:1) mixture. Hydrates were characterized using DSC, TGA, KFT, XRD, HSM, SEM and FT-IR. TGA showed that the commercial samples are dihydrate and the sample prepared from water/ethanol (1:1) was a monohydrate. Solubility studies revealed that monohydrate converted to dihydrate during solubility studies and as a result there was no significant difference in the equilibrium solubility of MH and DH. Thermal analysis under various conditions revealed that dehydration and melting took place simultaneously. Anhydrous AZI was found to be hygroscopic and converted to DH on storing at room temperature. Molecular modeling studies revealed the probable sites of attachment of water molecules to AZI.

Transdermal iontophoresis of insulin: II. Physicochemical considerations

Transdermal iontophoresis is one of the potential enhancement strategies for the delivery of large and charged molecules. Insulin, a polypeptide of 6 kDa was used as a model for large peptides to understand the influence of peptide concentration, NaCl concentration, buffer type and its concentration on the transport efficiency of iontophoresis. Maximum enhancement was found at 3 mg/ml (75 IU/ml). The permeation of insulin was found to increase up to 0.05 M NaCl and decreased at higher concentrations of NaCl. The glucose permeation studies showed that permeation of insulin increased in the presence of NaCl due to ion induced convective flow. The flux enhancement of insulin in the presence of phthalate buffer was higher in comparison to citrate buffer, but the enhancement in these two buffers was the same in the presence of 0.05 M NaCl, which was also supported by a similar trend in conductivity values. However, the solution conductivity values did not reflect the influence of co-ions and counter ions on the transport of large peptides across the skin. Overall the findings revealed that the transport efficiency of large peptides like insulin may be improved by the optimisation of competing ions in solution.

Transdermal iontophoresis of insulin. Part 1: A study on the issues associated with the use of platinum electrodes on rat skin

We have studied the issues associated with the use of platinum electrodes for transdermal iontophoretic delivery of peptides, using insulin as a model peptide. Insulin permeation was studied using full‐thickness rat skin by varying the donor solution pH as a function of electrode polarity. The stability of insulin under the iontophoretic conditions was studied using TLC, SDS‐polyacrylamide gel electrophoresis and HPLC. Large pH shifts were observed during anodal iontophoresis (AI), when the donor solution pH was above the isoelectric point of insulin and in cathodal iontophoresis (CI), when the donor solution pH was below the isoelectric point of insulin. The direction and magnitude of electroosmotic flow was influenced by pH of the donor solution and the electrode polarity. On the other hand, the buffer used to maintain the pH governed the contribution of electrorepulsion to the overall transport of insulin. Electrochemical degradation of insulin was significant during Al at pH 7.4. Among the pH investigated, Al of insulin at pH 3.6 and Cl at pH 8.35 were better, as the pH shift was relatively less and electrochemically more stable during iontophoresis as compared with other pH. In summary, the pH shift caused by platinum electrodes had a significant influence on the permeation and stability of insulin.