Pornsak Sriamornsak

Doxorubicin: an update on anticancer molecular action, toxicity and novel drug delivery systems

Objectives  The frontline drug doxorubicin has been used for treating cancer for over 30 years. While providing a cure in select cases, doxorubicin causes toxicity to most major organs, especially life‐threatening cardiotoxicity, which forces the treatment to become dose‐limiting.

Calcium pectinate gel beads for controlled release drug delivery : I. Preparation and in vitro release studies

Calcium pectinate gel (CPG) beads of indomethacin, a poorly soluble drug, were prepared by dispersing indomethacin in a solution of pectin and then dropping the dispersion into calcium chloride solution. The droplets instantaneously formed gelled spheres by ionotropic gelation. The effect of several factors such as pectin type, the presence of a hardening agent and the drug loading were investigated on the percentage of drug entrapped, size distribution and drug release from the CPG beads. The release characteristics were studied using the rotating basket dissolution method. Strong spherical beads with narrow size distributions, high yields and good entrapment efficiencies could be prepared. All factors investigated have significantly affected the release of indomethacin from CPG beads. The mechanism of drug release from CPG beads followed the diffusion controlled model for an inert porous matrix. Therefore, calcium pectinate gel could be a useful carrier for controlled release drug delivery of poorly soluble drugs.

Investigation of pectin as a carrier for oral delivery of proteins using calcium pectinate gel beads

A novel oral delivery of protein to the colon based on the polysaccharide pectin has been investigated using bovine serum albumin (BSA) as a model protein. Calcium pectinate gel (CPG) beads were prepared by extruding BSA-loaded pectin solution into agitated calcium chloride solution. Subsequent drying produced matrix beads in which BSA were embedded. In vitro experiments were conducted on the release of BSA from the CPG beads under conditions pertaining to those in vivo. Monitoring of release gives a sensitive indication of the behavior of pectin under the different conditions. The type of pectin and the presence of enzymes in the medium influence release characteristics. By changing the type of pectin it is possible to protect BSA during conditions of mouth to colon transit and susceptibility to enzymatic attack. Additionally, the release of BSA from CPG beads was strongly affected by cross-linking time but not particularly affected by the amount of protein added. The investigated factors also influenced bead sizes and entrapment efficiency. The results suggest that calcium pectinate gel beads are promising as a carrier for oral delivery of protein by means of colonic delivery.

Effect of calcium concentration, hardening agent and drying condition on release characteristics of oral proteins from calcium pectinate gel beads

Pectin has been investigated for its ability to produce solid calcium pectinate gel (CPG) beads containing bovine serum albumin (BSA). Several factors can influence the properties and release characteristics of the CPG beads. In this study, the effect of calcium concentration, hardening agent and drying condition on the encapsulation and release characteristics of BSA from the matrix gel beads made of calcium pectinate were studied. BSA release studies under conditions mimicking mouth to colon transit have shown that calcium pectinate protects the drug from being released completely in the physiological environment of the upper gastrointestinal tract, and is susceptible to the enzymatic action with consequent drug release. In addition, the release of BSA from CPG beads was strongly affected by calcium concentration and drying condition. However, the release was not particularly affected by the presence of hardening agent at the concentration of 1% or lower. Since the release of BSA as a model protein drug could be controlled by the regulation of the preparation conditions of CPG beads, the CPG beads may be used for a potential oral controlled release system for protein drugs.

Targeted therapy for cancer using pH-responsive nanocarrier systems

Most of the conventional chemotherapeutic agents used against cancer have poor efficacy. An approach to improve the efficacy of cancer chemotherapy is the development of carrier systems that can be triggered to release the anticancer drug in response to extracellular or intracellular chemical stimuli. To this end, pH-responsive nanocarriers have been developed to target drugs either to the slightly acidic extracellular fluids of tumor tissue or, after endocytosis, to the endosomes or lysosomes within cancer cells. These systems can release the drug by specific processes after accumulation in tumor tissues via the enhanced permeability and retention (EPR) effect or they can release the drugs in endosomes or lysosomes by pH-controlled hydrolysis after they are taken up by the cell via the endocytic pathway. This strategy facilitates the specific delivery of the drug while reducing systemic side-effects with high potential for improving the efficacy of cancer chemotherapy.

Application of pectin in oral drug delivery

Introduction: Biopolymers have been used extensively in the pharmaceutical field. Pectin, a biopolymer, has several unique properties that enable it to be used as an excipient or carrier for oral drug delivery systems. Accordingly, several investigators have identified the benefits of pectin-based delivery systems for oral drug administration. Areas covered: This review first describes the chemical structure, source and production, degree of esterification and gel formation properties of pectin. The application of pectin in various oral drug delivery platforms is also discussed, that is, controlled release systems, gastro-retentive systems, colon-specific delivery systems and mucoadhesive delivery systems. Expert opinion: Pectin from different sources provides different gelling abilities, due to variations in molecular size and chemical composition. Like other natural polymers, a major problem with pectin is inconsistency in reproducibility between samples, which may result in poor reproducibility in delivery characteristics. Scintigraphic studies and in vivo studies, in both animals and human volunteers, demonstrate the successful development of a pectin-based colon-specific drug delivery system. Pectin-based controlled release systems, gastro-retentive systems and mucoadhesive systems present promising approaches for increasing the bioavailability of drugs, but are in their infancy. A lack of direct correlation between in vitro release and in vivo absorption studies is a major concern with these systems.

Morphology and buoyancy of oil-entrapped calcium pectinate gel beads

A new emulsion-gelation method to prepare oil-entrapped calcium pectinate gel (CaPG) beads capable of floating in the gastric condition was designed and tested. The gel beads containing edible oil were prepared by either being gently mixed or homogenized an oil phase and a water phase containing pectin, and then extruded into calcium chloride solution with gentle agitation at room temperature. The gel beads formed were then separated, washed with distilled water, and dried at 37°C for 12 hours. A model of the emulsion-gelation process to illustrate the formation of oil-entrapped CaPG beads was proposed. The effect of selected factors, such as type of oil, percentage of oil, and type of pectin on morphology and floating properties was investigated. The oil-entrapped calcium pectinate gel beads floated if a sufficient amount of oil was used. Scanning electron photomicrographs demonstrated very small pores, ranging between 5 and 40 μm, dispersed all over the beads. The type and percentage of oil play an important role in controlling the floating of oil-entrapped CaPG beads. The results suggested that oil-entrapped CaPG beads were promising as a carrier for intragastric floating drug delivery.

Effect of degree of esterification of pectin and calcium amount on drug release from pectin-based matrix tablets.

The aim of this work was to assess the effect of 2 formulation variables, the pectin type (with different degrees of esterification [DEs]) and the amount of calcium, on drug release from pectin-based matrix tablets. Pectin matrix tablets were prepared by blending indomethacin (a model drug), pectin powder, and various amounts of calcium acetate and then tableting by automatic hydraulic press machine. Differential scanning calorimetry, powder x-ray diffraction, and Fourier transformed-infrared spectroscopy studies of the compressed tablets revealed no drug-polymer interaction and the existence of drug with low crystallinity. The in-vitro release studies in phosphate buffer (United States Pharmacopeia) and tris buffer indicated that the lower the DE, the greater the time for 50% of drug release (T50). This finding is probably because of the increased binding capacity of pectin to calcium. However, when the calcium was excluded, the pectins with different DEs showed similar release pattern with insignificant difference of T50. When the amount of calcium acetate was increased from 0 to 12 mg/tablet, the drug release was significantly slower. However, a large amount of added calcium (ie, 24 mg/tablet) produced greater drug release because of the partial disintegration of tablets. The results were more pronounced in phosphate buffer, where the phosphate ions induced the precipitation of calcium phosphate. In conclusion, both pectin type and added calcium affect the drug release from the pectin-based matrix tablets.

Studies on Pectins as Potential Hydrogel Matrices for Controlled-Release Drug Delivery

Polymeric hydrogels are widely used as controlled-release matrix tablets. In the present study, we investigated high-methoxy pectins for their potential value in controlled-release matrix formulations. The effects of compression force, ratio of drug to pectin, and type of pectin on drug release from matrix tablets were also investigated. The results of the in vitro release studies show that the drug release from compressed matrix tablets prepared from pectin can be modified by changing the amount and the type of pectin in the matrix tablets. However, compression force did not significantly affect the drug release. The mechanisms controlling release rate were discussed with respect to drug diffusion through the polymer matrices, but may be more complex.

Modification of theophylline release with alginate gel formed in hard capsules.

The aim of this work was to establish whether alginate gel formed spontaneously in hard gelatin capsules which modifies release of a model drug, theophylline. The effects of the alginate composition, the calcium addition, and the dissolution medium on drug release were also investigated. After the capsule shell dissolved in water, at neutral pH the gel layer of sodium alginate was formed immediately as the sodium alginate hydrated and swelled on contact with the aqueous medium. In acidic pH, the contents remained intact and the matrix shape was the same. Theophylline release from capsules containing different grades of alginate demonstrated different release patterns, depending on alginate composition and the pH of the medium. The capsules containing sodium/calcium salts of alginate showed the slowest drug release at neutral pH but the fastest in acidic medium. The presence of calcium acetate in the formulations influenced the drug release kinetics. The drug release in acidic medium showed a non-Fickian diffusion-controlled release, while those in water at neutral pH exhibited a Super Case II transport mechanism. The study also provides evidence that the behavior of alginate in forming the hydrated gel layer may explain the drug release behavior at different pHs.