Somasree Ray

Novel interpenetrating network microspheres of xanthan gum-poly(vinyl alcohol) for the delivery of diclofenac sodium to the intestine--in vitro and in vivo evaluation.

Xanthan gum (XG), a trisaccharide branched polymer and poly vinyl alcohol (PVA), was used to develop pH-sensitive interpenetrating network (IPN) microspheres by emulsion cross-linking method in the presence of glutaraldehyde as a cross-linker to deliver model anti-inflammatory drug, diclofenac sodium (DS) to the intestine. Various formulations were prepared by changing the ratio of XG:PVA, extent of cross-linking in order to optimize the formulation variables on drug encapsulation efficiency, and release rate. Formation of interpenetrating network and the chemical stability of DS after penetration of microspheres was confirmed by Fourier Transform infrared (FTIR) spectroscopy. Differential scanning calorimetry (DSC) and X-ray diffraction (XRD) analysis were done on the drug loaded microspheres which confirmed molecular dispersion of DS in the IPN. Microspheres formed were spherical with smooth surfaces, as evidenced by scanning electron microscopy (SEM), and mean particle size, as measured by laser light scattering technique ranged between 310.25–477.10 µm. Drug encapsulation of up to 82.94% was achieved as measured by UV method. Both equilibrium and dynamic swelling studies and in vitro release studies were performed in pH 1.2 and 6.8. Release data indicated a Fickian trend of drug release which depends on the extent of cross-linking and the ratio of XG:PVA present in the microsphere. When subjected to in vivo pharmacokinetic evaluation in rabbits, microparticles show slow and prolonged drug release when compared with DS solution. Based on the results of in vitro and in vivo studies it was concluded that these IPN microspheres provided oral controlled release of water-soluble DS.

Tailoring of locust bean gum and development of hydrogel beads for controlled oral delivery of glipizide

In this study, carboxymethyl derivative of locust bean gum was prepared, characterized, and its gelling ability with different concentrations (1–5% w/v) of aluminum chloride (AlCl3) was utilized for the development of glipizide-loaded beads in a completely aqueous environment. The beads were spherical when observed under a scanning electron microscope. Increase in gelling ion concentration decreased the drug entrapment efficiency from 97.68% to 95.14%. The beads swelled more slowly in pH 1.2 KCl-HCl buffer and exhibited a slower drug release pattern than that observed in pH 7.4 phosphate buffer. Irrespective of the dissolution media, the drug release became slower at higher AlCl3 concentration. The drug release in alkaline medium was found to be controlled by a combination of diffusion as well as polymer relaxation phenomena. Comparing the release profiles, it was observed that the beads treated with 5% AlCl3 provided slower drug release up to 10 h in alkaline medium without any sign of disintegration and, thus, this formulation was selected for further studies. Fourier transform infrared (FTIR) spectroscopy indicated the stable nature of the drug in the beads. Differential scanning calorimetry and X-ray diffraction analysis showed that most of the drug remained in amorphous state in the beads. Stability study indicated no statistical significant difference in drug entrapment efficiency of the beads. In vivo activity of the beads was tested and a prolonged hypoglycemic effect was achieved. Hence, carboxymethyl locust bean beads could be a potential carrier for controlled oral delivery of glipizide.

Carboxymethyl xanthan microparticles as a carrier for protein delivery

Xanthan gum (XG) was derivatized to sodium carboxymethyl xanthan gum (SCMXG) and then cross-linked with aluminium ions (Al+3) to prepare BSA-loaded microparticles (MPs) from a completely aqueous environment. The derivatized gum was characterized by various physical methods. Discrete and spherical BSA-loaded MPs were obtained from SCMXG solution, the pH of which was adjusted to 6 and 7 and the BSA entrapment efficiency was found to reach as high as 82%. The protein release in acidic dissolution medium was faster than that in alkaline dissolution medium and was accounted for the higher swelling ratio of the MPs in acidic environment. Moreover, the pH of the gum solution used to prepare the MPs also influenced the swelling and consequently protein release considerably.

Development and evaluation of xanthan gum-facilitated ethyl cellulose microsponges for controlled percutaneous delivery of diclofenac sodium

Development and evaluation of xanthan gum-facilitated ethyl cellulose microsponges for controlled percutaneous delivery of diclofenac sodium In this study, xanthan gum-facilitated ethyl cellulose microsponges were prepared by the double emulsification technique and subsequently dispersed in a carbopol gel base for controlled delivery of diclofenac sodium to the skin. Scanning electron microscopy revealed the porous, spherical nature of the microsponges. Increase in the drug/polymer ratio (0.4:1, 0.6:1, 0.8:1, m/m) increased their yield (79.1-88.5 %), drug entrapment efficiency (50.0-64.1 %), and mean particle diameter (181-255 μm). Compared to the microsponges with high drug/polymer ratio (0.8:1, m/m), the flux of entrapped drug through excised rat skin decreased by 19.9 % and 17.0 %, respectively, for the microsponges prepared at low and intermediate drug/polymer ratios. When an equivalent amount of pure drug (not entrapped into microsponges) was dispersed into the gel base and the flux was compared, the microsponges (drug/polymer ratio 0.8:1, m/m) were found to reduce the flux by 33.3 %. Whether the drug was dispersed either in un-entrapped or entrapped form into the gel base, the drug permeation through rat skin followed Higuchis diffusion kinetic model. The microsponges prepared at the lowest drug/polymer ratio exhibited a comparatively slower drug permeation profile and were hence considered most suitable for controlled drug delivery application. FTIR spectroscopy and DSC analyses indicated the chemically stable, amorphous nature of the drug in these microsponges. The gel containing these optimized microsponges was comparable to that of a commercial gel formulation and did not show serious dermal reactions. Hence, the microsponge system obtained at the lowest drug/polymer ratio could be useful for controlled release of diclofenac sodium to the skin. Razvoj i vrednovanje mikrospužvastih sustava etilceluloze i ksantan gume za kontroliranu perkutanu isporuku diklofenak natrija U radu su opisani mikrospužvasti sustavi s etilcelulozom i ksantan gumom pripravljeni metodom dvostruke emulzifikacije i dispergirani u podlogu s karbopol gelom za 0kontrolirano oslobađanje diklofenak natrija na kožu. Elektronska pretražna mikroskopija potvrdila je poroznu, sferičnu strukturu mikrospužvastih sustava. Povećanjem omjera lijeka i polimera (0,4:1, 0,6:1, 0,8:1, m/m) povećalo se iskorištenje (79,1-88,5 %), količina uklopljenog lijeka (50,0-64,1 %) i srednji promjer čestica (181-255 μ/m). Prolaz uklopljenog lijeka kroz izrezane komade kože štakora smanjio se za 19,9 %, odnosno 17,0 %, kada se omjer lijeka i polimera smanjio s visokog (0,8:1, m/m) na niski i srednji. Oslobađanje iz mikrospužvastih struktura s omjerom lijeka i polimera 0,8:1 (m/m) smanjeno je za 33,3 % u odnosu na oslobađanje ekvivalentne količina lijeka koji nije uklopljen već samo dispergiran u geliranu podlogu. Ako je lijek bio dispergiran kao neuklopljen ili kao uklopljen u geliranu podlogu, permeacija lijeka kroz kožu štakora slijedila je Higuchijev difuzijski kinetički model. Mikrospužvaste strukture pripravljene uz najniži omjer lijeka i polimera pokazale su sporiji permeacijski profil pa ih smatramo najpovoljnijima za kontrolirano oslobađanje lijeka. FTIR spektroskopija i DSC analiza pokazale su da je lijek u mikrospružvastim sustavima stabilan i amorfan. Gel s optimiranim mikrospužvastim sustavom sličan je komercijalnom gelu i ne pokazuje ozbiljne kožne reakcije. Sustav pripravljen s najnižim omjerom lijeka i polimera mogao bi biti pogodan za kontrolirano oslobađanje diklofenak natrija na kožu.

Adipic acid dihydrazide treated partially oxidized alginate beads for sustained oral delivery of flurbiprofen.

In this study, periodate oxidation of sodium alginate was controlled such that the oxidized alginate could form isolatable beads with Ca+2 ions. The beads of oxidized alginate having a degree of oxidation 1 mol%, entrapped 89% flurbiprofen and released almost all of its content within 1.5 h in pH 7.2 phosphate buffer solution. The beads were covalently crosslinked with adipic dihydrazide (ADH) in addition to ionic crosslinks and were characterized. Scanning electron microscopy revealed that the beads were spherical having smooth surfaces. The drug entrapment efficiency decreased (90–86%) with increasing concentration of ADH (2–6% w/v) in the gelation medium. However, the beads prolonged the drug release in alkaline dissolution medium up to 8 h depending upon the concentration of ADH. The beads prepared with 2% ADH swelled more rapidly and led to faster drug release in either pH 1.2 HCl solution or pH 7.2 phosphate buffer solution. The swelling tendencies were reduced and the drug release became slower with higher concentrations in either fluid. The drug diffusion from the beads followed super case II transport mechanism. FTIR spectroscopy indicated stable nature of flurbiprofen in the beads and therefore had potential as sustained oral delivery system for the drug.

Smart reticulated hydrogel of functionally decorated gellan copolymer for prolonged delivery of salbutamol sulphate to the gastro-luminal milieu.

A partially hydrolysed poly(acrylamide)-grafted-gellan (HPAmGG) copolymer was synthesised and characterised. Temperature- and concentration-dependent rheology and gel-like property of Gelrite gellan (GG) disappeared in HPAmGG copolymer. Smart HPAmGG hydrogel was fabricated with variation in aluminium chloride (AlCl3) strength and initial drug loading. The hydrogel reticulates seemed spherical and showed a maximum of ∼65% drug retention, but the assay was ∼22% lower for GG hydrogel. The drug release rate was inversely proportional to AlCl3 strength in simulated intestinal milieu (pH 7.4), but approximated a proportional relationship with drug load. HPAmGG hydrogel liberated only 10–17% content in simulated gastric milieu (pH 1.2) in 2 h. The release data correlated well with the pH-dependent swelling of hydrogel and indicated the anomalous drug diffusion mechanism. Differential scanning calorimetry, X-ray diffraction, and high-performance liquid chromatography analyses confirmed the amorphous nature of the drug and its stability in fresh and aged hydrogel. Hence, smart HPAmGG hydrogel had the potential to prolong drug release mimicking the variable pH of the gastrointestinal tract.

Polyethyleneimine-treated xanthan beads for prolonged release of diltiazem: in vitro and in vivo evaluation

The purpose of the study was to develop a multiunit sustained release dosage form of diltiazem hydrochloride using a natural polymer, sodium carboxymethyl xanthan gum and polyethyleneimine (PEI) from a completely aqueous environment. PEI treated diltiazem resin complex loaded beads were characterized by morphology, drug entrapment efficiency, in vitro and in vivo release behaviour. 40% and 80% drug was released in 2 hour in pH 1.2 and in 5 to 6 h in pH 6.8 respectively depending on the formulation variables. The prolonged release was attributed to decreased swelling of the beads due to PEI treatment. Maintaining the shape throughout the dissolution process, PEI treated diltiazem resin complex beads released the drug following non-Fickian transport phenomena. In vivo pharmacokinetic evaluation in rabbits shows slow and prolonged drug release when compared with diltiazem solution. The designed beads are suitable for prolonged release of a water soluble drug under a complete aqueous environment using natural gum.

Controlled delivery of bovine serum albumin from carboxymethyl xanthan microparticles.

Bovine serum albumin (BSA)-loaded carboxymethyl xanthan (CMX) microparticles were prepared following gelation of sodium carboxymethyl xanthan (SCMX) gum with different concentrations (1–5%) of aluminium chloride (AlCl3). The microparticles prepared using 1% AlCl3 were subsequently coated with 0.5% aqueous solution of either SCMX gum or sodium alginate. Both uncoated and coated microparticles were characterized for entrapment efficiency, surface morphology, particle size, in vitro release and protein stability. The uncoated microparticles became non-spherical and the mean diameter was found to increase with increasing AlCl3 concentration. Higher concentration of AlCl3 decreased BSA entrapment efficiency of the uncoated microparticles from 86–61%. Furthermore, BSA entrapment in coated microparticles was found lower (78–79%) than uncoated microparticles prepared using 1% AlCl3. Although, the uncoated microparticles released almost half of its content in NaCl-HCl buffer solution (pH 1.2) in 2 h, the alginate and xanthan coated microparticles did not liberate a substantial amount of entrapped protein within the same period and prolonged the release in PBS solution (pH 7.4) up to 10 and 12 h, respectively. The microparticles released the protein via diffusion and swelling of the polymer matrix. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that BSA integrity was well retained in the CMX microparticles.

Development of smart hydrogels of etherified gum ghatti for sustained oral delivery of ropinirole hydrochloride

Gum Ghatti (GG) is a water soluble complex polysaccharide obtained from Anogeissus latifolia. Due to its non toxic and excellent emulsifying characteristics, it was widely used in different pharmaceutical preparations. Currently another facet was explored for its utility as release retardant polymer in oral controlled drug delivery system. As GG solely was incapable of forming microspheres therefore modification of GG to Sodium carboxymethyl (NaCMGG) derivative was done by carboxymethylation process and its gel forming capacity was explored by the use of trivalent cation (Aluminium chloride) which results into complete microbead system in a complete aqueous environment for controlled delivery of Ropinirole Hydrochloride (RHCl). Rheological property of NaCMGG showed pseudoplastic shear thinning behavior. Spherical shape of bead was observed under scanning electron microscope. Depending upon the formulation variables, Drug entrapment efficiency (DEE) varies from 47.66±3.51 % to 71.4±2.65%., and 80 to 90% drug was released in 6h in pH 6.8 phosphate buffer. Drug release was governed by both fickian diffusion and polymer relaxation simultaneously. Compatible environment for drug entrapment was established by Fourier transform infrared (FTIR) spectroscopy and differential scanning calorimetry (DSC). Thus the modified derivative NaCMGG could be a promising polymer in biomedical application.

Novel gastroulcer protective micro(hydro)gels of sulfated locust bean gum-aluminium complex for immediate release of diclofenac sodium

In this study, carboxymethyl sulfate derivative (CLBS) of locust bean gum (LBG) was synthesized by varying the strength of sulfating reagent. CLBS was characterized by Fourier transform infrared (FTIR) spectroscopy, elemental analysis, and viscosity measurements. Furthermore, the degree of sulfation and carboxymethylation in CLBS was determined. Novel micro(hydro)gel particles of CLBS were fabricated in basic aluminum chloride solution and different concentration of diclofenac sodium was incorporated into these particles. Differential scanning calorimetry and FTIR analyses did not suggest any drug-polymer interaction. Spherical morphological structures of the particles were evident under scanning electron microscope. Regardless of the formulation variables, a maximum of ~60% drug entrapment efficiency was achieved. For a higher degree of substitution, CLBS particles disintegrated rapidly (~20 min) and released >80% drug in acidic medium (pH1.2 and pH4.0) in 60 min. However, the particles liberated only ~60% drug in phosphate buffer medium (pH6.8) during this period. Following disintegration of the particles, the pH of gastric environment elevated. In stomach histopathology, the ulcers were scored and it was estimated that CLBS afforded ~86% protection to the gastric mucosa from ulceration. Thus, the micro(hydro)gel particles of CLBS-aluminium complex could be useful for immediate analgesic effect of the drug without any significant gastric distress.