Chitosan/cyclodextrin nanoparticles as macromolecular drug delivery system.

The aim of this study was to generate a new type of nanoparticles made of chitosan (CS) and carboxymethyl-beta-cyclodextrin (CM-beta-CD) and to evaluate their potential for the association and delivery of macromolecular drugs. CS and CM-beta-CD or mixtures of CM-beta-CD/tripolyphosphate (TPP) were processed to nanoparticles via the ionotropic gelation technique. The resulting nanoparticles were in the size range of 231-383 nm and showed a positive zeta potential ranging from +20.6 to +39.7 mV. These nanoparticles were stable in simulated intestinal fluid pH 6.8 at 37 degrees C for at least 4h. Elemental analysis studies revealed the actual integration of CM-beta-CD to CS nanoparticles. Insulin and heparin used as macromolecular model drugs, could be incorporated into the different nanocarriers with association efficiencies of 85.5-93.3 and 69.3-70.6%, respectively. The association of these compounds led to an increase of the size of the nanoparticles (366-613 nm), with no significant modification of their zeta potentials (+23.3 to +37.1 mV). The release profiles of the associated macromolecules were highly dependent on the type of molecule and its interaction with the nanomatrix: insulin was very fast released (84-97% insulin within 15 min) whereas heparin remained highly associated to the nanoparticles for several hours (8.3-9.1% heparin within 8h). In summary, CS-CD (cyclodextrin) nanoparticles may be considered as nanocarriers for the fast or slow delivery of macromolecules.

In vivo evaluation of a nasal insulin delivery system based on thiolated chitosan.

The aim of this study was the preparation and in vivo evaluation of a nasal insulin delivery system based on thiolated chitosan. 2-Iminothiolane was covalently attached to chitosan. The resulting conjugate (chitosan-TBA) exhibited 304.9 +/- 63.5 micromol thiol groups per gram polymer. Microparticles were prepared via a new precipitation-micronization technique. The microparticulate delivery system comprised insulin, reduced glutathione and chitosan-TBA (Chito-TBA/Ins) or unmodified chitosan (Chito/Ins) and control microparticles were composed of insulin and mannitol (Mannitol/Ins). Due to a hydration process the size of Chito-TBA/Ins and Chito/Ins microparticles increased in phosphate buffer pH 6.8 2.6- and 2.2-fold, respectively. Fluorescent-labeled insulin-loaded chitosan-TBA microparticles showed a controlled release over 4 h. Chito-TBA/Ins administered nasally to rats led to an absolute bioavailability of 6.9 +/- 1.5%. The blood glucose level decreased for more than 2 h and the calculated absolute pharmacological efficacy was 4.9 +/- 1.4%. Chito/Ins, in comparison, displayed a bioavailability of 4.2 +/- 1.8% and a pharmacological efficacy of 0.7 +/- 0.6%. Mannitol/Ins showed a bioavailability of 1.6 +/- 0.4% and no reduction of the blood glucose level at all. According to these findings microparticles comprising chitosan-TBA seem to have substantial higher potential for nasal insulin administration than unmodified chitosan.

Thiolated chitosan microparticles: a vehicle for nasal peptide drug delivery.

The goal of this study was to develop a microparticulate delivery system based on a thiolated chitosan conjugate for the nasal application of peptides. Insulin was used as model peptide. For thiolation of chitosan 2-iminothiolane was covalently linked to chitosan. The resulting chitosan-TBA (chitosan-4-thiobutylamidine) conjugate featured 304.89+/-63.45 micromol thiol groups per gram polymer. 6.5% of these thiol groups were oxidised. A mixture of the chitosan-TBA conjugate, insulin and the permeation mediator reduced glutathione were formulated to microparticles. Control microparticles comprised unmodified chitosan and insulin. As second control served mannitol-insulin microparticles. All microparticulate systems were prepared via the emulsification solvent evaporation technique. In 100 mM phosphate buffer pH 6.8 chitosan-TBA-insulin microparticles swelled 4.39+/-0.52-fold in size, whereas chitosan based microparticles did not swell at all. Chitosan-TBA microparticles showed a controlled release of fluorescein isothiocyanate (FITC)-labelled insulin over 6 h. Nasal administered chitosan-TBA-insulin microparticles led to an absolute bioavailability of 7.24+/-0.76% (means+/-S.D.; n=3) in conscious rats. In contrast, chitosan-insulin microparticles and mannitol-insulin microparticles exhibited an absolute bioavailability of 2.04+/-1.33% and 1.04+/-0.27%, respectively (means+/-S.D.; n=4). Because of these results microparticles comprising chitosan-TBA and reduced glutathione seem to represent a useful formulation for the nasal administration of peptides.

Viscoelastic properties of a new in situ gelling thiolated chitosan conjugate.

The aim of this study was the synthesis of a new thiolated chitosan conjugate and the evaluation of its viscoelastic properties in vitro. The modification of chitosan was achieved by covalent attachment of isopropyl-S-acetylthioacetimidate to chitosan. The resulting conjugate (chitosan-TEA; chitosan-thioethylamidine) exhibited 300.7+/-27.4 micromol thiol groups per gram polymer and no disulfide bond. For rheological studies, the pH of 0.5% and 1% polymer solutions was adjusted to 6.5 in order to simulate a physiological pH-level. Both, 0.5% and 1% chitosan-TEA solutions showed the transition from sol to gel within 30 min. Within 6 h of incubation, the storage modulus of 0.5% and 1% chitosan-TEA increased 3354-fold and 6199-fold, whereas the loss modulus increased 11-fold and 38-fold, respectively. Frequency sweep measurements demonstrated an increase in crosslinking of the thiolated polymer as a function of time. The formation of inter- and/or intramolecular disulfide bonds was monitored indirectly via determining the decrease of thiol groups. Unmodified chitosan did not exhibit in situ gelling properties. The release of a fluorescent marker being incorporated in a 0.5% chitosan-TEA solution was significantly (p<0.001) slower, when the formulation was preincubated for one hour and consequently already highly crosslinked. The polymer generated within this study represents a promising novel tool for various drug delivery systems, where in situ gelling properties are advantageous.

Synthesis and in vitro evaluation of a novel thiolated chitosan.

In order to achieve the same properties as chitosan-4-thio-butyl-amidine and to overcome at the same time its insufficient stability, the aim of this study was to evaluate the imidoester reaction of isopropyl-S-acetylthioacetimidate for the chemical modification of chitosan and to study the properties of the resulting chitosan-thioethylamidine (TEA) derivative. The thioalkylamidine substitute was introduced without the formation of N-substituted non-thiol products. The resulting conjugates exhibited 1.05+/-0.17% or 139.68+/-17.13 micromol immobilized free thiol groups per gram polymer and a total amount of reduced and oxidized thiol groups of 1.81+/-0.65% or 179.46+/-67.95 micromol/g polymer. By the immobilization of thiol groups mucoadhesion was strongly improved due to the formation of disulfide bonds with mucus glycoproteins. Chitosan-TEA was investigated regarding to its mucoadhesive properties via tensile studies and the rotating cylinder method. In tensile studies the total work of adhesion of chitosan-TEA was increased 3.3-fold in comparison to unmodified chitosan. Results from the rotating cylinder method showed an improvement ratio of 8.9 for chitosan-TEA compared with unmodified chitosan. In spite of the immobilization of thiol groups onto chitosan its swelling behavior in aqueous solutions was not significantly altered. Cumulative release studies out of matrix tablets comprising the chitosan-TEA and the model compound fluorescence labeled dextrane (FD(4)) demonstrated a controlled release over 3h with a trend toward a pseudo-zero-order kinetic. Because of these features the new chitosan thioamidine conjugate might represent a promising new polymeric excipient for various drug delivery systems.

Nasal delivery of human growth hormone: in vitro and in vivo evaluation of a thiomer/glutathione microparticulate delivery system.

It was the aim of this study to develop and evaluate a nasal microparticulate delivery system for human growth hormone (hGH) based on the thiomer polycarbophil-cysteine (PCP-Cys) in combination with the permeation mediator glutathione (GSH). Microparticles were prepared by dissolving PCP-Cys/GSH/hGH (7.5:1:1.5), PCP/hGH (8.5:1.5), and mannitol/hGH (8.5:1.5) in demineralized water, followed by lyophilization and micronization. Particles were evaluated with regard to size distribution and swelling behavior using a laser diffraction particle size analyzer. The release of fluorescence-labelled hGH from microparticles was determined in Franz diffusion chambers. In vivo studies in rats were performed comparing the nasal bioavailability achieved by PCP-Cys/GSH/hGH microparticles with that of unmodified PCP/hGH microparticles and mannitol/hGH powder. PCP-Cys/GSH/hGH and PCP/hGH microparticles showed a comparable size distribution (80% in the range of 4.8-23 microm) and swelled to almost fourfold size in phosphate-buffered saline (PBS). Both formulations exhibited almost identical sustained drug release profiles. The intranasal administration of the PCP-Cys/GSH/hGH microparticulate formulation resulted in a relative bioavailability of 8.11+/-2.15%, which represents a 3-fold and 3.3-fold improvement compared to that of PCP/hGH microparticles and mannitol/hGH powder, respectively. The study suggests that the PCP-Cys/GSH/hGH nasal microparticulate formulation might represent a promising novel tool for the systemic delivery of hGH.

Thiomers: potential excipients for non-invasive peptide delivery systems.

In recent years thiolated polymers or so-called thiomers have appeared as a promising alternative in the arena of non-invasive peptide delivery. Thiomers are generated by the immobilisation of thiol-bearing ligands to mucoadhesive polymeric excipients. By formation of disulfide bonds with mucus glycoproteins, the mucoadhesive properties of these polymers are improved up to 130-fold. Due to formation of inter- and intramolecular disulfide bonds within the thiomer itself, dosage forms such as tablets or microparticles display strong cohesive properties resulting in comparatively higher stability, prolonged disintegration times and a more controlled release of the embedded peptide drug. The permeation of peptide drugs through mucosa can be improved by the use of thiolated polymers. Additionally some thiomers exhibit improved inhibitory properties towards peptidases. The efficacy of thiomers in non-invasive peptide delivery could be demonstrated by various in vivo studies. Tablets comprising a thiomer and pegylated insulin, for instance, resulted in a pharmacological efficacy of 7% after oral application to diabetic mice. Furthermore, a pharmacological efficacy of 1.3% was achieved in rats by oral administration of calcitonin tablets comprising a thiomer. Human growth hormone in a thiomer-gel was applied nasally to rats and led to a bioavailability of 2.75%. In all these studies, formulations comprising the corresponding unmodified polymer had only a marginal or no effect. According to these results drug carrier systems based on thiomers seem to be a promising tool for non-invasive peptide drug delivery.

Oral insulin delivery: the potential of thiolated chitosan-insulin tablets on non-diabetic rats.

It was the aim of this study to develop a delivery system providing an improved efficacy of orally administered insulin utilizing a thiolated polymer. 2-Iminothiolane was covalently linked to chitosan. The resulting chitosan-TBA (chitosan-4-thiobutylamidine) conjugate exhibited 453.5+/-64.1 micromol thiol groups per gram polymer. 3.1% of these thiol groups were oxidised. Additionally, the enzyme inhibitors BBI (Bowman-Birk-Inhibitor) and elastatinal were covalently linked to chitosan representing 3.5+/-0.1% and 0.5+/-0.03% of the total weight of the resulting polymer conjugate, respectively. Chitosan-TBA conjugate (5 mg), insulin (2.75 mg), the permeation mediator reduced glutathione (0.75 mg) and the two inhibitor conjugates (in each case 0.75 mg) were compressed to so-called chitosan-TBA-insulin tablets. Control tablets consisted of unmodified chitosan (7.25 mg) and insulin (2.75 mg). Chitosan-TBA-insulin tablets showed a controlled release of insulin over 8 h. In vitro mucoadhesion studies showed that the mucoadhesive/cohesive properties of chitosan were at least 60-fold improved by the immobilisation of thiol groups on the polymer. After oral administration of chitosan-TBA-insulin tablets to non-diabetic conscious rats, the blood glucose level decreased significantly for 24 h corresponding to a pharmacological efficacy of 1.69+/-0.42% (means+/-S.D.; n=6) versus s.c. injection. In contrast, neither control tablets nor insulin given in solution showed a comparable effect. According to these results the combination of chitosan-TBA, chitosan-enzyme-inhibitor conjugates and reduced glutathione seems to represent a promising strategy for the oral application of insulin.

Thiomers: development and in vitro evaluation of a peroral microparticulate peptide delivery system.

The aim of this study was to develop a peroral mucoadhesive microparticulate delivery system for peptide drugs. Microparticles containing either the mucoadhesive polymer poly(acrylic acid)-cysteine (PAA-Cys) or unmodified PAA, 15% insulin used as model peptide drug and 0, 30, 50 and 70% Eudragit RS (MP-RS0, MP-RS30, MP-RS50 and MP-RS70) were prepared by the emulsification solvent evaporation technique. Particle size distribution, release of incorporated insulin, mucoadhesive and swelling properties were examined. During preparation inter- and intramolecular cross-linking occurred, which could be quantified by the amount of disulfide bonds within the resulting particles; this was determined to be 69.2% of the total amount of thiol groups. This cross-linking led to a higher stability of the particles. Microparticles were spherical displaying a rough surface. The particle diameter was in the range of 1-110 microm in the following rank order beginning with the largest: MP-RS30>MP-RS50>MP-RS70=MP-RS0. The higher the ratio of Eudragit RS in the microparticles, the more prolonged was the release of insulin. In the case of MP-RS70, a sustained release over a time period of at least 60 min was achieved. Mucoadhesive properties and the capacity of water uptake followed the rank order: MP-RS0>MP-RS30>MP-RS50>MP-RS70. Compared to particles comprising unmodified PAA, the mucoadhesive properties of the thiolated microparticulate systems were up to 14-fold improved. According to these results PAA-Cys-Eudragit RS microparticles might be a promising tool for the peroral administration of peptide drugs.

Preparation and characterisation of thiolated poly(methacrylic acid)-starch compositions.

The development of mucoadhesive polymer systems, which start swelling in the intestine after oral administration without an enteric coating, might be the key for drug delivery systems exhibiting a prolonged intestinal residence time. The preparation and characterisation of such polymeric excipients was therefore the aim of this study. A poly(methacrylic acid)-cysteine conjugate (thiolated PMAA) exhibiting 747.8+/-30.9 micromol thiol groups per gram polymer was co-precipitated with starch at pH 3. The resulting thiolated PMAA-starch composition consisting of 24% thiolated PMAA and 76% starch was lyophilised and analysed with regard to its swelling behaviour as well as to its cohesive and mucoadhesive properties. Results demonstrated that the thiolated PMAA-starch composition does not swell at all in a simulated gastric fluid. In contrast, a 4- and 6-fold increase in weight by water uptake was observed at pH 5 and 7, respectively. Disintegration studies demonstrated improved cohesive properties due to the immobilisation of thiol groups on PMAA, which are involved in the formation of stabilising inter- and/or intrachain disulfide bonds. Tensile studies demonstrated a total work of adhesion of 90.2+/-15.2 and 27.5+/-2.9 microJ for thiolated PMAA-starch and PMAA-starch, respectively. These results were confirmed by mucoadhesion studies utilising the rotating cylinder method. Thiolated PMAA-starch represents therefore a promising novel mucoadhesive excipient, which might provide a prolonged residence time of various delivery systems in the intestine.

Preparation and in vitro characterization of poly(acrylic acid)-cysteine microparticles.

The purpose of the present study was to prepare and characterize a novel mucoadhesive microparticulate drug delivery system. Microparticles were prepared by the solvent evaporation emulsion technique using a poly(acrylic acid)-cysteine conjugate of an average molecular mass of 450 kDa with an amount of 308 micromol thiol groups per gram polymer. The cross-linking of thiol groups via the formation of disulfide bonds during this preparation process was pH-controlled. The resulting microparticles were characterized with regard to the degree of cross-linking and the amount of remaining free thiol groups, shape, size distribution and stability. Furthermore, the drug release behaviour using bromelain as model drug and the mucoadhesive properties were evaluated.Results demonstrated that the higher the pH of the aqueous phase was during the preparation process, the higher was the degree of cross-linking within the particles. However, even at pH 9, 8.9+/-2.2% of free thiol groups remained on the microparticles. Particles were of spherical and partially porous structure and had a main size in the range of 20-60 microm with a center at 35 microm. Because of the formation of disulfide bonds within the particles, they did not disintegrate under physiological conditions within 48 h. In addition, a controlled drug release of bromelain was achieved. Due to the immobilization of thiol groups on poly(acrylic acid), the mucoadhesive properties of the corresponding microparticles were improved threefold. These features should render poly(acrylic acid)-cysteine conjugate microparticles useful as drug delivery system providing a prolonged residence time on mucosal epithelia.

Systemic peptide delivery via the stomach: in vivo evaluation of an oral dosage form for salmon calcitonin.

It was the aim of this study to investigate the potential of stomach targeted delivery systems for systemic peptide administration using salmon calcitonin as a model drug. Chitosan was modified by the immobilization of thiol groups utilizing 2-iminothiolane in order to obtain a chitosan-4-thiobutylamidine conjugate (chitosan-TBA). Furthermore, a chitosan-pepstatin A conjugate was synthesized by a carbodiimide mediated linkage of the pepsin inhibitor to the polymer. The protective effect of this novel conjugate for calcitonin towards pepsin was evaluated in vitro. Minitablets (5 mg) were generated by direct compression of calcitonin, chitosan, chitosan-TBA, chitosan-pepstatin A conjugate and glutathione (GSH), respectively (A, 1:0:69:20:10; B, 1:79:0:20:0; C, 1:99:0:0:0). The drug release was investigated in an artificial gastric fluid. Biofeedback studies were performed in rats by determining the decrease in plasma calcium level after oral administration. The novel chitosan-pepstatin A conjugate displayed 291+/-58 nmol inhibitor per gram polymer (mean+/-S.D., n = 5). The chitosan-inhibitor conjugate showed a very strong protective effect for salmon calcitonin towards pepsinic degradation. A controlled drug release was provided by all tested dosage forms-A, B and C. Dosage form B led only to a slight reduction of the plasma calcium level, displaying a pharmacological efficacy versus i.v. injection of 0.41%, while dosage form C did not lead to any significant effect. In contrast, dosage form A led to a decrease in the plasma calcium level of 10% for at least 12 h. The pharmacological efficacy of this formulation was determined to be 1.35%. The study suggests that stomach targeted oral delivery might be a promising novel approach for noninvasive systemic peptide administration.

Improvement in the in situ gelling properties of deacetylated gellan gum by the immobilization of thiol groups.

The rheological properties of an in situ crosslinking thiolated deacetylated gellan gum were examined in vitro. Mediated by a carbodiimide, L-cysteine was covalently bound to deacetylated gellan gum (DGG). The deacetylated gellan gum-cysteine (DGG-Cys) conjugate displayed 216.53 +/- 59.54 micromol thiol groups per gram polymer (means +/- SD, n = 3). The thiolated polymer was capable of forming inter- and/or intramolecular disulfide bonds in aqueous solution (1.5%; m/m) at pH 7. After 6 h of incubation at room temperature, storage modulus, loss modulus, and complex viscosity increased 300-, 6.4-, and 26.6-fold, respectively, relative to the unthiolated polymer. Loss tangent of DGG-Cys was <1, indicating a gel, whereas the corresponding unmodified polymer had a loss tangent of >1, indicating a fluid. Frequency sweep measurements demonstrated an increase in crosslinking of the thiolated polymer as a function of time. DGG-Cys appeared to be superior to the unmodified polymer also in the presence of physiological cation concentrations found (e.g., in tear fluid and nasal secretion), which is referred to rheological properties. The polymer generated within this study represents a promising novel excipient for various drug delivery systems in which in situ gelling properties are favorable.