The effect of particle structure of chitosan-coated liposomes and type of chitosan on oral delivery of calcitonin

To optimize the properties of chitosan-coated liposomes for oral administration of peptide drugs, we examined the effect of type of chitosan and the structure of liposomal systems on the mucoadhesiveness of liposomes and resultant pharmacological effects of the liposomal peptide drug. A low-molecular weight chitosan (LCS) and a high-molecular weight chitosan (CS) were used as coating polymers of liposomes containing elcatonin (eCT). The muco-penetrative behaviors across the mucous gel layer covering the intestinal epithelial cells and the pharmacological effect after intragastric administration were determined in rats. The results showed that both LCS-coated liposomes (LCS-Lips) and CS-coated liposomes (CS-Lips) could permeate the mucous layer in the small intestine. The most interesting result was that LCS-Lips containing eCT showed remarkably more prolonged effectiveness in decreasing the blood calcium concentration than did CS-Lips containing eCT, moreover, it was also found that LCS had more efficiency to protect eCT from the enzymatic degradation than CS. In comparing the area above the plasma calcium concentration time curves (AAC) values among eCT-containing liposomes with different structures, i.e. eCT adsorbed on coated liposomes (eCT-ad-CS-Lip, eCT-ad-LCS-Lips) and eCT encapsulated in coated liposomes (eCT-encap-CS-Lips, eCT-encap-LCS-Lips), eCT-encap-CS-Lip showed much higher effectiveness than eCT-ad-CS-Lip. However, the AAC value for eCT-ad-LCS-Lip was comparable to that for eCT-encap-CS-Lip, while the value for eCT-ad-CS-Lip was nearly zero. These results suggested that LCS is a good mucoadhesive polymer candidate for enhancing the bioavailability of orally administered peptide containing liposomes, while encapsulation of eCT within the liposomal particles is important to protect eCT against enzymatic degradation in the gastrointestinal (GI) tract.     

Properties of liposomes coated with hydrophobically modified chitosan in oral liposomal drug delivery

Chitosan (CS) has been widely used as an adhesive coating polymer for oral liposomal drug delivery systems because of its adhesive properties on mucous layers. The coating mechanism or interaction of chitosan and liposomes or mucin mainly depends on electrostatic forces. Thus, to enhance the adhesive properties of chitosan, a hydrophobically modified chitosan, i.e., dodecylated chitosan (DC), was synthesized. BIACORE results showed that both CS and DC could interact with mucin. Differences in sensorgram patterns between chitosan-mucin and dodecylated chitosan-mucin were observed and tentatively attributed to differences in binding kinetics. The zeta potential of dodecylated chitosan-coated liposomes (DC-Lip) showed positive values in both liposomal formulations, i.e., negatively charged and neutral-charge liposomes. These results indicated that DC could be considered a more suitable polymer for coating neutral-charge liposomes than CS because the hydrophobic side chain of DC inserts itself into the lipid bilayer of liposomes. Moreover, CS seemed to be less effective in the coating of a neutral-charge liposome because of the low positive values of its zeta potential. CS provided solely electrostatic forces when used for coating liposomes while DC provided electrostatic and hydrophobic forces due to the long alkyl chain in its backbone. Confocal Laser Scanning Microscopy (CLSM) images indicated that both chitosan-coated liposomes (CS-Lip) and DC-Lip could adhere to and penetrate through the small intestine of rats after oral administration. The pharmacological results showed that DC-Lip had a greater effect in decreasing blood calcium concentration during the first 12 h compared with CS-Lip. Therefore, it can be concluded that dodecylated chitosan can be useful in designing oral liposomal drug delivery systems.     

N-trimethyl chitosan-modified liposomes as carriers for oral delivery of salmon calcitonin

Therapeutic peptide and protein drugs have high specificity and activity in their functions but present challenges in their administration route, requiring development of new delivery systems to improve their bioavailability. The aim of this work was to investigate the role of N-trimethyl chitosan- (TMC-) coated liposomes in the oral administration of calcitonin. TMC with a degree of quaternization around 78% was synthesized and its mucoadhesive properties were examined in vitro using the mucin-particle method, which confirmed that TMC showed mucoadhesion comparable to that of chitosan. TMC-coated liposomes containing calcitonin were prepared and characterized as having a particle size of 262 nm, zeta potential of 35.8 mV and high entrapment efficiency (89.1%). The in vivo evaluation of mucoadhesion was carried out using confocal laser microscopy to observe the residence time and permeation extent after intragastric administration. The results showed that TMC-coated liposomes prolonged the residence time and increased the penetration effect of the liposomal system compared to non-coated liposomes. The study of pharmacological effects confirmed that TMC-coated liposomes increased the area above the blood calcium concentration-time curves (AAC) from 3.13?±?20.50 to 448.84?±?103.56 compared to the calcitonin solution. These results support the feasibility of TMC-coated liposomes as a new oral delivery system for peptide and protein drugs.     

N-trimethyl chitosan-modified liposomes as carriers for oral delivery of salmon calcitonin

Therapeutic peptide and protein drugs have high specificity and activity in their functions but present challenges in their administration route, requiring development of new delivery systems to improve their bioavailability. The aim of this work was to investigate the role of N-trimethyl chitosan- (TMC-) coated liposomes in the oral administration of calcitonin. TMC with a degree of quaternization around 78% was synthesized and its mucoadhesive properties were examined in vitro using the mucin-particle method, which confirmed that TMC showed mucoadhesion comparable to that of chitosan. TMC-coated liposomes containing calcitonin were prepared and characterized as having a particle size of 262?nm, zeta potential of 35.8 mV and high entrapment efficiency (89.1%). The in vivo evaluation of mucoadhesion was carried out using confocal laser microscopy to observe the residence time and permeation extent after intragastric administration. The results showed that TMC-coated liposomes prolonged the residence time and increased the penetration effect of the liposomal system compared to non-coated liposomes. The study of pharmacological effects confirmed that TMC-coated liposomes increased the area above the blood calcium concentration-time curves (AAC) from 3.13?±?20.50 to 448.84?±?103.56 compared to the calcitonin solution. These results support the feasibility of TMC-coated liposomes as a new oral delivery system for peptide and protein drugs.     

Pulmonary delivery of elcatonin using surface-modified liposomes to improve systemic absorption: Polyvinyl alcohol with a hydrophobic anchor and chitosan oligosaccharide as effective surface modifiers

The aim of this study was to investigate the feasibility of surface-modified liposomes for pulmonary delivery of a peptide. Chitosan oligosaccharide (oligoCS) and polyvinyl alcohol with a hydrophobic anchor (PVA-R) were used as surface modifiers. The effect of liposomal surface modification on the behavior of the liposomes on pulmonary administration and potential toxicity were evaluated in vitro and in vivo. In an association study with A549 cells, PVA-R modification reduced interaction with A549 cells, whereas oligoCS modification electrostatically enhanced cellular interaction. The therapeutic efficacy of elcatonin (eCT) after pulmonary administration to rats was significantly enhanced and prolonged for 48 h after separate administration with oligoCS- or PVA-R-modified liposomes. oligoCS-modified liposomes adhered to lung tissues and caused opening of tight junctions, which enhanced eCT absorption. On the other hand, PVA-R-modified liposomes induced long-term retention of eCT in the lung fluid, leading to sustained absorption. Consequently, surface modification of liposomes with oligoCS or PVA-R has potential for effective peptide drug delivery through pulmonary administration.     

Mucoadhesive chitosan-coated liposomes: characteristics and stability

Lecithin liposomes, empty or containing FITC-dextran, were prepared by the ethanol injection method. Three different types of chitosans with different molecular weight and degrees of deacetylation were used (Seacure 113, 210 and 311). Chitosan coating was carried out by mixing the liposomal suspension with the chitosan solution followed by incubation. The size of liposomes was measured before and after polymer coating by an image analysis technique. The mean diameter of liposomes containing FITC-dextran was in the size range 250-280nm, whereas the size after coating was 300-330nm, regardless of chitosan type. All chitosan-coated liposomes were of spherical shape and no morphological differences between uncoated and coated liposomes were observed. Liposomes with FITC-dextran, originally entrapping 50% of the marker substance taken in the preparation and coated in the presence of unentrapped marker substance, contained 60-65%of the marker substance. The highest entrapment was found for liposomes coated with medium molecular weight chitosan. The stability of chitosan-coated liposomes in simulated gastric fluid was significantly higher as compared to uncoated liposomes. One can conclude that chitosan is stabilizing the original liposomal structure and protecting liposomally entrapped drug.     

Mucoadhesive chitosan-coated liposomes: characteristics and stability

Lecithin liposomes, empty or containing FITC-dextran, were prepared by the ethanol injection method. Three different types of chitosans with different molecular weight and degrees of deacetylation were used (Seacure 113, 210 and 311). Chitosan coating was carried out by mixing the liposomal suspension with the chitosan solution followed by incubation. The size of liposomes was measured before and after polymer coating by an image analysis technique. The mean diameter of liposomes containing FITC-dextran was in the size range 250-280 nm, whereas the size after coating was 300-330 nm, regardless of chitosan type. All chitosan-coated liposomes were of spherical shape and no morphological differences between uncoated and coated liposomes were observed. Liposomes with FITC-dextran, originally entrapping 50% of the marker substance taken in the preparation and coated in the presence of unentrapped marker substance, contained 60-65% of the marker substance. The highest entrapment was found for liposomes coated with medium molecular weight chitosan. The stability of chitosan-coated liposomes in simulated gastric fluid was significantly higher as compared to uncoated liposomes. One can conclude that chitosan is stabilizing the original liposomal structure and protecting liposomally entrapped drug.     

Enteral Absorption of Insulin in Rats from Mucoadhesive Chitosan-Coated Liposomes

Purpose. The mucoadhesiveness of polymer-coated liposomes was evaluated to develop a novel drug carrier system for oral administration of poorly absorbed drugs such as peptide drugs. Methods. Multilamellar liposomes consisting of dipalmitoylphosphatidylcholine (DPPC) and dicetyl phosphate (DCP) (DPPC:DCP = 8:2 in molar ratio) were coated with chitosan (CS), polyvinyl alcohol having a long alkyl chain (PVA-R) and poly (acrylic acid) bearing a cholesteryl group. The adhesiveness of the resultant polymer-coated liposomes to the rat intestine was measured in vitro by a particle counting method with a Coulter counter. The CS-coated liposomes containing insulin were administered to normal rats and the blood glucose level was monitored. Results. The existence of polymer layers on the surface of liposomes was confirmed by measuring the zeta potential of liposomes. The CS-coated liposomes showed the highest mucoadhesiveness and the degree of adhesion was dependent on the amount of CS on the surface of the liposomes. The blood glucose level of rats was found to be significantly decreased after administration of the CS-coated liposomes containing insulin. The lowered glucose level was maintained for more than 12h after administration of the liposomal insulin, which suggested mucoadhesion of the CS-coated liposomes in the intestinal tract of the rats.     

Development and characterization of polymer-coated liposomes for vaginal delivery of sildenafil citrate

Vaginal administration of sildenafil citrate has shown recently to develop efficiently the uterine lining with subsequent successful embryo implantation following in vitro fertilization. The aim of the present study was to develop sildenafil-loaded liposomes coated with bioadhesive polymers for enhanced vaginal retention and improved drug permeation. Three liposomal formulae were prepared by thin-film method using different phospholipid:cholesterol ratios. The optimal liposomal formulation was coated with bioadhesive polymers (chitosan and HPMC). A marked increase in liposomal size and zeta potential was observed for all coated liposomal formulations. HPMC-coated liposomes showed the greater bioadhesion and higher entrapment efficiency than chitosan-coated formulae. The in vitro release studies showed prolonged release of sildenafil from coated liposomes as compared to uncoated liposomes and sildenafil solution. Ex vivo permeation study revealed the enhanced permeation of coated relative to uncoated liposomes. Chitosan-coated formula demonstrated highest drug permeation and was thus selected for further investigations. Transmission electron microscopy (TEM) and Fourier transform infrared spectroscopy (FTIR) confirmed the successful coating of the liposomes by chitosan. Histopathological in vivo testing proved the efficacy of chitosan-coated liposomes to improve blood flow to the vaginal endometrium and to increase endometrial thickness. Chitosan-coated liposomes can be considered as potential novel drug delivery system intended for the vaginal administration of sildenafil, which would prolong system's retention at the vaginal site and enhance the permeation of sildenafil to uterine blood circulation.     

Hypoglycemic efficacy of chitosan-coated insulin liposomes after oral administration in mice

INTRODUCTION In the past two decades the potential usefulnessof liposomes as drug carriers for improving enteral ab-sorption of poorly absorbed drugs including peptidedrugs such as insulin has attracted considerable interest.These phospholipid vesicles are capable of encapsulat-ing both hydrophobic and hydrophilic drugs; they arebiodegradable and are not toxic in vivo. The drugsencapsulated in liposomes are sufficiently protectedfrom enzymatic attack and immune recognition[1]. Li-po…     

Liposomal vasoactive intestinal peptide for lung application: Protection from proteolytic degradation.

Inhalative administration of vasoactive intestinal peptide (VIP) is a promising approach for the treatment of severe lung diseases. However, the clinical use of VIP is limited by the fact that the peptide is prone to rapid degradation mechanisms and proteolytic digestion. Accordingly, VIP exhibits a very short period of activity in the lung. To overcome this problem, we have designed a liposomal drug delivery system for VIP and characterized it in terms of its potential to protect VIP from enzymatic cleavage. The proteolytic conditions of the lung, the target site of aerosolic administered VIP, were mimicked by bronchoalveolar lavage fluid (BALF), a lung surfactant solution, obtained by fiberoptic bronchoscopy. Thus, the stability of VIP was assessed by its resistance to enzymatic degradation in BALF, using a combination of high pressure liquid chromatography with mass spectrometry. We found that free VIP was rapidly digested, whereas liposomal-associated VIP remained intact. By fluorescence spectroscopic techniques using fluorescent-labelled VIP we got strong indications that the tight association of VIP with the lipid membrane is only minimally affected upon incubation with BALF. Loading capacity and stability of EtCy3-VIP loaded liposomes were measured by fluorescence fluctuation spectroscopy. Finally, the protective properties of the liposomes were also expressed in the maintained biological activity of the peptide incubated with BALF.     

Chitosan‐coated antifungal formulations for nebulisation

Objectives The aim of this study was to produce and characterise amphotericin B (AmB) containing chitosan‐coated liposomes, and to determine their delivery from an air‐jet nebuliser. Methods Soya phosphatidylcholine : AmB (100 : 1) multilamellar vesicles were generated by dispersing ethanol‐based proliposomes with 0.9% sodium chloride or different concentrations of chitosan chloride. These liposomes were compared with vesicles produced by the film hydration method and micelles. AmB loading, particle size, zeta potential and antifungal activity were determined for formulations, which were delivered into a two‐stage impinger using a jet nebuliser. Key findings AmB incorporation was highest for liposomes produced from proliposomes and was greatest (approximately 80% loading) in chitosan‐coated formulations. Following nebulisation, approximately 60% of the AmB was deposited in the lower stage of the two‐stage impinger for liposomal formulations, for which the mean liposome size was reduced. Although AmB loading in deoxycholate micellar formulations was high (99%), a smaller dose of AmB was delivered to the lower stage of the two‐stage impinger compared to chitosan‐coated liposomes generated from proliposomes. Chitosan‐coated and uncoated liposomes loaded with AmB had antifungal activities against Candida albicans and C. tropicalis similar to AmB deoxycholate micelles, with a minimum inhibitory concentration of 0.5 µg/ml. Conclusions This study has demonstrated that chitosan‐coated liposomes, prepared by an ethanol‐based proliposome method, are a promising carrier system for the delivery of AmB using an air‐jet nebuliser, having a high drug‐loading that is likely to be effectively delivered to the peripheral airways for the treatment of pulmonary fungal infections.     

Membrane-specific antibodies induced by liposomes can simultaneously bind to HIV-1 protein,peptide, and membrane lipid epitopes

Liposomes containing lipid A as an adjuvant and also containing either both (a) cholesterol and gp140 HIV envelope protein or (b) galactosylceramide and a 48 amino acid peptide from the membrane proximal external region of gp41 from HIV, as liposomal antigens were used for immunizing mice. Monoclonal antibodies from each type of immunization were obtained, which recognized either the lipid antigen or the protein (or peptide) antigen separately, or that simultaneously bound to both the lipid and protein (or peptide) antigens, by ELISA. After immunizing with liposomes containing both phosphatidylinositol 4-phosphate (PIP) and peptide antigen, a unique monoclonal antibody was also obtained, which did not bind separately either to the lipid or peptide antigen, or to the liposomes alone, but did bind to the original liposomal antigen containing the peptide but lacking PIP. Our data suggest that immunization with liposomes containing lipid A and also containing both a lipid and protein (or peptide) antigen induces antibodies that recognize broad topographical antigenic liposomal membrane surface patterns. These membrane-specific antibodies have unique binding characteristics.     

Chitosan-based liposomal thermogels for the controlled delivery of pingyangmycin: design,optimization and in vitro and in vivo studies

Pingyangmycin (PYM) has been applied clinically for many years to treat vascular malformations (VM) in China. The major limitation of PYM injections is quick diffusion from the injection site, which increases side effects, especially the possibility of pulmonary injury. In this paper, chitosan/glycerophosphate disodium (CS/GP) thermogels containing liposomes for sustained and localized PYM delivery were prepared and optimized by a three-level three-factorial Box–Behnken experimental design to evaluate the effects of different variables (the PYM concentration, CS amount and GP content), on the selected responses (cumulative percentage PYM released in 1?day, 9 days and the rate constant k). The results revealed that the optimized PYM liposomal thermogels had a controlled PYM release for 14 days in vitro, which confirmed the validity of optimization. In vitro morphological observation, cell cycle and apoptosis analysis showed an effective anti-proliferation action of PYM liposomal thermogels on human vascular endothelial cells (EA.hy926). In vivo pharmacokinetics research in rabbits displayed that compared with PYM liposomes and PYM thermogels, PYM liposomal thermogels had a better controlled delivery of PYM. Histological examination of rabbit ear veins showed that after local application with PYM lipsomal thermogels for 21 days, obvious vein thrombosis and inflammatory reaction could be observed. The above results indicated that PYM-loaded lipsomal CS/GP thermogels might have a good prospect for the treatment of VM.     

Application of surface‐coated liposomes for oral delivery of peptide: Effects of coating the liposome's surface on the GI transit of insulin

We prepared two kinds of surface‐coated liposomes and investigated their potencies as oral dosage forms for peptide drugs by focusing on their effects on the gastrointestinal (GI) transit of drugs. The surface of the liposomes was coated with poly(ethylene glycol) 2000 (PEG‐Lip) or the sugar chain of mucin (Mucin‐Lip). As a model peptide drug, insulin was encapsulated in these liposomes. Coating the surface with poly(ethylene glycol) was found to reduce the transit rate of liposomes in the small intestine after oral administration to rats in vivo. Mucin‐Lip was retained in the stomach longer than PEG‐Lip or uncoated liposomes. The effect of surface coating on the intestinal transit of liposomes was determined by means of in situ single pass perfusion in the rat small intestine. Statistical moment analysis was applied to the outflow pattern of both liposomes and encapsulated insulin. The mean transit time (MTT) and deviation of transit time (DTT) in the intestinal tract were calculated. The MTT of PEG‐Lip was much longer than those of uncoated liposomes and Mucin‐Lip and was significantly shortened after removal of the intestinal mucous layer. These results indicated that PEG‐Lip interacts strongly with the intestinal mucous layer, leading to its slow transit in the intestine. In contrast, coating the liposome's surface with mucin did not affect either the MTT or DTT of liposomes in the intestine. This result is in accordance with the in vivo observation that Mucin‐Lip was highly retained in the stomach, but not in any region of the small intestine in vivo. Both the MTT and DTT values of insulin encapsulated in PEG‐Lip and Mucin‐Lip were almost the same as those of liposomes themselves, suggesting that surface‐coated liposomes retained insulin in the intestinal tract. However, MTT and DTT of insulin were significantly shorter than those of uncoated liposomes because these liposomes degraded and released significant amounts of insulin during single pass perfusion. The ability of surface‐coated liposomes, especially of PEG‐Lip, to interact with the mucus layer and slow the transit rate in the GI tract is considered desirable for oral delivery of peptide drugs. Modification of the liposomal surface with appropriate materials, therefore, should be an effective method by which to achieve the oral delivery of peptide drugs.     

壳聚糖及其衍生物包覆脂质体对胰岛素肠道吸收的影响

目的考察壳聚糖及其衍生物包覆脂质体对胰岛素肠道吸收的影响。方法采用逆相蒸发制备胰岛素脂质体；采用在体肠灌流法研究壳聚糖及其衍生物包覆胰岛素脂质体的肠道吸收；用酶-苯酚法测定血糖值；用放射免疫法测定血清和肠组织中胰岛素含量。结果壳聚糖(CH)、壳聚糖-EDTA轭合物(CEC)包覆胰岛素脂质体和CH-CEC双层包覆胰岛素脂质体的最佳吸收部位均集中在十二指肠，胰岛素溶液的最佳吸收部位在结肠，而未包覆胰岛素脂质体和N-三甲基壳聚糖盐酸盐(TMC)包覆胰岛素脂质体的最佳吸收部位尚不能确定。在各肠段中，以CH-CEC双层包覆胰岛素脂质体的吸收最佳。结论壳聚糖及其衍生物包覆脂质体能促进胰岛素经肠道吸收，并可提高其在肠道中的稳定性。     

Oral absorption enhancement of salmon calcitonin by using both N-trimethyl chitosan chloride and oligoarginines-modified liposomes as the carriers

Abstract

In this study both N-trimethyl chitosan chloride (TMC) and oligoarginine (Arg8) were utilized to modify liposomes as the multifunctional carriers (TMC-Arg8-Lips) for enhancing the oral absorption of salmon calcitonin. Two permeation enhancers with positive charges were sequentially adsorbed on the liposomal surface with negative charges by electrostatic interaction. Instead of salmon calcitonin, fluorescein isothiocyanate dextran (FD4) was loaded in TMC-Arg8-Lips for Caco-2 cell permeation test in vitro and penetration examination in rat intestinal tract in vivo. The results showed that the apparent permeability coefficient (P_app) of TMC-Arg8-Lips containing FD4 were 7.0-, 4.4-, 1.8- and 1.4-folds higher than FD4 solution, FD4-TMC solution, non-modified liposomes (Non-Lips) and TMC modified liposomes (TMC-Lips), respectively. A strong fluorescence was observed by confocal laser scanning microscope (CLSM) at rat intestinal wall isolated in different times after the FD4 loaded carriers were intragastrically administrated. Furthermore, the images revealed that TMC-Arg8-Lips could penetrate deeply inside the mucosal membrane. The pharmacodynamic study indicated that TMC-Arg8-Lips containing calcitonin were more efficient in enhancing the absorption and prolonging the reduction of blood calcemia in rats. The area above the plasma calcium concentration–time curve (AAC) of TMC-Arg8-Lips containing calcitonin was increased by more than 16.6- and 1.6-fold when compared to Non-Lips and TMC-Lips, respectively.     

Evaluation of mucoadhesiveness of polymers by BIACORE method and mucin-particle method

To evaluate the reliability of the BIACORE method as a useful method for measuring the mucoadhesive interaction between chitosan and mucin, the mucin-particle method was used for comparison. In this study, the adhesivities of different-molecular-weight chitosans (chitosan Mw. 150,000, CS; low-molecular-weight chitosan, LCS) and hydrophobically modified chitosans (dodecylated CS, d-CS; dodecylated LCS, d-LCS) to mucin were determined. The BIACORE method showed that CS, LCS and d-CS could interact with mucin based on the increased resonance unit (RU) response after mucin was passed over the chitosans-immobilized sensor chip surface. Sensorgrams obtained from the interaction between these polymers and mucin also indicated the rate and strength of binding reaction. The rate and strength were higher for unmodified chitosans than hydrophobically modified chitosans. The simple in vitro mucoadhesive test or mucin-particle method revealed that the turbidity of unmodified chitosan/mucin mixtures was higher than that of dodecylated chitosans for all concentration of chitosans and mucin. The results from both BIACORE and the mucin-particle method implied that hydrophobic modification of chitosan reduced its adhesivity to mucin. The results from these two methods corresponded well. Therefore, the BIACORE method has promised as an alternative method for evaluating the adhesivity of adhesive polymers to mucin.     

Effectiveness of submicron-sized, chitosan-coated liposomes in oral administration of peptide drugs

The mucoadhesive behavior of chitosan-coated liposomes in the intestinal tract of the rat was examined to elucidate their particle size effects on the absorption of an entrapped drug, calcitonin. The intestine was removed from rats after oral administration of liposomes containing a fluorescent dye, and its various parts were observed with confocal laser scanning microscopy. Penetration of submicron-sized liposomes (ssLip) or chitosan-coated ssLip (ssCS-Lip) into the mucosa was observed, while such behavior was not observed for the multilamellar liposomes, even when coated with chitosan (CS-Lip). The retentive property of ssCS-Lip was confirmed by measuring the amount of dye in each part of the intestine. The pharmacologic effects of calcitonin-loaded liposomes of different particle size were measured after oral administration in rats. The pharmacologic effect of oral administration of ssLip coated with chitosan was detected up to 120 h after administration. The extensive pharmacologic effect of ssCS-Lip was attributed to their prolonged retention in the intestinal mucosa, partly owing to their penetrative property into the intestinal mucosa. The chitosan-coated ssLip, with their higher retentive property in the intestinal tract, are much more effective than ssLip and CS-Lip in improving the enteral absorption of peptide drugs.     

Chitosan–aprotinin coated liposomes for oral peptide delivery: Development, characterisation and in vivo evaluation

In order to improve the systemic uptake of therapeutic peptides/proteins after oral administration, the polymer-protease inhibitor conjugate chitosan–aprotinin was synthesised and polyelectrolyte complexes between negatively charged multilamellar vesicles (MLV) and positively charged chitosan–aprotinin conjugate were prepared. It could be demonstrated that chitosan–aprotinin was capable of significantly inhibiting Trypsin in vitro in concentrations of 0.05% and 0.1%, whereas no inhibition was observed in the presence of 0.1% chitosan. The size range of the prepared MLV was between 3 and 4.5 μm and the initially negative zeta potential (ca. −90 mV) of the core liposomes switched to a positive value after polymer coating (ca. +40 mV). Confocal laser microscopy studies showed comparable mucoadhesive properties of chitosan–aprotinin coated MLV and chitosan coated MLV. In comparison to calcitonin in solution, the area above the blood calcium concentration–time curve (AAC) after oral administration of calcitonin loaded chitosan coated MLV to rats increased around 11-fold, and around 15-fold in the case of calcitonin loaded chitosan–aprotinin coated MLV. Data gained in the current study are believed to contribute to the development of novel polymer-protease inhibitor based delivery systems.