Modified chitosans for oral drug delivery

The cationic polysaccharide chitosan has been extensively studied for oral drug delivery. In recent years, chemically modified chitosans developed in order to improve the properties of chitosan for oral drug delivery have gained increasing attention. Representatives of these novel polymers are trimethyl-chitosans, thiolated chitosans, carboxymethyl chitosan and derivatives, hydrophobic chitosans, chitosan succinate and phthalate, PEGylated chitosans and chitosan-enzyme inhibitor conjugates. Besides their use for oral delivery of therapeutic peptides and proteins, they have recently been evaluated regarding their potential for the delivery of other substance classes, including genes and efflux pump substrates. Within the current review, various modified chitosan derivatives, their properties and synthesis are discussed.     

Macromolecules as safe penetration enhancers for hydrophilic drugs—a fiction?

The early designs of a variety of low molecular weight transmucosal penetration enhancers for improved absorption of hydrophilic drugs (e.g. peptides and proteins) hampered their commercialization, primarily because of related mechanisms of action and inherent toxicities. During the past decade, however, novel types of macromolecular penetration enhancers, such as anionic polyacrylates and cationic chitosan and chitosan derivatives, have been developed. These polymers can enhance the paracellular permeability of mucosal epithelia (intestinal, nasal) by transiently opening the tight junctions, thereby increasing the paracellular absorption of hydrophilic and macromolecular drugs. Neither of these two classes of polymers interact with mucosal cell membrane components and consequently do not enhance transcellular transport of hydrophilic compounds. The polyacrylates and chitosan derivatives show no acute toxicity and are not absorbed. These characteristics favour the conclusion that both types of polymers are safe penetration enhancers for transmucosal delivery of hydrophilic drugs and offer promising prospects for novel pharmaceutical applications.     

Potential prospects of chitosan derivative trimethyl chitosan chloride (TMC) as a polymeric absorption enhancer: synthesis, characterization and applications

In recent years, researchers have been working extensively on various novel properties of polymers to develop increased efficiency of drug delivery and improve bioavailability of various drug molecules, especially macromolecules. Chitosan, a naturally occurring polysaccharide, because of its protonated/polymeric nature, provides effective and safe absorption of peptide and protein drugs. Its transmucosal absorption is, however, limited to acidic media because of its strong intermolecular hydrogen bonds. A new partially quaternized chitosan derivative, N-trimethyl chitosan chloride (TMC), has been synthesized with improved solubility, safety and effectiveness as an absorption enhancer at neutral pH and in aqueous environment. It enhances the absorption, especially of peptide drugs, by reversible opening of tight junctions in between epithelial cells, thereby facilitating the paracellular diffusion of peptide drugs. This derivative thus opens new perspectives as a biomaterial for various pharmaceutical applications/drug delivery systems. This review deals with the potential use of the quaternized chitosan derivative as a permeation enhancer for the mucosal delivery of macromolecular drugs along with its other biomedical applications.     

Thiolated chitosans: useful excipients for oral drug delivery

To improve the bioavailability of orally administered drugs, formulations based on polymers are of great interest for pharmaceutical technologists. Thiolated chitosans are multifunctional polymers that exhibit improved mucoadhesive, cohesive and permeation-enhancing as well as efflux-pump-inhibitory properties. They can be synthesized by derivatization of the primary amino groups of chitosan with coupling reagents bearing thiol functions. Various data gained in-vitro as well as in-vivo studies clearly demonstrate the potential of thiolated chitosans for oral drug delivery. Within the current review, the synthesis and characterization of thiolated chitosans so far developed is summarized. Features of thiolated chitosans important for oral drug delivery are discussed as well. Moreover, different formulation approaches, such as matrix tablets and micro-/nanoparticles, as well as the applicability of thiolated chitosans for the oral delivery of various substance classes including peptides and efflux pump substrates, are highlighted.     

Absorption enhancers for nasal drug delivery

This paper describes the basic concepts for the transmucosal delivery of drugs, and in particular the use of the nasal route for delivery of challenging drugs such as polar low-molecular-weight drugs and peptides and proteins. Strategies for the exploitation of absorption enhancers for the improvement of nasal delivery are discussed, including consideration of mechanisms of action and the correlation between toxic effect and absorption enhancement. Selected enhancer systems, such as cyclodextrins, phospholipids, bioadhesive powder systems and chitosan, are discussed in detail. Examples of the use of these enhancers in preclinical and clinical studies are given. Methods for assessing irritancy and damage to the nasal membrane from the use of absorption enhancers are also described. Finally, the mucosal use of absorption enhancers (chitosan) for the improved nasal delivery of vaccines is reported with reference to recent phase I/II clinical studies.     

Chitosan and its derivatives: potential excipients for peroral peptide delivery systems

In the 1990s chitosan turned out to be a useful excipient in various pharmaceutical formulations. By modifications of the primary amino group at the 2-position of this poly(beta1-->4 D-glucosamine), the features of chitosan can even be optimised according to a given task in drug delivery systems. For peroral peptide delivery these tasks focus on overcoming the absorption (I) and enzymatic barrier (II) of the gut. On the one hand, even unmodified chitosan proved to display a permeation enhancing effect for peptide drugs. On the other hand, a protective effect for polymer embedded peptides towards degradation by intestinal peptidases can be achieved by the immobilisation of enzyme inhibitors on the polymer. Whereas serine proteases are inhibited by the covalent attachment of competitive inhibitors such as the Bowman-Birk inhibitor, metallo-peptidases are inhibited by chitosan derivatives displaying complexing properties such as chitosan-EDTA conjugates. In addition, because of the mucoadhesive properties of chitosan and most of its derivatives, a presystemic metabolism of peptides on the way between the dosage form and the absorption membrane can be strongly reduced. Based on these unique features, the co-administration of chitosan and its derivatives leads to a strongly improved bioavailability of many perorally given peptide drugs such as insulin, calcitonin and buserelin. These polymers are therefore useful excipients for the peroral administration of peptide drugs.     

Chitosan and its salts for mucosal and transmucosal delivery

This review considers the application of chitosan and its salts in the delivery of drugs intended to act locally towards diseases of the mucosa itself (mucosal delivery), and to undergo systemic absorption by means of transmucosal routes (transmucosal delivery). Those chitosan properties that are particularly useful in mucosal and transmucosal delivery have been reviewed, such as mucoadhesion, penetration enhancement and peptidase inhibition behaviour. Chitosan bioactive properties have also been considered, such as anti-infective, haemostatic, wound healing and immune-stimulating activity. Chitosan is available with a wide range of molecular mass and deacetylation degree: the influence of these properties on polymer performance and solubility has been taken into account. As solubility in particular can strongly limit the results obtained at pH values close to neutrality, particular attention has been paid to chitosan salts and derivatives with modified solubility. Thanks to the presence of positively charged amino groups of the polymer, a subject of increasing interest is the exploitation of its interaction with acidic molecules having potential synergistic behaviour towards bioactive properties, or even with acidic drugs. The aim of the review is to describe not only some properties of chitosan, but also the way they can be modified by the acidic moiety.     

Targeted delivery of low molecular drugs using chitosan and its derivatives

Chitosan has prompted the continuous impetus for the development of safe and effective drug delivery systems because of its unique physicochemical and biological characteristics. The primary hydroxyl and amine groups located on the backbone of chitosan allow for chemical modification to control its physical properties. When the hydrophobic moiety is conjugated to a chitosan molecule, the resulting amphiphile may form self-assembled nanoparticles that can encapsulate a quantity of drugs and deliver them to a specific site of action. Chemical attachment of the drug to the chitosan throughout the functional linker may produce useful prodrugs, exhibiting the appropriate biological activity at the target site. Mucoadhesive and absorption enhancement properties of chitosan increase the in vivo residence time of the dosage form in the gastrointestinal tract and improve the bioavailability of various drugs. The main objective of this review is to provide an insight into various target-specific carriers, based on chitosan and its derivatives, towards low molecular weight drug delivery. The first part of the review is concerned with the organ-specific delivery of low molecular drugs using chitosan and its derivatives. The subsequent section considers the recent developments of drug delivery carriers for cancer therapy with special focus on various targeting strategies.     

Chitosans as absorption enhancers of poorly absorbable drugs: 3: Influence of mucus on absorption enhancement

Chitosans are potent nontoxic absorption enhancers after nasal administration but their effects on the intestinal epithelium in vivo has not been studied in detail. In this study, the effects of chitosans with varying molecular weights and degrees of acetylation on the absorption of a poorly absorbed model drug (atenolol) were studied in intestinal epithelial cell layers with or without a mucus layer and in an in situ perfusion model of rat ileum. The effects of the chitosans on epithelial morphology and release of lactate dehydrogenase (LDH) into the perfusate were investigated in the in situ model. The chitosans had pronounced effects on the permeability of mucus-free Caco-2 layers and enhanced the permeation of atenolol 10- to 15-fold, with different absorption kinetics for different chitosans, in accordance with previous results. In contrast, enhancement of atenolol absorption through rat ileum was modest. LDH release from the tissues perfused with chitosans did not increase, indicating that the chitosans were used at nontoxic concentrations. Morphological examination of the perfused ileal tissues revealed more mucus discharge from the tissues exposed to chitosans than from controls, which suggested that the discharged mucus may inhibit the binding of chitosan to the epithelial surface and hence decrease the absorption-enhancing effect. This hypothesis was supported by studies with intestinal epithelial HT29-H goblet cells covered with a mucus layer. The binding of chitosan to the epithelial cell surface and subsequent absorption-enhancing effects were significantly reduced in mucus-covered HT29-H cultures. When the mucus layer was removed prior to the addition of chitosan, the cell surface binding and absorption-enhancing effects of the chitosans were increased. We conclude that the modest absorption-enhancing effects of unformulated chitosan solutions in the perfused rat ileum are a result of the mucus barrier in this tissue. This effect may be overcome by increasing the local concentrations of both chitosan and drug, i.e,. through formulation of the chitosan into a particulate dosage form.     

Effect of chitosan structure properties and molecular weight on the intranasal absorption of tetramethylpyrazine phosphate in rats

The objective of this work was to assess and compare the absorption promoting effect of different molecular-weight chitosans, trimethyl chitosans and thiolated chitosans for intranasal absorption of 2,3,5,6-tetramethylpyrazine phosphate (TMPP). An in situ nasal perfusion technique in rats was utilized to test the rate and extent of TMPP absorption in situ. In vivo studies were carried out in rats and the pharmacokinetic parameters were calculated and compared with that of intravenous injection. All the chitosan derivatives investigated could enhance the intranasal absorption of TMPP significantly. However, thiolation could not improve the absorption-enhancing capacity of chitosan remarkably even when the thiolation ratio was as high as 152 μmol/g. In contrast, trimethylated chitosan exhibited stronger absorption-enhancing ability than the homopolymer chitosan. The permeation enhancing effect of chitosan increased with increasing molecular weight up to M_w 100 kDa. In vivo studies indicated that chitosan 100 kDa and TMC 50 kDa had comparable absorption-enhancing effect but chitosan 100 kDa functioned for more than 120 min versus 90 min for TMC. A good correlation was found between the in situ absorption data and plasma concentration in vivo for the polymers investigated. This study demonstrated that both chitosan structural features and chitosan molecular weight play a key role on promoting the intranasal absorption of TMPP. Taking safety reason into account, chitosan 100 kDa is the most promising as an intranasal absorption enhancer.     

Chitosan and its derivatives as intestinal absorption enhancers

Chitosan is a non-toxic, biocompatible polymer that has found a number of applications in drug delivery including that of absorption enhancer of hydrophilic macromolecular drugs. Chitosan, when protonated (pH<6.5), is able to increase the paracellular permeability of peptide drugs across mucosal epithelia. Chitosan derivatives have been evaluated to overcome chitosan's limited solubility and effectiveness as absorption enhancer at neutral pH values such as those found in the intestinal tract. Trimethyl chitosan chloride (TMC) has been synthesized at different degrees of quaternization. This quaternized polymer forms complexes with anionic macromolecules and gels or solutions with cationic or neutral compounds in aqueous environments and neutral pH values. TMC has been shown to considerably increase the permeation of neutral and cationic peptide analogs across Caco-2 intestinal epithelia. The mechanism by which TMC is enhancing the intestinal permeability is similar to that of protonated chitosan. It reversibly interacts with components of the tight junctions, leading to widening of the paracellular routes. This chitosan derivative does not provoke damage of the cell membrane, and does not alter the viability of intestinal epithelial cells. Co-administrations of TMC with peptide drugs were found to substantially increase the bioavailability of the peptide in both rats and juvenile pigs compared with administrations without the polymer.     

Oral drug absorption enhancement by chitosan and its derivatives.

Chitosan is a non-toxic, biocompatible polymer that has found a number of applications in drug delivery including that of absorption enhancer of hydrophilic macromolecular drugs. Chitosan, when protonated (pH<6.5), is able to increase the paracellular permeability of peptide drugs across mucosal epithelia. Chitosan derivatives have been evaluated to overcome chitosan's limited solubility and effectiveness as absorption enhancer at neutral pH values such as those found in the intestinal tract. Trimethyl chitosan chloride (TMC) has been synthesized at different degrees of quaternization. This quaternized polymer forms complexes with anionic macromolecules and gels or solutions with cationic or neutral compounds in aqueous environments and neutral pH values. TMC has been shown to considerably increase the permeation and/or absorption of neutral and cationic peptide analogs across intestinal epithelia. The mechanism by which TMC enhances intestinal permeability is similar to that of protonated chitosan. It reversibly interacts with components of the tight junctions, leading to widening of the paracellular routes. Mono-carboxymethylated chitosan (MCC) is a polyampholytic polymer, able to form visco-elastic gels in aqueous environments or with anionic macromolecules at neutral pH values. MCC appears to be less potent compared to the quaternized derivative. Nevertheless, MCC was found to increase the permeation and absorption of low molecular weight heparin (LMWH; an anionic polysaccharide) across intestinal epithelia. Neither chitosan derivative provokes damage of the cell membrane, and therefore they do not alter the viability of intestinal epithelial cells.     

Effects of N-trimethyl chitosan chloride, a novel absorption enhancer, on caco-2 intestinal epithelia and the ciliary beat frequency of chicken embryo trachea.

N-trimethyl chitosan (TMC) polymers are quaternized chitosans in different degrees of trimethylation. These polymers enhance the absorption of macromolecules through mucosal epithelia by triggering the reversible opening of tight junctions and only allow for paracellular transport. To investigate the safety of these novel absorption enhancers cytotoxicity and ciliotoxicity studies have been performed. Intestinal Caco-2 cell monolayers were chosen to study possible membrane damaging effects of these polymers, using confocal laser scanning microscopy visualization of nuclear staining by a membrane impermeable fluorescent probe during transport of the paracellular marker Texas red dextran (MW 10 000). Ciliated chicken embryo trachea tissue was used to study the effect of the polymers on the ciliary beat frequency (CBF) in vitro. In both studies the TMC polymers of different degrees of substitution (20, 40 and 60%) were tested at a concentration of 1.0% (w/v). No substantial cell membrane damage could be detected on the Caco-2 cells treated with TMCs, while the effect on the CBF in vitro was found to be marginal. TMC60 and TMC40 enhance paracellular transport of Texas red dextran in Caco-2 cell monolayers, whereas TMC20 is ineffective. In conclusion, TMCs of high degrees of substitution may be effective and safe absorption enhancers for peptide and protein drug delivery.     

The use of multifunctional polymers for non-invasive peptide and protein application

For the efficient delivery of peptide and protein drugs by non-invasive routes various strategies have been pursued to overcome enzymatic and mucosal barriers to gain sufficient bioavailability. Among such delivery systems multifunctional polymers have received considerable attention, which is reflected by numerous publications and patents. They are able to provide a controlled release for therapeutic peptides and proteins being embedded in the polymeric network either based on a simple diffusion process or on the biodegradation of the carrier matrix. Additionally, polymers such as polyacrylates display an inhibitory effect towards various proteases located on the absorption membrane. In combination with enzyme inhibitors, this protective effect towards enzymatic attack may further be improved. Moreover, polyacrylates and chitosan display a permeation enhancing effect, in particular for the paracellular uptake of peptide drugs from mucosal tissues. If these polymers also exhibit mucoadhesive properties, the concentration gradient of the drug on the mucosa can be increased and in the case of oral delivery the presystemic enzymatic degradation of the (poly)peptide drug in the intestine between the delivery system and the absorption membrane can be reduced. Delivery systems utilising multifunctional polymers include formulations such as nano- and microspheres, pellets and matrix-tablets.     

Chitosans as nasal absorption enhancers of peptides: comparison between free amine chitosans and soluble salts

A total of three free amine chitosans (CS J, CS L and CS H) and two soluble chitosan salts (CS G and CS HCl) were evaluated for their efficacy and safety as nasal absorption enhancers of peptides based on in situ nasal perfusion and subacute histological evaluation in rat. At 0.5% w/v, all chitosans were effective in enhancing the nasal absorption of [D-Arg(2)]-Kyotorphin, an enzymatically stable opioid dipeptide. The enhancing effect of the free amine chitosans increased as the pH was decreased from 6.0 to 4.0 (P<0.05). However, the pH effect was not significant for the two chitosan salts (P0.05), suggesting that their adjuvant activity may be less pH-dependent than the free amine form. CS J and CS G were subsequently selected for further studies. At only 0.02% w/v, their enhancing effect was already significant and comparable to that of 5% w/v hydroxypropyl-beta-cyclodextrin (HP-beta-CD). Both chitosans at 0.1% caused minimal release of total protein and phosphorus from the rat nasal mucosa, with the values similar to that of 5% HP-beta-CD. At 0. 5% the two chitosans also stimulated smaller release of lactate dehydrogenase, an intracellular enzyme used as marker of nasal membrane damage, than 1.25% dimethyl-beta-cyclodextrin. Morphological evaluation of the rat nasal mucosa following 2-week daily administration indicated that the two chitosans (1.0%) produced only mild to moderate irritation. In conclusion, both the free amine and the acid salt forms of chitosans are effective in enhancing the nasal absorption of [D-Arg(2)]-Kyotorphin and have potential for further studies as a safe and effective nasal absorption enhancer of peptide drugs.     

酰化改性壳聚糖的合成及其性质考察

目的探讨疏水性壳聚糖衍生物作为口服药用不溶性骨架材料的可行性。方法以N-邻苯二甲酰壳聚糖为中间体,合成C6位被3种不同长度脂肪链完全酰化的壳聚糖衍生物,采用IR、1H-NMR、元素分析等方法对其结构进行表征;采用固定圆锥法测定壳聚糖衍生物流动性、压缩成形性及其在不同溶剂中的溶解性;以茶碱为模型药物,考察壳聚糖衍生物用于控制药物释放的可行性并初步探讨其释药机制。结果成功合成了3种壳聚糖衍生物并对其结构进行了表征;3种衍生物在有机溶剂中的溶解度显著提高,且具有很好的流动性和压缩成形性;单独使用该类衍生物制备的茶碱不溶性骨架片可显著延长释放时间至30 h,其释药机制以扩散为主,符合Huguch i方程。结论酰化改性壳聚糖衍生物加工性能和缓释作用良好,可用于口服不溶性骨架制剂,是一种良好的新型辅料。     

Nasal clearance in health and disease.

This paper reviews the anatomical and physiological factors of importance for nasal drug delivery and discusses in particular the influence of the nasal mucociliary clearance mechanism on the nasal absorption of drugs. The effect of nasal pathological conditions on the mucociliary clearance mechanism and the possible effect of such disease states on nasal drug transport are also discussed. Strategies for the exploitation of bioadhesive drug delivery systems and especially nasal absorption enhancers for the improvement of nasal drug delivery are evaluated to include considerations of the mechanism of action and correlation between the degree of bioadhesion and absorption enhancement and transport of drugs across the nasal membrane. A range of studies involving bioadhesive/absorption enhancer systems are detailed. A selected bioadhesive material, chitosan, which has been shown to have excellent absorption enhancer properties for a variety of drugs is discussed in some detail.     

Chitosans for enhanced delivery of therapeutic peptides across intestinal epithelia: in vitro evaluation in Caco-2 cell monolayers

The aim of the study was to evaluate the transport enhancing effects of two chitosan salts, chitosan hydrochloride and chitosan glutamate (1.5% w/v), and the partially quaternized chitosan derivative, N-trimethyl chitosan chloride (TMC) (1.5 and 2.5% w/v), in vitro in Caco-2 cell monolayers. The transport of the peptide drugs buserelin, 9-desglycinamide, 8-arginine vasopressin (DGAVP) and insulin was followed for 4 h at pH values between 4.40 and 6.20. All the chitosans (1.5%) were able to increase the transport of the peptide drugs significantly in the following order: chitosan hydrochloride>chitosan glutamate>TMC. Due to its quaternary structure, TMC is better soluble than the chitosan salts and further increases in peptide transport were found at higher concentrations (2.5%) of this polymer. The better solubility of TMC may compensate for its lower efficacy at similar concentrations. The increases in peptide drug transport are in agreement with a lowering of the transepithelial electrical resistance (TEER) measured in the cell monolayers. No deleterious effect to the cell monolayers could be detected with the trypan blue exclusion technique. The enzyme inhibitory effect of chitosan hydrochloride (1.5%) was compared with carbomer (1.5%) [Carbopol® 934P] in transport studies with buserelin in the presence of the endoprotease, α-chymotrypsin. In the presence of α-chymotrypsin the transport of buserelin was decreased markedly (from 4.3 to 1.3% of the total dose applied) with chitosan hydrochloride (1.5%), in contrast with carbomer (1.5%) where the transport remained constant (1.4% of the total dose applied). Also the chitosan derivative TMC was not able to inhibit α-chymotrypsin. It is concluded from this study that chitosans are potent absorption enhancers, and that the charge, charge density and the structural futures of chitosan salts and N-trimethyl chitosan chloride are important factors determining their potential use as absorption enhancers for peptide drugs, but that they are unable to prevent degradation from proteolytic enzymes. Structural modification of the chitosan molecule may compensate for this shortcoming.     

Permeation enhancers in the transmucosal delivery of macromolecules

The present article presents a compilation of information regarding various chemical permeation enhancers useful for transmucosal delivery of macromolecules. In the recent past, biotechnology has provided a great number of macromolecules for treatment of various disorders. With the rise in importance of macromolecules, especially proteins and peptides, an enormous volume of research on various novel routes of drug delivery has been carried out. Inspite of its giving the highest and fastest bioavailability, the parenteral route is not a preferred option, due to its inconvenience and the noncompliance of patients. Mucosal surfaces are the most common and convenient routes for delivering drugs to the body. However, macromolecular drugs such as peptides and proteins are unable to overcome the mucosal barriers and/or are degraded before reaching the blood stream. Transmucosal drug delivery with various bioavailability enhancers is receiving increasing attention as a possible alternative to parenteral delivery of macromolecules. Among the various bioavailability enhancers, chemical permeation enhancers have been most studied. Permeation enhancers reversibly modulate the permeability of the barrier layer in favor of drug absorption. Newer permeation enhancers like zonula occludin toxin, poly-L-arginine, chitosan derivatives etc have shown a significant increase in drug absorption through transmucosal routes without serious damage to the barrier layer. In particular delivery of macromolecules via the nasal and pulmonary routesusing newer permeation enhancers has emerged as a possible alternative to the parenteral delivery ofmacromolecules.