Marc Lavertu scite author profile

Chitosan is a linear cationic biopolymer composed of glucosamine and N-acetyl-glucosamine that is only soluble in acidic aqueous solutions and precipitates when neutralized. However, it was recently discovered that chitosan dissolved in solutions containing glycerol phosphate was soluble at near neutral pH and produced a sol-gel transition when heated. Understanding this unique thermogelling system requires improved characterization of the ionization and solubility behaviors of chitosan, in particular dependencies on temperature, salt, chitosan concentration, and fD, where fD is the fraction of glucosamine monomers (deacetylated monomers) in chitosan. In the current study we performed temperature-controlled titration and dilution experiments on chitosan solutions with fD of 0.72, 0.85, and 0.98 at concentrations ranging from 1.875 to 30 mM of its glucosamine monomer and with 0 to 150 mM added salt. Light transmittance measurements were performed during titration to indicate precipitation. We found the apparent proton dissociation constant of chitosan, pKap, to (1) decrease strongly with increased temperature, (2) increase strongly with increased salt, (3) increase strongly with increased chitosan concentration in low-salt conditions, and (4) decrease weakly with increasing fD. All of the above influences on chitosan pKap were accurately predicted using a mean-field Poisson-Boltzmann (PB) cylindrical cell model where the only adjustable parameter was the temperature-dependent chitosan intrinsic monomeric dissociation constant pK0(T). The resulting chitosan pK0 values at 25 degrees C were in the range from 6.63 to 6.78 for all chitosans and salt contents tested. The temperature dependence of chitosan ionization was found to strongly reduce pK0(T) by 0.023 units per degrees C, for example, resulting in a reduction of chitosan pK0(T) from 7.1 at 5 degrees C to 6.35 at 37 degrees C for fD of 0.72 in 150 mM salt. A similar temperature-dependent reduction of the pKa of the glucosamine monomer was found (-0.027 units per degrees C) while the pKa of glycerol phosphate did not change significantly with temperature. The latter result suggested that chitosan solutions heated in the presence of glycerol phosphate will become partly neutralized by transferring protons to glycerol phosphate and thereby allow attractive interchain forces to form a physically cross-linked gel under the appropriate conditions. Additionally, the degree of ionization of chitosan when it precipitates upon addition of a strong base was measured to be in the range from 0.25 to 0.55 and was found to (1) be insensitive to temperature, (2) increase strongly with increased salt, and (3) increase strongly with fD. The salt effect was accounted for by the PB model, while the influence of fD appeared to be due to acetyl groups impeding attractive chain-to-chain association to increase solubility and require reduced ionization levels to precipitate.

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Chitosans for delivery of nucleic acids

Buschmann

Merzouki

Lavertu

et al. 2013

Advanced Drug Delivery Reviews

198

134

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Alternatives to efficient viral vectors in gene therapy are desired because of their poor safety profiles. Chitosan is a promising non-viral nucleotide delivery vector because of its biocompatibility, biodegradability, low immunogenicity and ease of manufacturing. Since the transfection efficiency of chitosan polyplexes is relatively low compared to viral counterparts, there is an impetus to gain a better understanding of the structure-performance relationship. Recent progress in preparation and characterisation has enabled coupling analysis of chitosans structural parameters that has led to increased TE by tailoring of chitosan's structure. In this review, we summarize the recent advances that have lead to a more rational design of chitosan polyplexes. We present an integrated review of all major areas of chitosan-based transfection, including preparation, chitosan and polyplexes physicochemical characterisation, in vitro and in vivo assessment. In each, we present the obstacles to efficient transfection and the strategies adopted over time to surmount these impediments.

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New Insights into Chitosan−DNA Interactions Using Isothermal Titration Microcalorimetry

et al. 2009

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The interaction of chitosan with plasmid DNA was investigated as a function of pH, buffer composition, degree of deacetylation (DDA), and molecular weight (M(n)) of chitosan, using isothermal titration microcalorimetry (ITC). The Single Set of Identical Sites model was used to obtain the enthalpy of interaction, the binding constant, and the stoichiometry of binding. The chitosan-DNA interaction was shown to be coupled with proton transfer from the buffer to chitosan, as revealed by the dependence of the measured heat release on the ionization enthalpy of the buffer. The measured enthalpy of binding was almost entirely due to proton transfer, because it was accounted for by the enthalpy of ionization of the buffer and of chitosan once the number of protons transferred was calculated. This proton transfer during binding resulted in the protonation of an additional 17, 37, and 58% of total glucosamine units at pH 5.5, 6.5, and 7.4, respectively. The strong polyanionic nature of DNA facilitates the ionization of glucosamines of chitosan upon complexation and is responsible for proton transfer. Interestingly, using the chitosan-DNA stoichiometry provided by ITC and the calculated degree of ionization of chitosan in the complex, the charge ratio of protonated amines to negative phosphate groups in the complex was nearly constant at 0.50-0.75 after saturation and was independent of the pH, buffer type and chitosan molecular characteristics. The chitosan-DNA binding constant was in the range of 10(9)-10(10) M(-1). The binding constant was pH-dependent and was greater at lower pH due to increased electrostatic attraction to DNA when chitosan is highly charged. Furthermore, the DDA and molecular weight of chitosan exerted a great influence on binding affinity which increased by almost an order of magnitude with an increase of the latter from 7 to 153 kDa. The binding affinity did not change significantly with DDA from 72 to 80% when the M(n) was kept constant near 80 kDa, but it increased substantially with DDA from 80 to 93% to reach a value similar to that obtained with chitosan of M(n) = 153 kDa and 80% DDA. These results provide insight into the previously reported dependence of the transfection efficiency of DNA/chitosan complexes on chitosan DDA and molecular weight, where complex stability and chitosan-DNA binding strength play a critical role.

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Marc Lavertu

High efficiency gene transfer using chitosan/DNA nanoparticles with specific combinations of molecular weight and degree of deacetylation

A validated 1H NMR method for the determination of the degree of deacetylation of chitosan

Ionization and Solubility of Chitosan Solutions Related to Thermosensitive Chitosan/Glycerol-Phosphate Systems

Chitosans for delivery of nucleic acids

New Insights into Chitosan−DNA Interactions Using Isothermal Titration Microcalorimetry

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