Influence of Chitosan Structure on the Formation and Stability of DNA−Chitosan Polyelectrolyte Complexes

Strand, Sabina P.; Danielsen, Signe; Christensen, Bjørn E.; Vårum, Kjell M.

doi:10.1021/bm0503726

Cited by 164 publications

(142 citation statements)

References 51 publications

(158 reference statements)

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“…As expected, in general, when pH and ionic strength were kept low (pH 4.0, ionic strength 10 mM) nanoparticle sizes remained smaller than 250 nm as seen from Table 2, independent of the chitosan molecular weight and N/P ratio. However, the lower molecular weight sample (5 kDa) formed the smaller nanoparticles with diameters ranging from 120 to 140 nm and the higher molecular chitosan (CH 150 kDa) exhibited nanoparticle sizes ranging from 200 to 240 nm, which is in agreement with results previously published on calf thymus DNA using the same range of chitosan molecular weight [18].…”

Section: Results and Discussion 31 Dynamic Light Scatteringsupporting

confidence: 91%

Effect of ionic strength solution on the stability of chitosan–DNA nanoparticles

Picola

Busson

Casé

et al. 2013

Journal of Experimental Nanoscience

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Chitosan-DNA nanoparticles employed in gene therapy protocols consist of a neutralised, stoichiometric core and a shell of the excess of chitosan which stabilises the particles against further coagulation. At low ionic strength, these nanoparticles possess a high stability; however, as the ionic strength increases, it weakens the electrostatic repulsion which can play a decisive part in the formation of highly aggregated particles. In this study, new results about the effect of ionic strength on the colloidal stability of chitosan-DNA nanoparticles were obtained by studying the interaction between chitosans of increasing molecular weights (5, 10, 16, 29, 57 and 150 kDa) and calf thymus DNA. The physicochemical properties of polyplexes were investigated by means of dynamic light scattering, static fluorescence spectroscopy, optic microscopy, transmission electronic microscopy and gel electrophoresis. After subsequent addition of salt to the nanoparticles solution, secondary aggregation increased the size of the polyplexes. The nanoparticles stability decreased drastically at the ionic strengths 150 and 500 mM, which caused the corresponding decrease in the thickness of the stabilising shell. The morphologies of chitosan/DNA nanoparticles at those ionic strengths were a mixture of large spherical aggregates, toroids and rods. The results indicated that to obtain stable chitosan-DNA nanoparticles, besides molecular weight and N/P ratio, it is quite important to control the ionic strength of the solution.

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Section: Results and Discussion 31 Dynamic Light Scatteringsupporting

confidence: 91%

Effect of ionic strength solution on the stability of chitosan–DNA nanoparticles

Picola

Busson

Casé

et al. 2013

Journal of Experimental Nanoscience

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“…OCS had greater complexation efficiency for pDNA than PCS (>90% compared to an average of 80% for PCS-pDNA), however, pDNA appears to be released from OCS faster than from PCS as evidenced by gel electrophoresis studies where there is evidence of faint bands seen at all N/P ratios, but more so at lower N/P ratios, suggesting that the pDNA is beginning to be released from the OCS. This result is in agreement with other reports which state that low MW chitosan forms less stable nanoparticles with pDNA than with high MW [23,25,49,50]. While stability is important extracellularly, release of the pDNA is critical in ensuring transfection so OCS-pDNA nanoparticles formulated at all the N/P ratios investigated were deemed suitable for transfection experiments.…”

Section: Discussionsupporting

confidence: 92%

Development of a gene-activated scaffold platform for tissue engineering applications using chitosan-pDNA nanoparticles on collagen-based scaffolds

Raftery

Tierney

Curtin

et al. 2015

Journal of Controlled Release

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“…Driven by electrostatic interactions, chitosanpDNA complexes have been used for transfection of mammalian cells both in vitro and in vivo (Koping-Hoggard et al, 2001;Romøren et al, 2003;Vauthier et al, 2014). Nevertheless, results of transfection efficiency using chitosan-based systems are strongly dependent on chitosan properties (e.g., molecular weight and the relative amount of N-acetylglucosamine units, namely degree of acetylation (DA)) (Lavertu et al, 2006;Santos-Carballal et al, 2015;Strand et al, 2005). Chitosan has been reported as a suitable candidate for transmucosal administration of drugs (Grenha et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Chitosan as a non-viral co-transfection system in a cystic fibrosis cell line

Fernández

Santos-Carballal

Weber

et al. 2016

International Journal of Pharmaceutics

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Successful gene therapy requires the development of suitable vehicles for the selective and efficient delivery of genes to specific target cells at the expense of minimal toxicity. In this work, we investigated a non-viral gene delivery system based on chitosan (CS) to specifically address cystic fibrosis (CF). Thus, electrostatic self-assembled CS-pEGFP and CS-pEGFPsiRNA complexes were prepared from high-pure fully characterized CS (Mw ~20 kDa and degree of acetylation ~30%). The average diameter of positively-charged complexes (i.e.  ~ +25 mV) was ~200 nm. The complexes were found relatively stable over 14 h in OptiMEM. Cell viability study did not show any significant cytotoxic effect of the CS-based complexes in a human bronchial cystic fibrosis cell line (s). We evaluated the transfection efficiency of this cell line with both CS-pEGFP and co-transfected with CS-pEGFP-siRNA complexes at (N/P) charge ratio of 12. We reported an increase in the fluorescence intensity of CS-pEGFP and a reduction in the cells co-transfected with CS-pEGFP-siRNA. This study shows proof-of-principle that co-transfection with chitosan might be an effective delivery system in a human CF cell line. It also offers a potential alternative to further develop therapeutic strategies for inherited disease treatments, such as CF.

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Influence of Chitosan Structure on the Formation and Stability of DNA−Chitosan Polyelectrolyte Complexes

Cited by 164 publications

References 51 publications

Effect of ionic strength solution on the stability of chitosan–DNA nanoparticles

Effect of ionic strength solution on the stability of chitosan–DNA nanoparticles

Development of a gene-activated scaffold platform for tissue engineering applications using chitosan-pDNA nanoparticles on collagen-based scaffolds

Chitosan as a non-viral co-transfection system in a cystic fibrosis cell line

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