D. Quong scite author profile

Calf thymus DNA was microencapsulated within crosslinked chitosan membranes, or immobilized within chitosan-coated alginate microspheres. Microcapsules were prepared by interfacial polymerization of chitosan, and alginate microspheres formed by emulsification/internal gelation. Diameters ranged from 20 to 500 microns, depending on the formulation conditions. Encapsulated DNA was quantified in situ by direct spectrophotometry (260 nm) and ethidium bromide fluorimetry, and compared to DNA measurements on the fractions following disruption and dissolution of the microspheres. Approximately 84% of the DNA was released upon core dissolution and membrane disruption, with 12% membrane bound. The yield of encapsulation was 96%. Leakage of DNA from intact microspheres/capsules was not observed. DNA microcapsules and microspheres were recovered intact from rat feces following gavage and gastrointestinal transit. Higher recoveries (60%) and reduced shrinkage during transit were obtained with the alginate microspheres. DNA was recovered and purified from the microcapsules and microspheres by chromatography and differential precipitation with ethanol. This is the first report of microcapsules or microspheres containing biologically active material (DNA) being passed through the gastrointestinal tract, with the potential for substantial recovery.

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DNA protection from extracapsular nucleases, within chitosan- or poly-L-lysine-coated alginate beads

Quong

Neufeld

1998

Biotechnol. Bioeng.

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External versus internal source of calcium during the gelation of alginate beads for DNA encapsulation

Quong

Neufeld

Skjåk‐Bræk³

et al. 1998

Biotechnol. Bioeng.

112

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Alginate gels produced by an external or internal gelation technique were studied so as to determine the optimal bead matrix within which DNA can be immobilized for in vivo application. Alginates were characterized for guluronic/mannuronic acid (G/M) content and average molecular weight using 1H‐NMR and LALLS analysis, respectively. Nonhomogeneous calcium, alginate, and DNA distributions were found within gels made by the external gelation method because of the external calcium source used. In contrast, the internal gelation method produces more uniform gels. Sodium was determined to exchange for calcium ions at a ratio of 2:1 and the levels of calcium complexation with alginate appears related to bead strength and integrity. The encapsulation yield of double‐stranded DNA was over 97% and 80%, respectively, for beads formed using external and internal calcium gelation methods, regardless of the composition of alginate. Homogeneous gels formed by internal gelation absorbed half as much DNAse as compared with heterogeneous gels formed by external gelation. Testing of bead weight changes during formation, storage, and simulated gastrointestinal (GI) conditions (pH 1.2 and 7.0) showed that high alginate concentration, high G content, and homogeneous gels (internal gelation) result in the lowest bead shrinkage and alginate leakage. These characteristics appear best suited for stabilizing DNA during GI transit. ©1998 John Wiley & Sons, Inc. Biotechnol Bioeng 57: 438‐446, 1998.

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Stability of chitosan and poly-L-lysine membranes coating DNA-alginate beads when exposed to hydrolytic enzymes

Quong

1999

Journal of Microencapsulation

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Soluble chitosan and poly-L-lysine are readily hydrolysed using lysozyme or chitosanase for chitosan, and trypsin, chymotrypsin or proteinase K for poly-L-lysine. For similar amounts of enzyme, chitosanase hydrolysed 57% of the chitosan, compared to 35% for lysozyme. In the case of poly-L-lysine, chymotrypsin and trypsin exhibited similar activities, hydrolysing approximately 41% of the polymer compared to proteinase K at only 16%. In contrast, chitosan and poly-L-lysine membranes, coating alginate beads, were almost totally inert to the respective hydrolytic enzymes. Less than 2% of the membrane weight was hydrolysed. It appears that either membrane material would be stable for in vivo application, and in particular in the protection of DNA during gastrointestinal transit. At chitosanase concentrations of 1.4 mg/ml and in the presence of sodium ions, 20% of the total double-stranded DNA was released from chitosan coated beads. An exchange of calcium for sodium within the bead liquefied the alginate core releasing DNA. The presence of calcium stabilized the alginate bead, retaining all the DNA. Highly pure DNA was recovered from beads through mechanical membrane disruption, core liquefaction in citrate and use of DNA spin-columns to separate DNA/alginate mixtures in a citrate buffer. DNA recovery efficiencies as high as 94% were achieved when the initial alginate/DNA weight ratio was 1000.

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External versus internal source of calcium during the gelation of alginate beads for DNA encapsulation

Quong

Neufeld

Skjåk‐Bræk³

et al. 1998

Biotechnol. Bioeng.

View full text Add to dashboard Cite

Alginate gels produced by an external or internal gelation technique were studied so as to determine the optimal bead matrix within which DNA can be immobilized for in vivo application. Alginates were characterized for guluronic/mannuronic acid (G/M) content and average molecular weight using 1H-NMR and LALLS analysis, respectively. Nonhomogeneous calcium, alginate, and DNA distributions were found within gels made by the external gelation method because of the external calcium source used. In contrast, the internal gelation method produces more uniform gels. Sodium was determined to exchange for calcium ions at a ratio of 2:1 and the levels of calcium complexation with alginate appears related to bead strength and integrity. The encapsulation yield of double-stranded DNA was over 97% and 80%, respectively, for beads formed using external and internal calcium gelation methods, regardless of the composition of alginate. Homogeneous gels formed by internal gelation absorbed half as much DNAse as compared with heterogeneous gels formed by external gelation. Testing of bead weight changes during formation, storage, and simulated gastrointestinal (GI) conditions (pH 1.2 and 7.0) showed that high alginate concentration, high G content, and homogeneous gels (internal gelation) result in the lowest bead shrinkage and alginate leakage. These characteristics appear best suited for stabilizing DNA during GI transit.

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D. Quong

Microencapsulation of DNA Within alginate microspheres and crosslinked chitosan membranes for in vivo application

DNA protection from extracapsular nucleases, within chitosan- or poly-L-lysine-coated alginate beads

External versus internal source of calcium during the gelation of alginate beads for DNA encapsulation

Stability of chitosan and poly-L-lysine membranes coating DNA-alginate beads when exposed to hydrolytic enzymes

External versus internal source of calcium during the gelation of alginate beads for DNA encapsulation

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