Effect of cationic polymer adsorbent pK a on the selective removal of endotoxin from an albumin solution

Sakata, Masayo; Todokoro, Masami; Kai, Takami; Kunitake, Masashi; Hirayama, Chuichi

doi:10.1007/bf02493008

Cited by 12 publications

(10 citation statements)

References 15 publications

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“…[25][26][27][28][29][30] Unlike anionic polymers, which exhibit pH-induced transitions in their physical conformation around pH 4-6, these cationic polymers display the change in their conformation at pH 8 or higher based on their pKa values ( Figure 5) [31][32][33] Several investigations focused on modifying these cationic polymers to reduce their pKa values to match the physiologic pH to become useful in biological and pharmaceutical applications. [34] One approach is to incorporate hydrophobic monomers into the cationic polymer backbone to shift the polymer's overall pKa towards the neutral pH range.…”

Section: Ph-sensitive Polymers Wth Basic Functional Groupsmentioning

confidence: 99%

Stimuli-Sensitive Particles for Drug Delivery

Grainger

El-Sayed

2010

Biologically-Responsive Hybrid Biomaterials

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Section: Ph-sensitive Polymers Wth Basic Functional Groupsmentioning

confidence: 99%

Stimuli-Sensitive Particles for Drug Delivery

Grainger

El-Sayed

2010

Biologically-Responsive Hybrid Biomaterials

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“…Cationic adsorption is remarkably dependent on the pK a of the adsorbent, pK a of the bioproducts and ionic strength of the buffer. [15] Hydrophobic adsorption is independent of the ionic strength. [5,6] Nucleic acids (DNA and RNA) are polynucleosides with anionic regions (phosphate groups), pentoses, and purine and pyrimidine bases, and, thus, the DNA charge is anionic when the pH exceeds the pK a (,2).…”

Section: Effects Of Pore Size and Pk A On Dna Adsorbing Capacitymentioning

confidence: 99%

Selective Removal of DNA from Bioproducts by Polycation‐Immobilized Cellulose Beads

Sakata

Nakayama

Yanagi

et al. 2006

Journal of Liquid Chromatography & Related Technologies

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This paper describes a method for the selective removal of DNA from various cellular products using columns packed with polycation-immobilized cellulose beads. Polyethyleneimine (PEI), poly-N,N-dimethylaminopropylacrylamide (poly(DAPA)) and poly(1-lysine) (P1L), all of which have cationic properties, were used as the ligands on the beads. Cellufine-GC15 w and -CPC w were used as cellulose matrices. Adsorption of DNA by the beads was determined using a batchwise method or a column method. Each bead type showed high DNA adsorbing activity at pH 7.0 and ionic strengths of m ¼ 0.05 -0.8. The larger the pore size of the beads, the larger the DNA-adsorbing activity. The DNA adsorbing capacities per wet mL of PEI-, poly(DAPA)-and P1L immobilized Cellufine-CPC with large pore sizes, were 3.7, 3.2, and 1.8 mg, respectively. When a protein, such as bovine serum albumin (BSA) or g-globulin, was present in solution with the DNA under physiological conditions (pH 7.0, m ¼ 0.2), the DNA selectivity of the PEI immobilized Cellufine-CPC columns was unsatisfactory, because both the DNA and the protein were adsorbed into the column. In contrast, the poly(DAPA) immobilized Cellufine-CPC column selectively removed DNA from each protein solution contaminated with DNA under similar conditions: the DNA concentration in each treated protein solution was below 10 ng mL 21 , and high recovery of each protein (.92%) was obtained.

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“…Therefore, we considered that aminated PMLG beads may be used as selective adsorbents for DNA. The adsorption of several cellular products, such as DNA, BSA and -globulin, increased with increasing the bead's M lim [34][35][36]. A swelling size of cellular product (protein and DNA) in a solution is estimated as not its nanometer size but its molecular size.…”

Section: Aminated Poly( -Methyl L-glutamate) Beadsmentioning

confidence: 99%

Chromatographic Removal of DNA from Protein Solutions by Cationic Polymer Beads

Sakata

Kunitake²

2007

CPA

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Drugs produced using recombinant gene technology often contain nucleic acids (DNA) as impurities. Such contaminants must be removed from solutions used for injection, because the influence of such DNA on the living body has not been fully clarified. Various techniques for DNA removal described in the patent literature are not broadly applicable, as they are tailored to meet specific product requirements. To remove DNA from a solution of high-molecular weight compounds, such as proteins, the adsorption method has proven to be most effective. This review intends to discuss various methods of chromatographic removal and separation of DNA from protein solutions using cationic polymer adsorbents. We will first discuss chromatographic properties of various DNA-specific polymer adsorbents, and then describe effects of adsorbent's pore size, its amino-group content, its surface pKa value, and buffer's condition on removal of DNA from a protein solution. Finally, we will discuss how to optimize a method of removal DNA without affecting the recovery of important compounds, such as proteins.

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Effect of cationic polymer adsorbent pK a on the selective removal of endotoxin from an albumin solution

Cited by 12 publications

References 15 publications

Stimuli-Sensitive Particles for Drug Delivery

Stimuli-Sensitive Particles for Drug Delivery

Selective Removal of DNA from Bioproducts by Polycation‐Immobilized Cellulose Beads

Chromatographic Removal of DNA from Protein Solutions by Cationic Polymer Beads

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