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Nucleic Acid Purification : Its Principle and Miniaturization

Nucleic Acid Purification : Its Principle and Miniaturization. MEC seminar 2004. Apr. 13 Ji Youn Lee. Heating region. Lysis of tissue (or cells) and nucleic acid purification. Inlet I. Inlet II. mRNA separation module (immobilized oligo-dT). Hybridization module.

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Nucleic Acid Purification : Its Principle and Miniaturization

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  1. Nucleic Acid Purification: Its Principle and Miniaturization MEC seminar 2004. Apr. 13 Ji Youn Lee

  2. Heating region Lysis of tissue (or cells) and nucleic acid purification Inlet I Inlet II mRNA separation module (immobilized oligo-dT) Hybridization module Target mRNA capture module Fluorescence detection module Waste Outlet

  3. Topics • Brief introduction of nucleic acid purification principle • Summary of papers about nucleic acid purification on chip

  4. Purification from What? • Proteins • Enzymes, DNA- or RNA-binding proteins, transcription factors… etc. • Salts • Buffer change • Other contaminants • Short DNA fragments, dNTPs… etc. • Commercially available products • PCR cleanup kit, gel elution kit, plasmid, genomic DNA, total RNA, mRNA purification kits

  5. Principle Disruption of the water structure around negatively charged silica, allowing a cation bridge to form. (guanidinium isothiocyanate, sodium iodide, and etc.) Selective binding to filter (in the presence of the chaotropic salt) Washing with ethanol Elution with low-ionic strength buffer When the salt is removed, rehydration of the silica matrix breaks the attraction between the matrix and DNA.

  6. General Procedure Binding buffer + sample (Chaotropic salts) Washing buffer (Ethanol) Elution buffer (Low salts) Filter Centrifugation Centrifugation Centrifugation Purified nucleic acid solution

  7. How Miniaturize? • Material packing (silica beads) • Incorporation of silica-based resins into micro-flow device • Electrophoresis 23, 727–733 (2002) • Analytical Biochemistry 283, 175–191 (2000) • Pillar structure • Using microfabricated silica pillar structures

  8. Nucleic Acid Purification Using Microfabricated Silicon Structures Nathaniel C. Cady, Scott Stelick, Carl A. Batt Biosensors and Bioelectronics 19 (2003) 59-66 (Cornell Univ.)

  9. Summary • Objective • A microfluidic device to purify bacteriophage lambda DNA and bacterial chromosomal DNA • Materials • A microfabricated channel in which silica-coated pillars were etched • Methods • DNA was selectively bound to these pillars in the presence of the chaotropic salt guanidinium isothiocyanate, • followed by washing with ethanol and elution with low-ionic strength buffer.

  10. Summary (continued) • Results • Surface area • Initial: 0.7 cm2 • With pillars: 2.1~4.2 cm2 • Surface to volume ratio • 4200 cm2/ml • Efficiency • ~16% • Capacity • 200 ng/2.45 cm2 = 82 ng/cm2

  11. 10 m 10 m 50 m Fig. 1 Schematic representation of channels containing microfabricated silica pillars. The spacing between pillars and the pillar width was kept constant at 10 m, while the depth of the channels and height of the pillars could be adjusted between 20 and 50 m.

  12. Fig. 2

  13. Fig. 3 • DNA elution profile for total DNA from 107 E. coli cells. • Initial 200 ㎕ wash with TE buffer (fractions 1~4) • 107 E. coli cells in 100 ㎕ of L6 buffer were loaded (fractions 5~6) • Ethanol wash (fractions 7~10) • Eluted with TE (fractions 11~16) • The error bars represent the standard deviation between three separate experiments.

  14. Fig. 4 Protein (87% removal) DNA DNA and protein concentration profile for DNA purification from 107 E. coli cells.

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