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200 10$aBioencapsulation in silica-based nanoporous sol-gel glasses$b[electronic resource] /$fBouzid Menaa, Farid Menaa and Olga Sharts
210   $aNew York $cNova Science Publishers$dc2010
215   $a1 online resource (84 p.)
225 1 $aNanotechnology science and technology
300   $aDescription based upon print version of record.
311   $a1-60876-989-5 
320   $aIncludes bibliographical references (p. [51]-66) and index.
327   $a""BIOENCAPSULATION IN SILICA-BASED NANOPOROUS SOL-GEL GLASSES ""; ""BIOENCAPSULATION IN SILICA-BASED NANOPOROUS SOL-GEL GLASSES ""; ""CONTENTS""; ""PREFACE""; ""ABSTRACT ""; ""1. INTRODUCTION""; ""2.  BIOENCAPSULATION VIA SOL-GEL PROCESS IN SILICA-BASED MATERIALS: METHOD, MATERIALS,  BIOAPPLICATIONS, AND CHARACTERIZATION TECHNIQUES ""; ""2.1. Protein Bioencapsulation via Sol-Gel Process""; ""2.2. Materials and Bioapplications""; ""2.3. Probing the Silica-Protein Interactions and Protein-Folding""; ""2.3.1. Characterization of the Silica Host Matrix""
327   $a""2.3.2. Characterizing the Protein Folding in Nanoporous Sol-Gel Glasses """"3. PARAMETERS INFLUENCING THE PROTEIN CONFORMATION IN NANOPOROUS SILICA-BASED SOL-GEL GLASSES ""; ""3.1. INTRODUCTION TO THERMODYNAMICSa??? DRIVING FORCES AND INTERACTIONS INFLUENCING THE PROTEIN FOLDING IN SILICA-BASED NANOPOROUS MATERIALS""; ""3.2. The Surface Hydration and Hydrophobicity Influence the Protein Folding in Nanoporous Sol-Gel Glasses ""; ""3.2.1. Hydrophobic Effects on Protein Conformation Induced by Silica Glass Surface Modification with Hydrophobic Organosilanes Precursors ""
327   $a""3.2.2. Hydrophobic Effects Induced by the Decrease of siloxane a???[O-Si-O]- Network Dimension by Glass Surface Modification with Multiple Hydrophobic Alkyl Groups Attached at the Silicon of Organosilane Precursors""""3.2.3. Solute Effects and Hofmeister Ions Effects""; ""3.3. STERIC EFFECTS INDUCED BY THE CHOICE OF CROWDED SILANE MODIFIERS IN TMOS- DERIVED  SOL-GEL GLASSES THE HOST MATRIX ""; ""3.4. INFLUENCE OF THE PORE SIZE, PORE SHAPE  AND SURFACE AREA OF THE SILICA-BASED HOST  MATRIX ON PROTEIN FOLDING ""; ""3.5. THERMAL STABILITY OF PROTEINS CONFINED  IN THE POROUS HOST MATRIX ""
327   $a""4. ENHANCING THE PROTEIN FOLDING  BY INTRODUCING AND ASSOCIATING HYDROPHOBIC AND STERIC EFFECTS  IN MODIFIED SILICA-BASED  POROUS GLASSES """"4.1. INCORPORATING FLUORO-BASED ORGANOSILANES  IN TO FORM SUPERHYDROPHOBIC CROWDED ORGANICALLY MODIFIED SILICA BASED HOST MATRICES""; ""4.2. INCORPORATING PHOSPHONATE GROUPS  IN HYDROPHOBIC SILICA NETWORK ""; ""5. EMERGING TECHNIQUES FOR A BETTER UNDERSTANDING OF PROTEIN INTERACTIONS AND CONFORMATIONS IN NANOPOROUS  SOL-GEL GLASSES ""; ""5.1. IN-SITU MAS NMR""; ""5.2. FLUORO-RAMAN SPECTROSCOPY""; ""CONCLUSION ""; ""REFERENCES""; ""INDEX ""
410  0$aNanotechnology science and technology series.
606   $aBiocolloids
606   $aProtein folding
606   $aSilica gel
608   $aElectronic books.
615  0$aBiocolloids.
615  0$aProtein folding.
615  0$aSilica gel.
676   $a612/.01575
700   $aMenaa$b Bouzid$0905184
701   $aMenaa$b Farid$0905185
701   $aSharts$b Olga$0905186
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906   $aBOOK
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996   $aBioencapsulation in silica-based nanoporous sol-gel glasses$92024469
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