PMID-sentid Pub_year Sent_text comp_official_name comp_offsetprotein_name organism prot_offset 27524053-0 2016 Biomimetic mineralization of nano-sized, needle-like hydroxyapatite with ultrahigh capacity for lysozyme adsorption. Durapatite 53-67 lysozyme Homo sapiens 96-104 26838882-0 2016 Lysozyme loading and release from Se doped hydroxyapatite nanoparticles. Durapatite 43-57 lysozyme Homo sapiens 0-8 10092395-0 1999 Adsorption of Bovine Serum Albumin and Lysozyme on Hydrophobic Calcium Hydroxyapatites. Durapatite 63-86 lysozyme Homo sapiens 39-47 25214782-0 2014 Effect of hydroxyapatite-containing microspheres embedded into three-dimensional magnesium phosphate scaffolds on the controlled release of lysozyme and in vitro biodegradation. Durapatite 10-24 lysozyme Homo sapiens 140-148 23859812-10 2013 LSZ strongly interacts with the hydroxyapatite particles and thus only forms thin films with very low elastic moduli. Durapatite 32-46 lysozyme Homo sapiens 0-3 32261362-0 2014 Hydroxyapatite-containing gelatin/chitosan microspheres for controlled release of lysozyme and enhanced cytocompatibility. Durapatite 0-14 lysozyme Homo sapiens 82-90 23859812-4 2013 In this work, we study the rheological properties of a hydroxyapatite suspension system with additions of the proteins bovine serum albumin (BSA), lysozyme (LSZ) and fibrinogen (FIB). Durapatite 55-69 lysozyme Homo sapiens 157-160 23629536-0 2013 The adsorptive behavior of albumin and lysozyme proteins on rod-shaped and plate-shaped hydroxyapatite. Durapatite 88-102 lysozyme Homo sapiens 39-47 23629536-1 2013 The adsorption behavior of albumin (BSA) and lysozyme (LSZ) on rod-shaped and plate-shaped hydroxyapatite (HA) was investigated to evaluate the influence of crystal orientation and morphology on the selective protein adsorption of HA. Durapatite 91-105 lysozyme Homo sapiens 45-53 23629536-1 2013 The adsorption behavior of albumin (BSA) and lysozyme (LSZ) on rod-shaped and plate-shaped hydroxyapatite (HA) was investigated to evaluate the influence of crystal orientation and morphology on the selective protein adsorption of HA. Durapatite 91-105 lysozyme Homo sapiens 55-58 23629536-8 2013 The amount of adsorbed BSA increased in the following order: HA-pH 4.0, HA-pH 2.0, HA-40 C and HA-80 C. The amount of adsorbed LSZ on HA increased in the following order--HA-pH 2.0, HA-pH 4.0, HA-40 C and HA-80 C--with a corresponding decrease in the a/c intensity ratio. Durapatite 61-63 lysozyme Homo sapiens 127-130 23629536-8 2013 The amount of adsorbed BSA increased in the following order: HA-pH 4.0, HA-pH 2.0, HA-40 C and HA-80 C. The amount of adsorbed LSZ on HA increased in the following order--HA-pH 2.0, HA-pH 4.0, HA-40 C and HA-80 C--with a corresponding decrease in the a/c intensity ratio. Durapatite 72-74 lysozyme Homo sapiens 127-130 23629536-8 2013 The amount of adsorbed BSA increased in the following order: HA-pH 4.0, HA-pH 2.0, HA-40 C and HA-80 C. The amount of adsorbed LSZ on HA increased in the following order--HA-pH 2.0, HA-pH 4.0, HA-40 C and HA-80 C--with a corresponding decrease in the a/c intensity ratio. Durapatite 72-74 lysozyme Homo sapiens 127-130 23629536-8 2013 The amount of adsorbed BSA increased in the following order: HA-pH 4.0, HA-pH 2.0, HA-40 C and HA-80 C. The amount of adsorbed LSZ on HA increased in the following order--HA-pH 2.0, HA-pH 4.0, HA-40 C and HA-80 C--with a corresponding decrease in the a/c intensity ratio. Durapatite 72-74 lysozyme Homo sapiens 127-130 23629536-8 2013 The amount of adsorbed BSA increased in the following order: HA-pH 4.0, HA-pH 2.0, HA-40 C and HA-80 C. The amount of adsorbed LSZ on HA increased in the following order--HA-pH 2.0, HA-pH 4.0, HA-40 C and HA-80 C--with a corresponding decrease in the a/c intensity ratio. Durapatite 72-74 lysozyme Homo sapiens 127-130 23629536-8 2013 The amount of adsorbed BSA increased in the following order: HA-pH 4.0, HA-pH 2.0, HA-40 C and HA-80 C. The amount of adsorbed LSZ on HA increased in the following order--HA-pH 2.0, HA-pH 4.0, HA-40 C and HA-80 C--with a corresponding decrease in the a/c intensity ratio. Durapatite 72-74 lysozyme Homo sapiens 127-130 23629536-8 2013 The amount of adsorbed BSA increased in the following order: HA-pH 4.0, HA-pH 2.0, HA-40 C and HA-80 C. The amount of adsorbed LSZ on HA increased in the following order--HA-pH 2.0, HA-pH 4.0, HA-40 C and HA-80 C--with a corresponding decrease in the a/c intensity ratio. Durapatite 72-74 lysozyme Homo sapiens 127-130 23629536-8 2013 The amount of adsorbed BSA increased in the following order: HA-pH 4.0, HA-pH 2.0, HA-40 C and HA-80 C. The amount of adsorbed LSZ on HA increased in the following order--HA-pH 2.0, HA-pH 4.0, HA-40 C and HA-80 C--with a corresponding decrease in the a/c intensity ratio. Durapatite 72-74 lysozyme Homo sapiens 127-130 10092395-1 1999 The adsorption of bovine serum albumin (BSA) and lysozyme (LSZ) to oleyl phosphate(OP)-grafted calcium hydroxyapatite (OP-CaHAP) with different degrees of hydrophobicity, ranging the number of surface oleyl group per unit nm2 (nO) from 0 to 2.60, was investigated. Durapatite 95-117 lysozyme Homo sapiens 49-57 10092395-1 1999 The adsorption of bovine serum albumin (BSA) and lysozyme (LSZ) to oleyl phosphate(OP)-grafted calcium hydroxyapatite (OP-CaHAP) with different degrees of hydrophobicity, ranging the number of surface oleyl group per unit nm2 (nO) from 0 to 2.60, was investigated. Durapatite 95-117 lysozyme Homo sapiens 59-62 7850845-0 1994 Lysozyme and lactoperoxidase inhibit the adherence of Streptococcus mutans NCTC 10449 (serotype c) to saliva-treated hydroxyapatite in vitro. Durapatite 117-131 lysozyme Homo sapiens 0-8 9490000-0 1998 Adsorption of human lysozyme onto hydroxyapatite. Durapatite 34-48 lysozyme Homo sapiens 20-28 7850845-2 1994 In this study the effects of lysozyme and lactoperoxidase on the adhesion of 3H-labelled Streptococcus mutans (NCTC 10449, serotype c strain) to saliva-coated hydroxyapatite were studied at pH 5.0 and 7.0. Durapatite 159-173 lysozyme Homo sapiens 29-37 7850845-10 1994 The inhibition of adherence of a serotype c strain of S. mutans to saliva-coated hydroxyapatite is a novel antibacterial mechanism for both lysozyme and lactoperoxidase. Durapatite 81-95 lysozyme Homo sapiens 140-148 32206909-9 2020 The mixtures inhibited lysozyme and peroxidase activities on the hydroxyapatite surfaces; however, the degree of inhibition did not differ from that of hyaluronic acid of 1 or 2 MDa only. Durapatite 65-79 lysozyme Homo sapiens 23-31 34463099-0 2021 Defect Induced Charge Redistribution and Enhanced Adsorption of Lysozyme on Hydroxyapatite for Efficient Antibacterial Activity. Durapatite 76-90 lysozyme Homo sapiens 64-72 6224288-1 1983 IgA, IgG, albumin, lysozyme, alpha-amylase and glucosyltransferase were identified in the saliva coat which forms on hydroxyapatite exposed to whole saliva. Durapatite 117-131 lysozyme Homo sapiens 19-27 8381363-0 1993 Identification of the adsorbing site of lysozyme onto the hydroxyapatite surface using hydrogen exchange and 1H NMR. Durapatite 58-72 lysozyme Homo sapiens 40-48 8381363-2 1993 The H-D exchange reaction was initiated by transferring the lysozyme adsorbed on hydroxyapatite powder from H2O into D2O. Durapatite 81-95 lysozyme Homo sapiens 60-68 8381363-4 1993 The H-D exchange rate of amide protons of residues 9, 11, 13, and 83 was slowed in the hydroxyapatite-lysozyme complex compared with free lysozyme. Durapatite 87-101 lysozyme Homo sapiens 102-110 8381363-4 1993 The H-D exchange rate of amide protons of residues 9, 11, 13, and 83 was slowed in the hydroxyapatite-lysozyme complex compared with free lysozyme. Durapatite 87-101 lysozyme Homo sapiens 138-146 33455195-3 2020 With lysozyme (Lys) wrapped on the surface of Zn-based ZIF (ZIF-8), Lys/ZIF-8 could strongly bond metal ions to promote nucleation and growth of bone-like hydroxyapatite (HAp), leading to formation of HAp@Lys/ZIF-8 composites. Durapatite 155-169 lysozyme Homo sapiens 5-13 33455195-3 2020 With lysozyme (Lys) wrapped on the surface of Zn-based ZIF (ZIF-8), Lys/ZIF-8 could strongly bond metal ions to promote nucleation and growth of bone-like hydroxyapatite (HAp), leading to formation of HAp@Lys/ZIF-8 composites. Durapatite 155-169 lysozyme Homo sapiens 15-18 33455195-3 2020 With lysozyme (Lys) wrapped on the surface of Zn-based ZIF (ZIF-8), Lys/ZIF-8 could strongly bond metal ions to promote nucleation and growth of bone-like hydroxyapatite (HAp), leading to formation of HAp@Lys/ZIF-8 composites. Durapatite 155-169 lysozyme Homo sapiens 68-71 33455195-3 2020 With lysozyme (Lys) wrapped on the surface of Zn-based ZIF (ZIF-8), Lys/ZIF-8 could strongly bond metal ions to promote nucleation and growth of bone-like hydroxyapatite (HAp), leading to formation of HAp@Lys/ZIF-8 composites. Durapatite 155-169 lysozyme Homo sapiens 68-71