﻿<?xml version="1.0" encoding="utf-8" ?>
<XML>
  <ISCJOURNAL>
    <YEAR>2023</YEAR>
    <VOL>5</VOL>
    <NO>16</NO>
    <MOSALSAL>16</MOSALSAL>
    <PAGE_NO>20</PAGE_NO>
    <ARTICLES>
      <DOI>10.61186/jcc.5.3.2</DOI>      
      <ARTICLE>
        <LANGUAGE_ID>1</LANGUAGE_ID>
        <TitleF/>
        <TitleE>Advancements in nanoparticle-supported Laccase immobilization:Offering promising solutions for water treatment</TitleE>        
        <ABSTRACTS>
          <ABSTRACT>
            <LANGUAGE_ID>1</LANGUAGE_ID>
            <CONTENT>Water purification has become a crucial matter in various societies. Increasing demand for water treatment is a 
              constant challenge in the field of water treatment. Nowadays enzyme immobilization plays a crucial role in the 
              realm of water cleansing. Also, laccase is the most common enzyme used in this context. Laccase is an enzyme 
              that has gained popularity in various water treatment applications due to its ability to degrade organic pollutants 
              and contaminants. It can be used in combination with different materials, including nanoparticles, to enhance its 
              performance in water purification processes. Laccase is known for its effectiveness in breaking down a wide range 
              of organic compounds, making it a valuable tool in the field of water refinement and environmental remediation. 
              This study aims to delve into current knowledge about the role of nanoparticles supported in laccase immobilization
              for water purification. Our exploration method describes the use of metal-based, magnetic, carbon-based, 
              and other nanoparticle supports along with novel methods including cross-linking, covalent binding, encapsulation,
              adsorption, and layer-by-layer assembly used in laccase immobilization. Results reveal the effectiveness 
              of diverse nanoparticles in enhancing laccase stability and activity. In conclusion underscores the potential of 
              nanoparticle-supported laccase immobilization as a sustainable solution for water treatment, offering improved 
              enzyme performance and reusability.</CONTENT>
          </ABSTRACT>
        </ABSTRACTS>
        <PAGES>
          <PAGE>
            <FPAGE>159</FPAGE>
            <TPAGE>178</TPAGE>
          </PAGE>
        </PAGES>
        <AUTHORS>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Sogand</NameE>
            <MidNameE/>
            <FamilyE>Bahadori</FamilyE>
            <Organizations>
              <Organization>Department of Chemistry, Kerman Branch, Islamic Azad University</Organization>
            </Organizations>
            <Countries>
              <Country>Iran</Country>
            </Countries>
            <EMAILS>
              <Email>Sogolbahadori@gmail.com</Email>
            </EMAILS>
          </AUTHOR>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Maryam</NameE>
            <MidNameE/>
            <FamilyE> Azimpour</FamilyE>
            <Organizations>
              <Organization>Hospital of Shahid Ayatollah Dastgheib, Shiraz University of Medical Science</Organization>
            </Organizations>
            <Countries>
              <Country>Iran</Country>
            </Countries>
            <EMAILS>
              <Email>info@jourcc.com</Email>
            </EMAILS>         
          </AUTHOR>
        </AUTHORS>
        <KEYWORDS>
          <KEYWORD>
            <KeyText>Laccase immobilization</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Nanoparticle-supported materials</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Metal-based materials</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Magnetic nanomaterials</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Carbon-based nanomaterials</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Immobilization methods</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Water treatment</KeyText>
          </KEYWORD>
        </KEYWORDS>
        <PDFFileName>Article2.pdf</PDFFileName>
        <REFRENCES>
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