ABOUT INDEXING EDITORIAL BOARD ARCHIVES AUTHOR GUIDELINES SUBMIT PAPER NEWS, EVENTS AUTHOR'S PAGE CONTACT
Materiale Plastice
Cite as: Mater. Plast.
https://doi.org/10.37358/Mat.Plast.1964

OSIM Nr. R102356
ISSN Print 0025-5289
ISSN Online 2668-8220
Journal Metrics
* Impact factor 2020: 0.593
Materiale Plastice - Latest Issue

Latest Issue >>>
ARCHIVES
   Volume 59, 2022
   Volume 58, 2021
   Volume 57, 2020
   Volume 56, 2019
   Volume 55, 2018
   Volume 54, 2017
   Volume 53, 2016
   Volume 52, 2015
   Volume 51, 2014
   Volume 50, 2013
   Volume 49, 2012
   Volume 48, 2011
   Volume 47, 2010
   Volume 46, 2009
   Volume 45, 2008
   Volume 44, 2007
   Volume 43, 2006
   Volume 42, 2005
   Volume 41, 2004
   Volume 40, 2003
 
<<<< back

Materiale Plastice (Mater. Plast.), Year 2022, Volume 59, Issue 1, 99-108

https://doi.org/10.37358/MP.22.1.5563

Adina Milena Tatar, Nicoleta Maria Mihut, Minodora Maria Pasare, Liviu Cirtina, Olivia Roxana Alecsoiu, Dragos Pasculescu, Roxana Avramoiu

Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm


Abstract:
Infections that occur after the insertion of biomedical devices are a major problem; potential sources of infection are due to the adhesion of bacteria on the surface of implants, bacteria that form biofilms. In order to combat or to effectively prevent various microbial, which occur in medical procedures, we try to make compounds and materials that prevent the formation or development of microbial biofilm. The aim of this study was to obtain nanostructured surfaces based on magnetite, carboxymethylcellulose and ceftriaxone, as films with anti-infective properties in order to use them in the field of current biomedicine. To obtain nanostructured surfaces with high non-stick potential, the carboxymethylcellulose-functionalized magnetite powder was homogenized with an anti-infective agent, ceftriaxone. From the analysis of the obtained results it was found that the nanostructured surfaces obtained had a strong antimicrobial character infections and can be used successfully in the coating of medical implants, in order to combat the microbial biofilm.


Keywords:
nanostructured surfaces; microbial biofilm; nanoparticles; magnetite; nanotechnologies

Issue: 2022 Volume 59, Issue 1
Pages: 99-108
Publication date: 2022/4/5
https://doi.org/10.37358/MP.22.1.5563
download pdf   Download Pdf Article
Creative Commons License
This article is published under the Creative Commons Attribution 4.0 International License
Citation Styles
Cite this article as:
TATAR, A.M., MIHUT, N.M., PASARE, M.M., CIRTINA, L., ALECSOIU, O.R., PASCULESCU, D., AVRAMOIU, R., Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm, Mater. Plast., 59(1), 2022, 99-108. https://doi.org/10.37358/MP.22.1.5563

Vancouver
Tatar AM, Mihut NM, Pasare MM, Cirtina L, Alecsoiu OR, Pasculescu D, Avramoiu R. Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm. Mater. Plast.[internet]. 2022 Jan;59(1):99-108. Available from: https://doi.org/10.37358/MP.22.1.5563


APA 6th edition
Tatar, A.M., Mihut, N.M., Pasare, M.M., Cirtina, L., Alecsoiu, O.R., Pasculescu, D. & Avramoiu, R. (2022). Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm. Materiale Plastice, 59(1), 99-108. https://doi.org/10.37358/MP.22.1.5563


Harvard
Tatar, A.M., Mihut, N.M., Pasare, M.M., Cirtina, L., Alecsoiu, O.R., Pasculescu, D., Avramoiu, R. (2022). 'Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm', Materiale Plastice, 59(1), pp. 99-108. https://doi.org/10.37358/MP.22.1.5563


IEEE
A.M. Tatar, N.M. Mihut, M.M. Pasare, L. Cirtina, O.R. Alecsoiu, D. Pasculescu, R. Avramoiu, "Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm". Materiale Plastice, vol. 59, no. 1, pp. 99-108, 2022. [online]. https://doi.org/10.37358/MP.22.1.5563


Text
Adina Milena Tatar, Nicoleta Maria Mihut, Minodora Maria Pasare, Liviu Cirtina, Olivia Roxana Alecsoiu, Dragos Pasculescu, Roxana Avramoiu,
Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm,
Materiale Plastice,
Volume 59, Issue 1,
2022,
Pages 99-108,
ISSN 2668-8220,
https://doi.org/10.37358/MP.22.1.5563.
(https://revmaterialeplastice.ro/Articles.asp?ID=5563)
Keywords: nanostructured surfaces; microbial biofilm; nanoparticles; magnetite; nanotechnologies


RIS
TY - JOUR
T1 - Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm
A1 - Tatar, Adina Milena
A2 - Mihut, Nicoleta Maria
A3 - Pasare, Minodora Maria
A4 - Cirtina, Liviu
A5 - Alecsoiu, Olivia Roxana
A6 - Pasculescu, Dragos
A7 - Avramoiu, Roxana
JF - Materiale Plastice
JO - Mater. Plast.
PB - Materiale Plastice SRL
SN - 2668-8220
Y1 - 2022
VL - 59
IS - 1
SP - 99
EP - 108
UR - https://doi.org/10.37358/MP.22.1.5563
KW - nanostructured surfaces
KW - microbial biofilm
KW - nanoparticles
KW - magnetite
KW - nanotechnologies
ER -


BibTex
@article{MatPlast2022P99,
author = {Tatar Adina Milena and Mihut Nicoleta Maria and Pasare Minodora Maria and Cirtina Liviu and Alecsoiu Olivia Roxana and Pasculescu Dragos and Avramoiu Roxana},
title = {Research on Obtaining Nanostructured Surfaces Efficient in Combating Microbial Biofilm},
journal = {Materiale Plastice},
volume = {59},
number = {1},
pages = {99-108},
year = {2022},
issn = {2668-8220},
doi = {https://doi.org/10.37358/MP.22.1.5563},
url = {https://revmaterialeplastice.ro/Articles.asp?ID=5563}
}


Download article Citations:
 PlainText citation Plain Text
 Text citation Text
 GoogleScholar citation Google Scholar


Downloads number: 12
<<<< back
 
  Search Authors
Crossref Member Badge
 DOI  logo
 Gold Open Access | Source=http://www.plos.org/  | Author=art designer at PLoS
Creative Commons License