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Chemical Agents for Microbial Control01:27

Chemical Agents for Microbial Control

Chemicals play important roles in controlling microbial growth by targeting microbial structures and functions as sanitizers, antiseptics, disinfectants, and sterilants.Alcohols are commonly used sanitizers, effectively disrupting lipid membranes, which compromises cell integrity. They are also used as antiseptics and disinfectants due to their rapid action and versatility.Phenols and their derivatives phenolics , known for denaturing proteins and disrupting cell membranes, are particularly...
Biological Methods for Microbial Control01:28

Biological Methods for Microbial Control

Biological agents offer an effective means of controlling microbial growth by leveraging natural processes like predation, competition, and the secretion of antimicrobial substances.Predatory bacteria such as Bdellovibrio species target and kill pathogens like Salmonella and E. coli. They are widely used in poultry farms to control infections. Myxococcus species help combat plant-pathogenic fungi. These naturally occurring predators serve as eco-friendly alternatives to chemical pesticides and...
Surface Membrane Barriers01:18

Surface Membrane Barriers

The skin and mucous membranes serve as the primary line of defense against pathogens by providing both physical and chemical protection. These barriers are essential in preventing the entry and establishment of microbes, thereby maintaining the integrity of the host.
The outer layer of the skin, the epidermis, is a robust barrier comprising layers of closely packed keratinized cells. This dense arrangement prevents microbes from penetrating the body. The periodic shedding of epidermal cells...
Physical Methods for Controlling Microbial Growth: Radiation and Filtration01:26

Physical Methods for Controlling Microbial Growth: Radiation and Filtration

Radiation and filtration are essential tools for microbial control, targeting microorganisms through distinct mechanisms. Radiation eliminates microbes by damaging their DNA, either killing them or inhibiting their growth. Based on wavelength, radiation is classified into two types: nonionizing and ionizing radiation.Non-ionizing radiation, such as UV radiation (200–400 nm), is absorbed by DNA, causing defects that effectively disinfect surfaces, air, and water, including safety cabinets.
Methods for Controlling Microbial Growth01:29

Methods for Controlling Microbial Growth

Microbial growth control refers to various methods employed to inhibit, reduce, or eliminate microorganisms to ensure safety and hygiene across different settings. These methods are categorized based on the target environment and the level of microbial control required.Biocides are versatile agents designed to control microorganisms by either inhibiting their growth or outright killing them. These agents work through various physical, chemical, mechanical, or biological mechanisms. The...
Antimicrobial Effectiveness01:28

Antimicrobial Effectiveness

The effectiveness of antimicrobial agents depends on various factors influencing their ability to eliminate microbial populations. Larger microbial populations require more time for complete eradication, emphasizing the importance of population size analysis when evaluating antimicrobial efficacy.Microbial resistance to antimicrobial agents varies significantly. Highly resilient microorganisms include endospores, gram-negative bacteria, and non-enveloped viruses, while prions are exceptionally...

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Related Experiment Video

Updated: Jun 14, 2026

Evaluation of Antimicrobial Activities of Nanoparticles and Nanostructured Surfaces In Vitro
11:52

Evaluation of Antimicrobial Activities of Nanoparticles and Nanostructured Surfaces In Vitro

Published on: April 21, 2023

A substrate-independent approach for bactericidal surfaces.

W C E Schofield1, J P S Badyal

  • 1Department of Chemistry, Science Laboratories, Durham University, Durham DH1 3LE, England, United Kingdom.

ACS Applied Materials & Interfaces
|April 2, 2010
PubMed
Summary
This summary is machine-generated.

This study presents a novel method for creating antibacterial surfaces using plasmachemical functionalization. The resulting surfaces show bactericidal activity and can be regenerated, offering an eco-friendly alternative to existing methods.

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Establishing the Minimal Bactericidal Concentration of an Antimicrobial Agent for Planktonic Cells (MBC-P) and Biofilm Cells (MBC-B)
06:36

Establishing the Minimal Bactericidal Concentration of an Antimicrobial Agent for Planktonic Cells (MBC-P) and Biofilm Cells (MBC-B)

Published on: January 2, 2014

Related Experiment Videos

Last Updated: Jun 14, 2026

Evaluation of Antimicrobial Activities of Nanoparticles and Nanostructured Surfaces In Vitro
11:52

Evaluation of Antimicrobial Activities of Nanoparticles and Nanostructured Surfaces In Vitro

Published on: April 21, 2023

Establishing the Minimal Bactericidal Concentration of an Antimicrobial Agent for Planktonic Cells (MBC-P) and Biofilm Cells (MBC-B)
06:36

Establishing the Minimal Bactericidal Concentration of an Antimicrobial Agent for Planktonic Cells (MBC-P) and Biofilm Cells (MBC-B)

Published on: January 2, 2014

Area of Science:

  • Materials Science
  • Surface Chemistry
  • Biotechnology

Background:

  • Traditional antibacterial surface methods are often substrate-specific or cause environmental harm through leaching.
  • There is a need for versatile and eco-friendly antibacterial surface technologies.

Purpose of the Study:

  • To develop a new method for creating broadly applicable and regenerable antibacterial surfaces.
  • To functionalize solid surfaces with poly(4-vinyl pyridine) and quaternize them to achieve bactericidal properties.

Main Methods:

  • Plasmachemical functionalization of various solid surfaces with poly(4-vinyl pyridine).
  • Activation of the functionalized surfaces via quaternization using bromobutane.
  • Testing of the resulting surfaces for bactericidal activity and regenerability.

Main Results:

  • Successfully created bioactive surfaces with bactericidal activity through plasmachemical functionalization and quaternization.
  • Demonstrated the applicability of this method across diverse substrate materials.
  • Showcased the easy regeneration of the antibacterial properties by simple water rinsing.

Conclusions:

  • Plasmachemical functionalization offers a versatile and effective route to impart durable antibacterial properties to surfaces.
  • This quaternization approach provides a regenerable and potentially eco-friendlier alternative to conventional antibacterial surface treatments.
  • The developed method holds promise for various applications requiring antimicrobial surfaces without ecological compromise.