Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Physical Methods for Controlling Microbial Growth: Radiation and Filtration01:26

Physical Methods for Controlling Microbial Growth: Radiation and Filtration

1.4K
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.
1.4K
Key Techniques in Microbiology01:19

Key Techniques in Microbiology

2.8K
Aseptic techniques prevent contamination, ensure experimental accuracy, and protect researchers and microbial cultures. These techniques are essential in clinical, industrial, and research settings where sterility is required.Maintaining Sterility in Laboratory PracticesScientists maintain sterility by sterilizing tools with heat or chemicals, disinfecting work surfaces, and handling cultures in controlled environments. Working near an open flame or within a laminar flow hood reduces the risk...
2.8K
Physical Methods for Controlling Microbial Growth: Temperature01:23

Physical Methods for Controlling Microbial Growth: Temperature

1.4K
Heat is a widely used method to control microbial growth by targeting and denaturing cellular proteins, thereby killing or inactivating microbes. This method's effectiveness is quantified using parameters such as the thermal death point (TDP), thermal death time (TDT), and decimal reduction time (D value). TDP represents the lowest temperature at which all microorganisms in a liquid suspension are eliminated within 10 minutes, whereas TDT is the time necessary to achieve sterilization at a...
1.4K
Factors Influencing Microbial Growth: Temperature01:27

Factors Influencing Microbial Growth: Temperature

1.6K
Microorganisms display remarkable adaptations, enabling them to thrive in diverse ecological niches across a wide range of temperatures. Temperature profoundly influences microbial growth by affecting enzymatic activity, membrane fluidity, and other cellular processes.Each microorganism operates within a specific temperature range defined by three cardinal points: minimum, optimum, and maximum. Below the minimum temperature, membranes lose fluidity, halting transport processes. Above the...
1.6K
Biological Methods for Microbial Control01:28

Biological Methods for Microbial Control

1.1K
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...
1.1K

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Extended-spectrum β-lactamase-producing bacteria from hospital wastewater pipes: isolation, characterization and biofilm control using common disinfectants.

The Journal of hospital infection·2024
Same author

More than just the gene: investigating expression using a non-native plasmid and host and its impact on resistance conferred by β-lactamase OXA-58 isolated from a hospital wastewater microbiome.

Letters in applied microbiology·2024
Same author

Microbiome-derived antimicrobial peptides show therapeutic activity against the critically important priority pathogen, Acinetobacter baumannii.

NPJ biofilms and microbiomes·2024
Same author

A novel characterized multi-drug-resistant Pseudocitrobacter sp. isolated from a patient colonized while admitted to a tertiary teaching hospital.

The Journal of hospital infection·2024
Same author

Large-scale characterization of hospital wastewater system microbiomes and clinical isolates from infected patients: profiling of multi-drug-resistant microbial species.

The Journal of hospital infection·2023
Same author

Acinetobacter baumannii biofilm biomass mediates tolerance to cold plasma.

Letters in applied microbiology·2019
Same journal

Investigating the antimicrobial efficacy of two aerosolised hydrogen peroxide fumigation cycles for biological safety cabinet decontamination.

Journal of applied microbiology·2026
Same journal

Phytochemical profile and anticryptococcal activity of a phenolic-rich fraction from the bark of Myracrodruon urundeuva M. Allemão.

Journal of applied microbiology·2026
Same journal

Streptococcus thermophilus 1131 and Lactobacillus delbrueckii subsp. bulgaricus 2038 induce immune responses via M cell-mediated transcytosis in an in vitro human gut model.

Journal of applied microbiology·2026
Same journal

The oral phageome in human health, disease, and clinical implications.

Journal of applied microbiology·2026
Same journal

Lactiplantibacillus plantarum LSC3 attenuates anaphylactic response in a murine model of food allergy.

Journal of applied microbiology·2026
Same journal

Isolation, Genomic Analysis, and Evaluation of the Novel Lytic Phage vB_Cf_HW01: Potent Antibiofilm Activity and Therapeutic Efficacy Against a Clinical Isolate of Citrobacter freundii.

Journal of applied microbiology·2026
See all related articles

Related Experiment Video

Updated: Mar 7, 2026

Investigating the Detrimental Effects of Low Pressure Plasma Sterilization on the Survival of Bacillus subtilis Spores Using Live Cell Microscopy
10:03

Investigating the Detrimental Effects of Low Pressure Plasma Sterilization on the Survival of Bacillus subtilis Spores Using Live Cell Microscopy

Published on: November 30, 2017

10.1K

Microbiological interactions with cold plasma.

P Bourke1, D Ziuzina1, L Han1

  • 1Plasma Research Group, School of Food Science and Environmental Health, Dublin Institute of Technology, Dublin 1, Ireland.

Journal of Applied Microbiology
|March 1, 2017
PubMed
Summary
This summary is machine-generated.

Cold plasma (CP) offers a novel approach to combatting microbial resistance and biofilms in food and healthcare. This technology utilizes reactive oxygen and nitrogen species for effective decontamination and treatment.

Keywords:
anti-microbial resistancebiofilmscold plasma technologyfoodhealthcaremechanism of actionmicrobiological interactions

More Related Videos

Basic Research in Plasma Medicine - A Throughput Approach from Liquids to Cells
07:37

Basic Research in Plasma Medicine - A Throughput Approach from Liquids to Cells

Published on: November 17, 2017

13.5K
An Atmospheric Pressure Plasma Setup to Investigate the Reactive Species Formation
08:36

An Atmospheric Pressure Plasma Setup to Investigate the Reactive Species Formation

Published on: November 3, 2016

10.5K

Related Experiment Videos

Last Updated: Mar 7, 2026

Investigating the Detrimental Effects of Low Pressure Plasma Sterilization on the Survival of Bacillus subtilis Spores Using Live Cell Microscopy
10:03

Investigating the Detrimental Effects of Low Pressure Plasma Sterilization on the Survival of Bacillus subtilis Spores Using Live Cell Microscopy

Published on: November 30, 2017

10.1K
Basic Research in Plasma Medicine - A Throughput Approach from Liquids to Cells
07:37

Basic Research in Plasma Medicine - A Throughput Approach from Liquids to Cells

Published on: November 17, 2017

13.5K
An Atmospheric Pressure Plasma Setup to Investigate the Reactive Species Formation
08:36

An Atmospheric Pressure Plasma Setup to Investigate the Reactive Species Formation

Published on: November 3, 2016

10.5K

Area of Science:

  • Microbiology
  • Biophysics
  • Biotechnology

Background:

  • Growing antibiotic resistance and concerns with biocidal agents necessitate new antimicrobial strategies.
  • Microbiological challenges in food, healthcare, and clinical settings are significant.
  • Biofilms present enhanced stability, making them a key research focus.

Purpose of the Study:

  • To review the basics of cold plasma (CP) technology.
  • To discuss CP's interactions with microbiological targets.
  • To explore CP applications in food and clinical settings, focusing on infections and mechanisms.

Main Methods:

  • Review of cold plasma technology principles.
  • Analysis of CP interactions with diverse microbial targets.
  • Examination of mechanistic insights and applications.

Main Results:

  • Cold plasma generates reactive oxygen and nitrogen species for decontamination.
  • CP shows potential in microbial decontamination, wound healing, and cancer treatment.
  • Tailoring CP offers control over specific microbiological challenges.

Conclusions:

  • Cold plasma is an evolving technology for microbial decontamination.
  • CP has significant potential in addressing food and healthcare-associated infections.
  • Further research into plasma mechanisms can optimize its application.