Plasma Biology

Irving Langmuir coined the name “plasma” to describe an ionized gas back in 1927. Just over 90 years later, plasma technology is becoming increasingly important in our daily life. For example, in the medical field and dentistry, plasma is used as a method of disinfection and sterilization. Moreover,...

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Sprache:Englisch
Veröffentlicht: MDPI - Multidisciplinary Digital Publishing Institute 2022
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description Irving Langmuir coined the name “plasma” to describe an ionized gas back in 1927. Just over 90 years later, plasma technology is becoming increasingly important in our daily life. For example, in the medical field and dentistry, plasma is used as a method of disinfection and sterilization. Moreover, additional potential novel applications of this technology in different forms of therapy have been proposed. In the agricultural sector, plasma technology could contribute to higher crop yields by enhancing seed germination and the growth of plants, as well as the preservation of foods by disinfection. Plasma technology could also be utilized in environmental applications, including water treatment and remediation, as well as treatment of exhaust gases. Although recent extensive studies have uncovered the broad potential of plasma technology, its mechanisms of action remain unclear. Therefore, further studies aimed at elucidating the molecular mechanisms of plasma technology are required. This book is composed of original articles and reviews investigating the molecular mechanisms of plasma biology. Relevant areas of study include applications in plasma medicine, plasma agriculture, as well as plasma chemistry. Studies on potential therapeutic approaches using plasma itself and plasma-treated solutions are also included.
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spelling doab-20.500.12854ir-768392024-04-09T23:16:19Z Plasma Biology Sakudo, Akikazu Yagyu, Yoshihito cold jet atmospheric pressure plasma reactive oxygen and nitrogen species backbone cleavage hydroxylation carbonyl formation cold atmospheric plasma autophagy silymarin nanoemulsion PI3K/mTOR pathway wound healing oncology regenerative medicine plasma atmospheric pressure plasma jets large-scale imaging machine learning cancer treatment cellular imaging reactive oxygen species mesoporous silica nanoparticles biomaterials bone regeneration cytotoxicity proliferation osteogenic differentiation plasma-activated medium TRAIL DR5 apoptosis ROS/RNS atmospheric-pressure plasma titanium amine mesenchymal stem cells antibiotic resistant bacteria antibiotic resistance gene disinfection E. coli inactivation sterilization cell migration endothelial cells VEGF gynaecological oncology vulva cancer risk factors plasma tissue interaction premalignant lesions cancer development patient stratification individualised profiling predictive preventive personalised medicine (PPPM/3PM) treatment Candida albicans cold plasma treatment genome hydrolytic enzyme activity carbon assimilation drug susceptibility malignant melanoma acidification nitrite acidified nitrite nitration membrane damage CAP cancer cold atmospheric pressure plasma hydrogen peroxide hypochlorous acid moDCs peroxynitrite RNS ROS non-thermal plasma biological activity breast cancer solution plasma process aqueous solutions chitin chitosan degradation deacetylation non-thermal atmospheric pressure plasma Pectobacteriaceae Dickeya spp. Pectobacterium spp. antibacterial plant protection agriculture selective cancer treatment reaction network mathematical modeling n/a Mdm2–p53 plasma treatment molecular dynamic (MD) simulations thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues Irving Langmuir coined the name “plasma” to describe an ionized gas back in 1927. Just over 90 years later, plasma technology is becoming increasingly important in our daily life. For example, in the medical field and dentistry, plasma is used as a method of disinfection and sterilization. Moreover, additional potential novel applications of this technology in different forms of therapy have been proposed. In the agricultural sector, plasma technology could contribute to higher crop yields by enhancing seed germination and the growth of plants, as well as the preservation of foods by disinfection. Plasma technology could also be utilized in environmental applications, including water treatment and remediation, as well as treatment of exhaust gases. Although recent extensive studies have uncovered the broad potential of plasma technology, its mechanisms of action remain unclear. Therefore, further studies aimed at elucidating the molecular mechanisms of plasma technology are required. This book is composed of original articles and reviews investigating the molecular mechanisms of plasma biology. Relevant areas of study include applications in plasma medicine, plasma agriculture, as well as plasma chemistry. Studies on potential therapeutic approaches using plasma itself and plasma-treated solutions are also included. 2022-01-11T13:43:46Z 2022-01-11T13:43:46Z 2021 book ONIX_20220111_9783036515687_574 9783036515687 9783036515670 https://directory.doabooks.org/handle/20.500.12854/76839 eng image/jpeg Attribution 4.0 International https://mdpi.com/books/pdfview/book/4288 https://mdpi.com/books/pdfview/book/4288 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-0365-1567-0 10.3390/books978-3-0365-1567-0 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783036515687 9783036515670 363 Basel, Switzerland open access
spellingShingle cold jet atmospheric pressure plasma
reactive oxygen and nitrogen species
backbone cleavage
hydroxylation
carbonyl formation
cold atmospheric plasma
autophagy
silymarin nanoemulsion
PI3K/mTOR pathway
wound healing
oncology
regenerative medicine
plasma
atmospheric pressure plasma jets
large-scale imaging
machine learning
cancer treatment
cellular imaging
reactive oxygen species
mesoporous silica nanoparticles
biomaterials
bone regeneration
cytotoxicity
proliferation
osteogenic differentiation
plasma-activated medium
TRAIL
DR5
apoptosis
ROS/RNS
atmospheric-pressure plasma
titanium
amine
mesenchymal stem cells
antibiotic resistant bacteria
antibiotic resistance gene
disinfection
E. coli
inactivation
sterilization
cell migration
endothelial cells VEGF
gynaecological oncology
vulva cancer
risk factors
plasma tissue interaction
premalignant lesions
cancer development
patient stratification
individualised profiling
predictive preventive personalised medicine (PPPM/3PM)
treatment
Candida albicans
cold plasma treatment
genome
hydrolytic enzyme activity
carbon assimilation
drug susceptibility
malignant melanoma
acidification
nitrite
acidified nitrite
nitration
membrane damage
CAP
cancer
cold atmospheric pressure plasma
hydrogen peroxide
hypochlorous acid
moDCs
peroxynitrite
RNS
ROS
non-thermal plasma
biological activity
breast cancer
solution plasma process
aqueous solutions
chitin
chitosan
degradation
deacetylation
non-thermal atmospheric pressure plasma
Pectobacteriaceae
Dickeya spp.
Pectobacterium spp.
antibacterial
plant protection
agriculture
selective cancer treatment
reaction network
mathematical modeling
n/a
Mdm2–p53
plasma treatment
molecular dynamic (MD) simulations
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
Plasma Biology
title Plasma Biology
title_full Plasma Biology
title_fullStr Plasma Biology
title_full_unstemmed Plasma Biology
title_short Plasma Biology
title_sort plasma biology
topic cold jet atmospheric pressure plasma
reactive oxygen and nitrogen species
backbone cleavage
hydroxylation
carbonyl formation
cold atmospheric plasma
autophagy
silymarin nanoemulsion
PI3K/mTOR pathway
wound healing
oncology
regenerative medicine
plasma
atmospheric pressure plasma jets
large-scale imaging
machine learning
cancer treatment
cellular imaging
reactive oxygen species
mesoporous silica nanoparticles
biomaterials
bone regeneration
cytotoxicity
proliferation
osteogenic differentiation
plasma-activated medium
TRAIL
DR5
apoptosis
ROS/RNS
atmospheric-pressure plasma
titanium
amine
mesenchymal stem cells
antibiotic resistant bacteria
antibiotic resistance gene
disinfection
E. coli
inactivation
sterilization
cell migration
endothelial cells VEGF
gynaecological oncology
vulva cancer
risk factors
plasma tissue interaction
premalignant lesions
cancer development
patient stratification
individualised profiling
predictive preventive personalised medicine (PPPM/3PM)
treatment
Candida albicans
cold plasma treatment
genome
hydrolytic enzyme activity
carbon assimilation
drug susceptibility
malignant melanoma
acidification
nitrite
acidified nitrite
nitration
membrane damage
CAP
cancer
cold atmospheric pressure plasma
hydrogen peroxide
hypochlorous acid
moDCs
peroxynitrite
RNS
ROS
non-thermal plasma
biological activity
breast cancer
solution plasma process
aqueous solutions
chitin
chitosan
degradation
deacetylation
non-thermal atmospheric pressure plasma
Pectobacteriaceae
Dickeya spp.
Pectobacterium spp.
antibacterial
plant protection
agriculture
selective cancer treatment
reaction network
mathematical modeling
n/a
Mdm2–p53
plasma treatment
molecular dynamic (MD) simulations
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
topic_facet cold jet atmospheric pressure plasma
reactive oxygen and nitrogen species
backbone cleavage
hydroxylation
carbonyl formation
cold atmospheric plasma
autophagy
silymarin nanoemulsion
PI3K/mTOR pathway
wound healing
oncology
regenerative medicine
plasma
atmospheric pressure plasma jets
large-scale imaging
machine learning
cancer treatment
cellular imaging
reactive oxygen species
mesoporous silica nanoparticles
biomaterials
bone regeneration
cytotoxicity
proliferation
osteogenic differentiation
plasma-activated medium
TRAIL
DR5
apoptosis
ROS/RNS
atmospheric-pressure plasma
titanium
amine
mesenchymal stem cells
antibiotic resistant bacteria
antibiotic resistance gene
disinfection
E. coli
inactivation
sterilization
cell migration
endothelial cells VEGF
gynaecological oncology
vulva cancer
risk factors
plasma tissue interaction
premalignant lesions
cancer development
patient stratification
individualised profiling
predictive preventive personalised medicine (PPPM/3PM)
treatment
Candida albicans
cold plasma treatment
genome
hydrolytic enzyme activity
carbon assimilation
drug susceptibility
malignant melanoma
acidification
nitrite
acidified nitrite
nitration
membrane damage
CAP
cancer
cold atmospheric pressure plasma
hydrogen peroxide
hypochlorous acid
moDCs
peroxynitrite
RNS
ROS
non-thermal plasma
biological activity
breast cancer
solution plasma process
aqueous solutions
chitin
chitosan
degradation
deacetylation
non-thermal atmospheric pressure plasma
Pectobacteriaceae
Dickeya spp.
Pectobacterium spp.
antibacterial
plant protection
agriculture
selective cancer treatment
reaction network
mathematical modeling
n/a
Mdm2–p53
plasma treatment
molecular dynamic (MD) simulations
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
url ONIX_20220111_9783036515687_574