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This eBook is a collection of articles from a Frontiers Research Topic. Frontiers Research Topics are very popular trademarks of the Frontiers Journals Series: they are collections of at least ten articles, all centered on a particular subject. With their unique mix of varied contributions from Original Research to Review Articles, Frontiers Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author by contacting the Frontiers Editorial Office: frontiersin.org/about/contact
Science: general issues --- Medical genetics --- histone deacetylation --- CpG methylation --- cytocrin --- epigenetic factors --- Epigenetic traits --- Pregnancy --- Sugar metabolism --- eye epigenetics --- in vitro fertilization --- histone deacetylation --- CpG methylation --- cytocrin --- epigenetic factors --- Epigenetic traits --- Pregnancy --- Sugar metabolism --- eye epigenetics --- in vitro fertilization
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This eBook is a collection of articles from a Frontiers Research Topic. Frontiers Research Topics are very popular trademarks of the Frontiers Journals Series: they are collections of at least ten articles, all centered on a particular subject. With their unique mix of varied contributions from Original Research to Review Articles, Frontiers Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author by contacting the Frontiers Editorial Office: frontiersin.org/about/contact
histone deacetylation --- CpG methylation --- cytocrin --- epigenetic factors --- Epigenetic traits --- Pregnancy --- Sugar metabolism --- eye epigenetics --- in vitro fertilization
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This eBook is a collection of articles from a Frontiers Research Topic. Frontiers Research Topics are very popular trademarks of the Frontiers Journals Series: they are collections of at least ten articles, all centered on a particular subject. With their unique mix of varied contributions from Original Research to Review Articles, Frontiers Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author by contacting the Frontiers Editorial Office: frontiersin.org/about/contact
Science: general issues --- Medical genetics --- histone deacetylation --- CpG methylation --- cytocrin --- epigenetic factors --- Epigenetic traits --- Pregnancy --- Sugar metabolism --- eye epigenetics --- in vitro fertilization
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Biocatalysis, that is, the use of biological catalysts (enzymes, cells, etc.) for the preparation of highly valuable compounds is undergoing a great development, being considered an extremely sustainable approach to undertaking environmental demands. In this scenario, this book illustrates the versatility of applied biocatalysis for the preparation of drugs and other bioactive compounds through the presentation of different research articles and reviews, in which several authors describe the most recent developments in this appealing scientific area. By reading the excellent contributions gathered in this book, it is possible to have an updated idea about new advances and possibilities for a new exciting future.
n/a --- biotransformations --- glycosidases --- bacteria --- OcUGT1 --- antioxidant activity --- glycodiverfication --- benzoxathiepins --- coprostanol --- 7-methylguanosine iodide --- sulfuretin --- chondroitin sulfates --- 7-methylguanine arabinoside iodide --- 7-methyl-2?-deoxyguanosine iodide --- microalgae --- chitosan oligosaccharides --- deacetylation degree --- cholesterol --- Tecadenoson --- esterase --- metabolic pathways --- chitinases --- alcohol --- transglycosylation reaction --- MALDI-TOF --- photooxidation --- aqueous solubility --- ?-transaminase --- cascade --- nutraceutical --- antimuscarinic agents --- extraction --- rutin oligomers --- Alcalase® --- HPSEC --- Cladribine --- purine nucleoside phosphorylase --- pleiotropic effects --- biotransamination --- amino acid --- stereoselective --- laccase activity --- biocatalysis --- Ribavirin --- lyases --- chitosanases --- anti-inflammatory --- glycosaminoglycan --- polysaccharides --- amine transaminases --- ester hydrolysis --- Spirulina --- asymmetric synthesis --- reductive amination --- glycosyltransferase --- statins --- stereoselective synthesis --- xanthine oxidase inhibition --- reduction reaction --- pig liver esterase (PLE)
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Natural polysaccharides, such as cellulose and chitin, possess unique hierarchical nanoarchitectures that can never be artificially reconstructed, and their nano-organized structures are involved in the hidden materials functions with great potential. Pioneering the emerging functions of nano-organized polysaccharides will break through to achieve the Sustainable Development Goals.
Technology: general issues --- chitin nanofiber --- deacetylated chitin --- nanopaper --- thermal diffusivity --- powder electroluminescent device --- cellulose nanofiber --- paper electronic device --- paper-based light-emitting device --- dehydrogenative polymer --- enzymatic radical coupling --- lignin --- nanocellulose --- microsphere --- TEMPO-oxidized cellulose nanofiber --- chitosan−ZnCl2 complex --- crystal structure --- X-ray fiber diffraction --- nanofibrillated bacterial cellulose --- bacterial cellulose --- peritoneally disseminated gastric cancer --- doxorubicin --- intraperitoneal chemotherapy --- hemicellulose --- xylan --- nanocrystal --- Pickering emulsion --- cellulose derivatives --- cellulose nanocrystal --- cholesteric liquid crystal --- functional materials --- material form --- cellulose nanofibers --- nanocomposite --- xerogel --- flame-retardant --- polydopamine doping --- pyrolysis --- 3D porous nanocarbon --- supercapacitor --- surface carboxylation --- surface deacetylation --- cell culture scaffold --- skin repair --- wound healing --- biomedical applications --- functional nanocomposite --- aqueous process --- sol–gel --- hydrogels --- aerogels --- freeze-drying --- cryogels --- n/a --- sol-gel
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Natural polysaccharides, such as cellulose and chitin, possess unique hierarchical nanoarchitectures that can never be artificially reconstructed, and their nano-organized structures are involved in the hidden materials functions with great potential. Pioneering the emerging functions of nano-organized polysaccharides will break through to achieve the Sustainable Development Goals.
chitin nanofiber --- deacetylated chitin --- nanopaper --- thermal diffusivity --- powder electroluminescent device --- cellulose nanofiber --- paper electronic device --- paper-based light-emitting device --- dehydrogenative polymer --- enzymatic radical coupling --- lignin --- nanocellulose --- microsphere --- TEMPO-oxidized cellulose nanofiber --- chitosan−ZnCl2 complex --- crystal structure --- X-ray fiber diffraction --- nanofibrillated bacterial cellulose --- bacterial cellulose --- peritoneally disseminated gastric cancer --- doxorubicin --- intraperitoneal chemotherapy --- hemicellulose --- xylan --- nanocrystal --- Pickering emulsion --- cellulose derivatives --- cellulose nanocrystal --- cholesteric liquid crystal --- functional materials --- material form --- cellulose nanofibers --- nanocomposite --- xerogel --- flame-retardant --- polydopamine doping --- pyrolysis --- 3D porous nanocarbon --- supercapacitor --- surface carboxylation --- surface deacetylation --- cell culture scaffold --- skin repair --- wound healing --- biomedical applications --- functional nanocomposite --- aqueous process --- sol–gel --- hydrogels --- aerogels --- freeze-drying --- cryogels --- n/a --- sol-gel
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Natural polysaccharides, such as cellulose and chitin, possess unique hierarchical nanoarchitectures that can never be artificially reconstructed, and their nano-organized structures are involved in the hidden materials functions with great potential. Pioneering the emerging functions of nano-organized polysaccharides will break through to achieve the Sustainable Development Goals.
Technology: general issues --- chitin nanofiber --- deacetylated chitin --- nanopaper --- thermal diffusivity --- powder electroluminescent device --- cellulose nanofiber --- paper electronic device --- paper-based light-emitting device --- dehydrogenative polymer --- enzymatic radical coupling --- lignin --- nanocellulose --- microsphere --- TEMPO-oxidized cellulose nanofiber --- chitosan−ZnCl2 complex --- crystal structure --- X-ray fiber diffraction --- nanofibrillated bacterial cellulose --- bacterial cellulose --- peritoneally disseminated gastric cancer --- doxorubicin --- intraperitoneal chemotherapy --- hemicellulose --- xylan --- nanocrystal --- Pickering emulsion --- cellulose derivatives --- cellulose nanocrystal --- cholesteric liquid crystal --- functional materials --- material form --- cellulose nanofibers --- nanocomposite --- xerogel --- flame-retardant --- polydopamine doping --- pyrolysis --- 3D porous nanocarbon --- supercapacitor --- surface carboxylation --- surface deacetylation --- cell culture scaffold --- skin repair --- wound healing --- biomedical applications --- functional nanocomposite --- aqueous process --- sol-gel --- hydrogels --- aerogels --- freeze-drying --- cryogels --- chitin nanofiber --- deacetylated chitin --- nanopaper --- thermal diffusivity --- powder electroluminescent device --- cellulose nanofiber --- paper electronic device --- paper-based light-emitting device --- dehydrogenative polymer --- enzymatic radical coupling --- lignin --- nanocellulose --- microsphere --- TEMPO-oxidized cellulose nanofiber --- chitosan−ZnCl2 complex --- crystal structure --- X-ray fiber diffraction --- nanofibrillated bacterial cellulose --- bacterial cellulose --- peritoneally disseminated gastric cancer --- doxorubicin --- intraperitoneal chemotherapy --- hemicellulose --- xylan --- nanocrystal --- Pickering emulsion --- cellulose derivatives --- cellulose nanocrystal --- cholesteric liquid crystal --- functional materials --- material form --- cellulose nanofibers --- nanocomposite --- xerogel --- flame-retardant --- polydopamine doping --- pyrolysis --- 3D porous nanocarbon --- supercapacitor --- surface carboxylation --- surface deacetylation --- cell culture scaffold --- skin repair --- wound healing --- biomedical applications --- functional nanocomposite --- aqueous process --- sol-gel --- hydrogels --- aerogels --- freeze-drying --- cryogels
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This book presents recent advances in the field of bone tissue engineering, including molecular insights, innovative biomaterials with regenerative properties (e.g., osteoinduction and osteoconduction), and physical stimuli to enhance bone regeneration.
Medicine --- bone --- collagen type I --- alginate --- conditioned medium --- viability --- MSC --- osteogenesis --- pulsed electromagnetic field --- osteogenic factors --- wool keratin scaffolds --- bone tissue engineering --- biocompatibility --- biomaterials --- bone augmentation --- bone conduction --- bone grafting --- calcium hydroxyapatite --- tissue regeneration --- dental implants --- osseointegration --- osteoporosis --- zoledronate --- animal model --- titanium membrane --- titanium foil --- occlusive titanium barrier --- guided bone regeneration --- osteoporotic condition --- xenograft --- bone regeneration --- titanium implants --- additive manufacturing --- reused powder --- unit cell topology --- tissue engineering --- mechanical properties --- stem cells --- surface functionalization --- titanium --- protein adsorption --- surface modifications --- cell interactions --- collagen hydrogel --- cell delivery --- olfactory ectomesenchyme stem cells --- bioactive glasses --- alkali-free --- sol–gel --- bone remodeling --- bone disorders --- biomechanics --- scaffolds --- microenvironment --- 3D bioprinting --- computational modeling --- bone implant --- bone defects --- chitosan --- degree of deacetylation --- bone formation --- X-ray micro CT --- histology --- sheep tibia
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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.
Technology: general issues --- 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 --- Mdm2-p53 --- plasma treatment --- molecular dynamic (MD) simulations --- 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 --- Mdm2-p53 --- plasma treatment --- molecular dynamic (MD) simulations
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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.
Technology: general issues --- 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 --- Mdm2-p53
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