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The book starts with the editors’ preface summarizing the contributions of each of the following thirteen articles dealing with chemical and pharmacological aspects of the molecular modulators of the oxidative stress in regard to various therapeutic approaches in cardiovascular and neurodegenerative diseases, cancer, and diabetes. The seven articles present data from original research studies enlightening the roles and mechanisms of action of small molecular weight compounds (natural and synthetic; ascorbic acid/vitamin C, deferoxamine, N-acetylcysteine, MitoVitE, α-tocopherol, trolox, and ezetimibe) or proteins (SIRT3) in modulation of oxidative stress. In the six review papers, the authors present and discuss the possible therapeutic potential of novel approaches and compounds that are promising and deserve further investigation, in modulation of oxidative stress.
Research & information: general --- Biology, life sciences --- ascorbic acid --- deferoxamine --- N-acetylcysteine --- ischemia/reperfusion --- cardiac fibroblasts --- reactive oxygen species --- photobiomodulation --- reactive oxygen species (ROS) --- nuclear factor kappa-light-chain-enhancer of activated B cells (NF-кB) --- cancer --- diabetes --- wound healing --- glucose --- pentose phosphate pathway --- NADPH --- redox balance --- glycogen --- glycolysis --- stress resistance --- insulin resistance --- immunomodulation --- inflammation --- olive tree --- oxidative stress --- secoirioids --- sirtuin 3 --- high fat diet --- sex differences --- mice --- metabolic stress --- antioxidants --- ADHD --- Nrf2 --- NRF2-KEAP1 --- ROS --- cancer metabolism --- antioxidant --- cancer therapy --- chemoresistance --- radioresistance --- sepsis --- MitoVitE --- mitochondria --- gene expression --- cytokines --- mRNA --- vitamin C --- folic acid --- one-carbon metabolism --- C2C12 cells --- metabolomics --- mass spectrometry --- type 2 diabetes --- dipeptidyl peptidase-4 inhibitors --- biomarkers --- ER stress --- Ezetimibe --- ischemia-reperfusion --- ionizing radiation --- liver --- hydroperoxide --- epigenetics --- miR7/MAFG/Nrf2 axe --- n/a
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The book starts with the editors’ preface summarizing the contributions of each of the following thirteen articles dealing with chemical and pharmacological aspects of the molecular modulators of the oxidative stress in regard to various therapeutic approaches in cardiovascular and neurodegenerative diseases, cancer, and diabetes. The seven articles present data from original research studies enlightening the roles and mechanisms of action of small molecular weight compounds (natural and synthetic; ascorbic acid/vitamin C, deferoxamine, N-acetylcysteine, MitoVitE, α-tocopherol, trolox, and ezetimibe) or proteins (SIRT3) in modulation of oxidative stress. In the six review papers, the authors present and discuss the possible therapeutic potential of novel approaches and compounds that are promising and deserve further investigation, in modulation of oxidative stress.
Research & information: general --- Biology, life sciences --- ascorbic acid --- deferoxamine --- N-acetylcysteine --- ischemia/reperfusion --- cardiac fibroblasts --- reactive oxygen species --- photobiomodulation --- reactive oxygen species (ROS) --- nuclear factor kappa-light-chain-enhancer of activated B cells (NF-кB) --- cancer --- diabetes --- wound healing --- glucose --- pentose phosphate pathway --- NADPH --- redox balance --- glycogen --- glycolysis --- stress resistance --- insulin resistance --- immunomodulation --- inflammation --- olive tree --- oxidative stress --- secoirioids --- sirtuin 3 --- high fat diet --- sex differences --- mice --- metabolic stress --- antioxidants --- ADHD --- Nrf2 --- NRF2-KEAP1 --- ROS --- cancer metabolism --- antioxidant --- cancer therapy --- chemoresistance --- radioresistance --- sepsis --- MitoVitE --- mitochondria --- gene expression --- cytokines --- mRNA --- vitamin C --- folic acid --- one-carbon metabolism --- C2C12 cells --- metabolomics --- mass spectrometry --- type 2 diabetes --- dipeptidyl peptidase-4 inhibitors --- biomarkers --- ER stress --- Ezetimibe --- ischemia-reperfusion --- ionizing radiation --- liver --- hydroperoxide --- epigenetics --- miR7/MAFG/Nrf2 axe --- n/a
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The book starts with the editors’ preface summarizing the contributions of each of the following thirteen articles dealing with chemical and pharmacological aspects of the molecular modulators of the oxidative stress in regard to various therapeutic approaches in cardiovascular and neurodegenerative diseases, cancer, and diabetes. The seven articles present data from original research studies enlightening the roles and mechanisms of action of small molecular weight compounds (natural and synthetic; ascorbic acid/vitamin C, deferoxamine, N-acetylcysteine, MitoVitE, α-tocopherol, trolox, and ezetimibe) or proteins (SIRT3) in modulation of oxidative stress. In the six review papers, the authors present and discuss the possible therapeutic potential of novel approaches and compounds that are promising and deserve further investigation, in modulation of oxidative stress.
ascorbic acid --- deferoxamine --- N-acetylcysteine --- ischemia/reperfusion --- cardiac fibroblasts --- reactive oxygen species --- photobiomodulation --- reactive oxygen species (ROS) --- nuclear factor kappa-light-chain-enhancer of activated B cells (NF-кB) --- cancer --- diabetes --- wound healing --- glucose --- pentose phosphate pathway --- NADPH --- redox balance --- glycogen --- glycolysis --- stress resistance --- insulin resistance --- immunomodulation --- inflammation --- olive tree --- oxidative stress --- secoirioids --- sirtuin 3 --- high fat diet --- sex differences --- mice --- metabolic stress --- antioxidants --- ADHD --- Nrf2 --- NRF2-KEAP1 --- ROS --- cancer metabolism --- antioxidant --- cancer therapy --- chemoresistance --- radioresistance --- sepsis --- MitoVitE --- mitochondria --- gene expression --- cytokines --- mRNA --- vitamin C --- folic acid --- one-carbon metabolism --- C2C12 cells --- metabolomics --- mass spectrometry --- type 2 diabetes --- dipeptidyl peptidase-4 inhibitors --- biomarkers --- ER stress --- Ezetimibe --- ischemia-reperfusion --- ionizing radiation --- liver --- hydroperoxide --- epigenetics --- miR7/MAFG/Nrf2 axe --- n/a
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The book is a collection of original research and review articles addressing the intriguing field of the cellular and molecular players involved in muscle homeostasis and regeneration. One of the most ambitious aspirations of modern medical science is the possibility of regenerating any damaged part of the body, including skeletal muscle. This desire has prompted clinicians and researchers to search for innovative technologies aimed at replacing organs and tissues that are compromised. In this context, the papers, collected in this book, addressing a specific aspects of muscle homeostasis and regeneration under physiopathologic conditions, will help us to better understand the underlying mechanisms of muscle healing and will help to design more appropriate therapeutic approaches to improve muscle regeneration and to counteract muscle diseases.
Research & information: general --- Biology, life sciences --- lysine --- mTORC1 --- satellite cells --- proliferation --- skeletal muscle growth --- muscle satellite cell --- transthyretin --- thyroid hormone --- myogenesis --- exosomes --- skeletal muscle --- genotype --- genetic variation --- muscle phenotypes --- sarcopenia --- aging --- calcium homeostasis --- hibernation --- mitochondria --- sarcoplasmic reticulum --- Acvr1b --- Tgfbr1 --- myostatin --- Col1a1 --- fibrosis --- atrophy --- IGF2R --- muscle homeostasis --- inflammation --- muscular dystrophy --- pericytes --- macrophages --- Nfix --- phagocytosis --- RhoA-ROCK1 --- splicing isoforms --- CRISPR-Cas9 --- exon deletion --- NF-Y --- muscle differentiation --- C2C12 cells --- denervation --- neuromuscular junction --- heavy resistance exercise --- acetylcholine receptor --- cell culture --- neonatal myosin --- neural cell adhesion molecule --- biomarkers --- mitophagy --- mitochondrial dynamics --- mitochondrial quality control --- mitochondrial-derived vesicles (MDVs) --- mitochondrial-lysosomal axis --- Hibernation --- electron microscopy --- immunocytochemistry --- α-smooth muscle actin --- confocal microscopy --- connexin 43 --- connexin 26 --- gap junctions --- myofibroblasts --- Platelet-Rich Plasma --- transforming growth factor (TGF)-β1 --- muscle regeneration --- inflammatory response --- cell precursors --- experimental methods --- stem cell markers --- muscles --- heterotopic ossification --- skeletal muscle stem and progenitor cells --- HO precursors --- muscle atrophy --- septicemia --- mitochondrial fusion --- mitochondrial fission --- iPSC --- extracellular vesicles --- Drosophila --- muscle --- genetic control --- muscle diversification --- fascicle --- myofiber --- myofibril --- sarcomere --- hypertrophy --- hyperplasia --- splitting --- radial growth --- longitudinal growth --- exercise --- muscle stem cells --- stem cells niche --- neuromuscular disorders --- Duchenne muscular dystrophy --- pharmacological approach --- single-cell --- mass cytometry --- skeletal muscle regeneration --- skeletal muscle homeostasis --- fibro/adipogenic progenitors --- myogenic progenitors --- muscle populations --- evolution --- metazoans --- differentiation --- transdifferentiation --- muscle precursors --- regenerative medicine --- stem cells --- FAPs --- tissue niche --- growth factors --- muscle pathology
Choose an application
The book is a collection of original research and review articles addressing the intriguing field of the cellular and molecular players involved in muscle homeostasis and regeneration. One of the most ambitious aspirations of modern medical science is the possibility of regenerating any damaged part of the body, including skeletal muscle. This desire has prompted clinicians and researchers to search for innovative technologies aimed at replacing organs and tissues that are compromised. In this context, the papers, collected in this book, addressing a specific aspects of muscle homeostasis and regeneration under physiopathologic conditions, will help us to better understand the underlying mechanisms of muscle healing and will help to design more appropriate therapeutic approaches to improve muscle regeneration and to counteract muscle diseases.
Research & information: general --- Biology, life sciences --- lysine --- mTORC1 --- satellite cells --- proliferation --- skeletal muscle growth --- muscle satellite cell --- transthyretin --- thyroid hormone --- myogenesis --- exosomes --- skeletal muscle --- genotype --- genetic variation --- muscle phenotypes --- sarcopenia --- aging --- calcium homeostasis --- hibernation --- mitochondria --- sarcoplasmic reticulum --- Acvr1b --- Tgfbr1 --- myostatin --- Col1a1 --- fibrosis --- atrophy --- IGF2R --- muscle homeostasis --- inflammation --- muscular dystrophy --- pericytes --- macrophages --- Nfix --- phagocytosis --- RhoA-ROCK1 --- splicing isoforms --- CRISPR-Cas9 --- exon deletion --- NF-Y --- muscle differentiation --- C2C12 cells --- denervation --- neuromuscular junction --- heavy resistance exercise --- acetylcholine receptor --- cell culture --- neonatal myosin --- neural cell adhesion molecule --- biomarkers --- mitophagy --- mitochondrial dynamics --- mitochondrial quality control --- mitochondrial-derived vesicles (MDVs) --- mitochondrial-lysosomal axis --- Hibernation --- electron microscopy --- immunocytochemistry --- α-smooth muscle actin --- confocal microscopy --- connexin 43 --- connexin 26 --- gap junctions --- myofibroblasts --- Platelet-Rich Plasma --- transforming growth factor (TGF)-β1 --- muscle regeneration --- inflammatory response --- cell precursors --- experimental methods --- stem cell markers --- muscles --- heterotopic ossification --- skeletal muscle stem and progenitor cells --- HO precursors --- muscle atrophy --- septicemia --- mitochondrial fusion --- mitochondrial fission --- iPSC --- extracellular vesicles --- Drosophila --- muscle --- genetic control --- muscle diversification --- fascicle --- myofiber --- myofibril --- sarcomere --- hypertrophy --- hyperplasia --- splitting --- radial growth --- longitudinal growth --- exercise --- muscle stem cells --- stem cells niche --- neuromuscular disorders --- Duchenne muscular dystrophy --- pharmacological approach --- single-cell --- mass cytometry --- skeletal muscle regeneration --- skeletal muscle homeostasis --- fibro/adipogenic progenitors --- myogenic progenitors --- muscle populations --- evolution --- metazoans --- differentiation --- transdifferentiation --- muscle precursors --- regenerative medicine --- stem cells --- FAPs --- tissue niche --- growth factors --- muscle pathology
Choose an application
The book is a collection of original research and review articles addressing the intriguing field of the cellular and molecular players involved in muscle homeostasis and regeneration. One of the most ambitious aspirations of modern medical science is the possibility of regenerating any damaged part of the body, including skeletal muscle. This desire has prompted clinicians and researchers to search for innovative technologies aimed at replacing organs and tissues that are compromised. In this context, the papers, collected in this book, addressing a specific aspects of muscle homeostasis and regeneration under physiopathologic conditions, will help us to better understand the underlying mechanisms of muscle healing and will help to design more appropriate therapeutic approaches to improve muscle regeneration and to counteract muscle diseases.
lysine --- mTORC1 --- satellite cells --- proliferation --- skeletal muscle growth --- muscle satellite cell --- transthyretin --- thyroid hormone --- myogenesis --- exosomes --- skeletal muscle --- genotype --- genetic variation --- muscle phenotypes --- sarcopenia --- aging --- calcium homeostasis --- hibernation --- mitochondria --- sarcoplasmic reticulum --- Acvr1b --- Tgfbr1 --- myostatin --- Col1a1 --- fibrosis --- atrophy --- IGF2R --- muscle homeostasis --- inflammation --- muscular dystrophy --- pericytes --- macrophages --- Nfix --- phagocytosis --- RhoA-ROCK1 --- splicing isoforms --- CRISPR-Cas9 --- exon deletion --- NF-Y --- muscle differentiation --- C2C12 cells --- denervation --- neuromuscular junction --- heavy resistance exercise --- acetylcholine receptor --- cell culture --- neonatal myosin --- neural cell adhesion molecule --- biomarkers --- mitophagy --- mitochondrial dynamics --- mitochondrial quality control --- mitochondrial-derived vesicles (MDVs) --- mitochondrial-lysosomal axis --- Hibernation --- electron microscopy --- immunocytochemistry --- α-smooth muscle actin --- confocal microscopy --- connexin 43 --- connexin 26 --- gap junctions --- myofibroblasts --- Platelet-Rich Plasma --- transforming growth factor (TGF)-β1 --- muscle regeneration --- inflammatory response --- cell precursors --- experimental methods --- stem cell markers --- muscles --- heterotopic ossification --- skeletal muscle stem and progenitor cells --- HO precursors --- muscle atrophy --- septicemia --- mitochondrial fusion --- mitochondrial fission --- iPSC --- extracellular vesicles --- Drosophila --- muscle --- genetic control --- muscle diversification --- fascicle --- myofiber --- myofibril --- sarcomere --- hypertrophy --- hyperplasia --- splitting --- radial growth --- longitudinal growth --- exercise --- muscle stem cells --- stem cells niche --- neuromuscular disorders --- Duchenne muscular dystrophy --- pharmacological approach --- single-cell --- mass cytometry --- skeletal muscle regeneration --- skeletal muscle homeostasis --- fibro/adipogenic progenitors --- myogenic progenitors --- muscle populations --- evolution --- metazoans --- differentiation --- transdifferentiation --- muscle precursors --- regenerative medicine --- stem cells --- FAPs --- tissue niche --- growth factors --- muscle pathology
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