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Learning to see (better): Improving visual deficits with perceptual learning

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Book Series: Frontiers Research Topics ISSN: 16648714 ISBN: 9782889196036 Year: Pages: 95 DOI: 10.3389/978-2-88919-603-6 Language: English
Publisher: Frontiers Media SA
Subject: Science (General) --- Psychology
Added to DOAB on : 2016-08-16 10:34:25
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Perceptual learning can be defined as a long lasting improvement in a perceptual skill following a systematic training, due to changes in brain plasticity at the level of sensory or perceptual areas. Its efficacy has been reported for a number of visual tasks, such as detection or discrimination of visual gratings (De Valois, 1977; Fiorentini & Berardi, 1980, 1981; Mayer, 1983), motion direction discrimination (Ball & Sekuler, 1982, 1987; Ball, Sekuler, & Machamer, 1983), orientation judgments (Fahle, 1997; Shiu & Pashler, 1992; Vogels & Orban, 1985), hyperacuity (Beard, Levi, & Reich, 1995; Bennett & Westheimer, 1991; Fahle, 1997; Fahle & Edelman, 1993; Kumar & Glaser, 1993; McKee & Westheimer, 1978; Saarinen & Levi, 1995), visual search tasks (Ahissar & Hochstein, 1996; Casco, Campana, & Gidiuli, 2001; Campana & Casco, 2003; Ellison & Walsh, 1998; Sireteanu & Rettenbach, 1995) or texture discrimination (Casco et al., 2004; Karni & Sagi, 1991, 1993). Perceptual learning is long-lasting and specific for basic stimulus features (orientation, retinal position, eye of presentation) suggesting a long-term modification at early stages of visual analysis, such as in the striate (Karni & Sagi, 1991; 1993; Saarinen & Levi, 1995; Pourtois et al., 2008) and extrastriate (Ahissar & Hochstein, 1996) visual cortex. Not confined to a basic research paradigm, perceptual learning has recently found application outside the laboratory environment, being used for clinical treatment of a series of visually impairing conditions such as amblyopia (Levi & Polat, 1996; Levi, 2005; Levi & Li, 2009, Polat et al., 2004; Zhou et al., 2006), myopia (Tan & Fong, 2008) or presbyopia (Polat, 2009). Different authors adopted different paradigms and stimuli in order to improve malfunctioning visual abilities, such as Vernier Acuity (Levi, Polat & Hu, 1997), Gratings detection (Zhou et al., 2006), oculomotor training (Rosengarth et al., 2013) and lateral interactions (Polat et al., 2004). The common result of these studies is that a specific training produces not only improvements in trained functions, but also in other, untrained and higher-level visual functions, such as visual acuity, contrast sensitivity and reading speed (Levi et al, 1997a, 1997b; Polat et al., 2004; Polat, 2009; Tan & Fong, 2008). More recently (Maniglia et al. 2011), perceptual learning with the lateral interactions paradigm has been successfully used for improving peripheral vision in normal people (by improving contrast sensitivity and reducing crowding, the interference in target discrimination due to the presence of close elements), offering fascinating new perspectives in the rehabilitation of people who suffer of central vision loss, such as maculopathy patients, partially overcoming the structural differences between fovea and periphery that limit the vision outside the fovea. One of the strongest point, and a distinguishing feature of perceptual learning, is that it does not just improve the subject’s performance, but produces changes in brain’s connectivity and efficiency, resulting in long-lasting, enduring neural changes. By tailoring the paradigms on each subject’s needs, perceptual learning could become the treatment of choice for the rehabilitation of visual functions, emerging as a simple procedure that doesn’t need expensive equipment.

Visual perception and visual cognition in healthy and pathological ageing

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Book Series: Frontiers Research Topics ISSN: 16648714 ISBN: 9782889192533 Year: Pages: 183 DOI: 10.3389/978-2-88919-253-3 Language: English
Publisher: Frontiers Media SA
Subject: Science (General) --- Psychology
Added to DOAB on : 2015-11-16 15:44:59
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Our understanding of visual perception and visual cognition has advanced considerably over the last decades. The effects of ageing on visual perception and visual cognition are less well understood. This Research Topic features state-of-the-art approaches to determining the effects of ageing on visual perception, visual attention, visual memory and visually guided behaviour. Studies using methods that incorporate psychophysics, eye movements, electrophysiology, structural and functional neuroimaging, as well as computational modelling are included. In addition to the focus on how ageing effects normal vision, the topic also includes studies on the effects of pathological ageing in the retina (e.g., age-related macular degeneration) and the brain (e.g., neurodegenerative disorders) on vision and visual cognition.

Nutrition and Eye Health

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ISBN: 9783039219902 9783039219919 Year: Pages: 242 DOI: 10.3390/books978-3-03921-991-9 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Biology --- Science (General)
Added to DOAB on : 2020-01-30 16:39:46
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Blindness and visual impairment impact significantly on an individual’s physical and mental well-being. Loss of vision is a global health problem, with approximately 250 million of the world’s population currently living with vision loss, of which 36 million are classified as blind. Visual impairment is more frequent in the elderly, with cataract and age-related macular degeneration (AMD) accounting for over 50% of cases globally. Oxidative stress has been strongly implicated in the pathogenesis of both conditions, and consequently the role of nutritional factors, in particular carotenoids and micronutrient antioxidants, have been investigated as possible preventative or therapeutic strategies. Dry eye syndrome (DES) is one of the most common ophthalmic conditions in the world. DES occurs where the eye does not produce enough tears and/or the tears evaporate too quicklyleading to discomfort and varying degrees of visual disturbance. There has recently been a great deal of interest in the potential for oral or topical supplementation with essential fatty acids (EFAs), specifically omega-3 and omega-6 fatty acids, as an adjunct to conventional treatments for DES. The objective of this Special Issue on ‘Nutrition and Eye Health’ is to publish papers describing the role of nutrition in maintaining eye health and the use of nutritional interventions to prevent or treat ocular disease. A particular (but not exclusive) emphasis will be on papers (reviews and/or clinical or experimental studies) relating to cataract, AMD and DES.

Keywords

lutein --- RR-zeaxanthin --- mesozeaxanthin (RS zeaxanthin) --- light damage --- photoreceptor degeneration --- oxidative stress --- endoplasmic reticulum stress --- electroretinography --- advanced glycation end products --- chyrsin --- diabetic retinopathy --- endoplasmic reticulum --- retinal pigment epithelium --- visual cycle --- cataract --- phytoconstituents --- lens --- preclinical models --- drug discovery --- age-related macular degeneration --- gut-retina axis --- gut microbiota --- dietary habits --- micronutrients --- fish oil --- omega-3 polyunsaturated fatty acids --- personalised medicine --- Lactobacillus paracasei KW3110 --- retina --- light --- macrophage --- saffron --- Crocus Sativus L. --- crocin --- crocetin --- supplements --- anti-oxidant --- anti-inflammatory --- AMD --- diabetes --- glaucoma --- retina --- oxidative stress --- inflammation --- microvascular lesions --- neoangiogenesis --- polyphenols --- flavonoids --- carotenoids --- saponins --- rosmarinic acid --- sinapic acid --- lenses --- estrogen-deficient rats --- oxidative stress --- reduced glutathione --- omega-3 --- fatty acid --- diet --- dietary assessment --- clinical survey --- eye disease --- dry eye --- age-related macular degeneration --- food frequency questionnaire --- CODS --- clinical practice guidelines --- systematic reviews --- age-related macular degeneration --- nutritional supplements --- diet --- nutrition --- AGREE II --- Cucurbita argyrosperma --- corneal chemical burn --- angiogenesis --- corneal neovascularization (CNV) --- vascular endothelial growth factor (VEGF) --- interleukin-1? (IL-1?) --- cyclooxigenase-2 (COX-2) --- nuclear factor-kappaB (NF-?B) --- dietary antioxidants --- antioxidant supplements --- lens --- cataract --- n/a

Mitochondrial Dysfunction in Aging and Diseases of Aging

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ISBN: 9783039213276 9783039213283 Year: Pages: 270 DOI: 10.3390/books978-3-03921-328-3 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology
Added to DOAB on : 2019-12-09 11:49:15
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This collection of review articles authored by international experts pulls together current information about the role of mitochondria in aging and diseases of aging. Mitochondria are vitally important cellular organelles and undergo their own aging process becoming less efficient in aged animals including humans. These changes have wide-ranging significance contributing to immune dysfunction (autoimmunity and immune deficiency), inflammation, delayed healing, skin and retinal damage, cancer and most of the degenerative diseases of aging. Mitochondrial aging predisposes to drug toxicity in the geriatric population and to many of the features of normal aging. The research detailed in this book summarizes current understanding of the role of mitochondria in the complex molecular changes of aging, moving on to specific diseases of aging. Mitochondrial dysfunction is an important target for development of treatments for aging and disease. The last article details how exercise is a treatment and combats many features of the aging process.

Keywords

aging --- mitochondria --- inflammation --- innate immunity --- adaptive immunity --- immunosenescence --- cell danger response --- healing cycle --- mitochondria --- purinergic signaling --- metabokines --- sphingolipids --- integrated cell stress response --- de-emergence --- crabtree effect --- pasteur effect --- coenzyme Q10 --- aging --- age-related diseases --- mitochondrial dysfunction --- mitochondria --- skin --- ageing --- reactive oxygen species --- photoageing --- 25(OH)D --- 1,25(OH)2D --- aging --- cytokines --- inflammation --- morbidity and mortality --- prevention --- reactive oxygen species --- ultraviolet --- aging --- mitochondria --- retina --- optic nerve --- diabetic retinopathy --- age-related macular degeneration --- glaucoma --- drug-induced mitochondrial toxicity --- polypharmacy --- aging --- mitochondrial dysfunction --- insulin resistance --- type 2 diabetes --- mitochondrial transfer --- exosomes --- mitochondrial --- genetic mutations --- cardiovascular disease --- heart failure --- cardiomyopathy --- mitochondria --- cancer --- nucleotide metabolism --- DNA damage --- NAD+ --- mitochondria --- ALS --- axonal transport --- mitophagy --- SOD1 --- Miro1 --- PINK1 --- Parkin --- multiple sclerosis --- mitochondria --- neuroinflammation --- neurodegeneration --- Parkinson’s disease --- mitochondria --- ageing --- neurodegenerative disease --- Alzheimer’s disease --- eIF2? --- metabolism --- mitochondria --- proteostasis --- stress response --- aging --- exercise --- mitochondria --- aerobic --- ROS --- inflammation --- senescence --- lysosome --- autophagy --- mitophagy --- n/a

Seaweeds Secondary Metabolites: Successes in and/or Probable Therapeutic Applications

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ISBN: 9783039283002 9783039283019 Year: Pages: 320 DOI: 10.3390/books978-3-03928-301-9 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology --- Nutrition and Food Sciences
Added to DOAB on : 2020-04-07 23:07:08
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Seaweeds are recognized as highly nutritious, and their use in gastronomy is increasing. Their health benefits and their potential to prevent several diseases have also been established. In this Special Issue several health effects are discussed, with more emphasis on their antitumor activity and potential use to treat Alzheimer’s disease. The key bioactive metabolites, from which phlorotannins can be highlighted, are presented, as well as some important in vivo studies. Altogether, the chapters provide in-depth information about the biological activities of seaweed metabolites, contributing to elucidate the health effects of seaweed.

Keywords

Padina pavonica --- osteosarcoma --- apoptosis --- algae --- chemo-preventive agent --- phytol --- fucosterol --- fatty acid --- laurinterol --- Laurencia --- antitumoral --- breast cancer explants --- organotypic culture --- ex vivo --- phlorotannin --- eckmaxol --- high-speed counter-current chromatography --- NMR spectroscopy --- mass spectrometry --- isolation and purification --- Ecklonia maxima --- fucoidan --- age-related macular degeneration --- VEGF --- oxidative stress --- Saccharina latissima --- Fucus vesiculosus --- Fucus distichus subsp. evanescens --- Fucus serratus --- Laminaria digitata --- Symphyocladia latiuscula --- bromophenols --- mushroom tyrosinase --- B16F10 --- melanin --- red seaweed --- bioactives --- extraction --- biorefinery --- seaweed --- gut microbiota --- prebiotics --- dietary fibre --- complex polysaccharides --- polyphenols --- polyunsaturated fatty acids --- carotenoids --- phytochemicals --- Padina pavonica --- marine algae --- osteoporosis --- bone metabolism --- bone health --- nutraceutical --- Bifurcaria bifurcata --- linear diterpenes --- extraction --- identification --- biological activities --- macroalgae --- high value applications --- phlorotannin --- amyloid-? aggregation --- insulin glycation --- dynamic simulation --- kidney --- ischemia-reperfusion injury --- Ecklonia cava --- phlorotannins --- Alzheimer’s disease --- seaweeds --- cholinesterases --- beta-secretase --- beta-amyloid aggregation --- neuroprotection --- K14HPV16 --- genotoxicity assay --- papillomavirus --- cancer --- seaweeds --- hyperpigmentation --- skin aging --- skincare --- photo-protection --- seaweeds --- secondary metabolites --- in vivo studies --- clinical trials --- health effects --- dieckol --- eckol --- fucoxanthin --- kahalalide F

Metabolomics in Neurodegenerative Disease

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ISBN: 9783039280407 / 9783039280414 Year: Pages: 184 DOI: 10.3390/books978-3-03928-041-4 Language: eng
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology
Added to DOAB on : 2020-06-09 16:38:57
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The range of human neurodegenerative diseases continues to pose significant unmet medical needs for societies around the world. The progressive and terminal nature of these conditions places a considerable personal burden on the individual affected but also on public health systems and health services. Tens of millions of people are indiscriminately affected by various dementias, which are rising at an alarming rate. There are no cures for many conditions, and it is clear that treatments applied as early as possible could greatly improve outcomes for patients. Therefore, new disease classification and diagnostic tools should be a key priority. Metabolomics represents a relatively new field of analytical science, which can be extremely useful in the early diagnosis of disease. The relatively unique feature of metabolites is that they sit at the intersection between the genetic background of an organism and its environment. Because many neurodegenerative diseases are not genetically inherited (instead having a range of known genetic risk factors and also a large number of unknown environmental triggers) the field of metabolomics offers great promise for the discovery of new, biologically, and clinically relevant biomarkers for neurodegenerative disorders. It is already bringing forward new knowledge in terms of the mechanisms of neurodegenerative disease.

Iron as Therapeutic Targets in Human Diseases Volume 1

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ISBN: 9783039280827 9783039280834 Year: Pages: 472 DOI: 10.3390/books978-3-03928-083-4 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology --- Biochemistry
Added to DOAB on : 2020-04-07 23:07:08
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Iron is an essential element for almost all organisms, a cofactor playing a crucial role in a number of vital functions, including oxygen transport, DNA synthesis, and respiration. However, its ability to exchange electrons renders excess iron potentially toxic, since it is capable of catalyzing the formation of highly poisonous free radicals. As a consequence, iron homeostasis is tightly controlled by sophisticated mechanisms that have been partially elucidated. Because of its biological importance, numerous disorders have been recently linked to the deregulation of iron homeostasis, which include not only the typical disorders of iron overload and deficiency but also cancer and neurodegenerative diseases. This leads iron metabolism to become an interesting therapeutic target for novel pharmacological treatments against these diseases. Several therapies are currently under development for hematological disorders, while other are being considered for different pathologies. The therapeutic targeting under study includes the hepcidin/ferroportin axis for the regulation of systemic iron homeostasis, complex cytosolic machineries for the regulation of the intracellular iron status and its association with oxidative damage, and reagents exploiting proteins of iron metabolism such as ferritin and transferrin receptor. A promising potential target is a recently described form of programmed cell death named ferroptosis, in which the role of iron is essential but not completely clarified. This Special Issue has the aim to summarize the state-of-the-art, and the latest findings published in the iron field, as well as to elucidate future directions.

Keywords

cinnamic acid derivatives --- soybean seed ferritin --- iron release --- binding ability --- Fe2+-chelating activity --- reducibility --- adverse event profile --- anaemia --- bioengineering --- labile iron --- intravenous iron --- iron-carbohydrate complex --- iron processing --- iron metabolism --- infection --- innate immunity --- hepcidin --- ferritin --- anemia of inflammation --- pharmaceutical targets --- iron deficiency anemia --- nutrient iron --- oral iron therapy --- FeSO4 --- NaFeEDTA --- non-transferrin-bound iron (NTBI) --- developing countries --- Indonesia --- neurodegeneration --- mitochondria --- therapy --- heme --- haem --- Iron-sulfur --- Friedreich Ataxia --- Oxidative stress --- Iron chelators --- iron deficiency --- anemia --- cancer --- hepcidin --- patient blood management --- malaria --- iron deficiency --- hepcidin --- TNF --- children --- Africa --- Anemia --- iron deficiency --- oral iron salts --- intravenous iron --- Sucrosomial® iron --- M cells --- bioavailability --- tolerability --- efficacy --- iron --- gut microbiota --- iron supplementation --- iron transporters --- mucosal immunity --- SCFA --- intestinal inflammation --- inflammatory bowel disease (IBD) --- colorectal cancer --- oxidative stress --- anaemia --- cardiovascular disease --- chronic kidney disease --- IV iron therapy --- bone homeostasis --- iron overload --- iron deficiency --- osteoclast --- osteoblast --- osteoporosis --- neurodegeneration with brain iron accumulation --- iron chelation therapy --- multifunctional iron chelators --- fluorescent iron chelator --- 3-hydroxy-4-pyridinone --- fluorophore --- rhodamine --- membrane interactions --- bacteria --- antibacterial activity --- histidine --- iron --- anemia --- oxidative stress --- kidney --- chelation --- iron --- retina --- age-related macular degeneration (AMD) --- iron --- lipid --- obesity --- cancer --- neurodegeneration --- iron chelation --- phlebotomy --- NCOA4 --- ferritinophagy --- iron homeostasis --- erythropoiesis --- ferroptosis --- cancer --- Tfr2 --- iron metabolism --- hepcidin --- erythropoiesis --- SNC --- ferritin --- iron mobilization --- chaotropes --- flavin nucleotide --- electron transfer --- kinetics --- ferritin --- iron --- iron delivery --- nanotechnology --- nanocage --- drug delivery --- inflammation --- serum biomarker --- iron metabolism --- hepcidin --- ferroportin --- hemochromatosis --- anemia --- hepcidin --- iron deficiency anemia --- iron dextran --- neonatal period --- pig --- supplementation --- Alzheimer’s disease --- neuroinflammation --- neurodegeneration --- cytokines --- neuroimmune responses --- iron --- genetic hemochromatosis --- non transferrin bound iron --- hepcidin --- ferroportin --- venesections --- Anemia of chronic disease --- anemia of inflammation --- hepcidin --- anti-hepcidin therapy --- iron supplementation --- macrophage --- central nurse macrophage --- red pulp macrophage --- Kupffer cell --- iron metabolism --- erythropoiesis --- erythroblastic islands --- erythrophagocytosis --- inflammation --- iron homeostasis --- lung diseases --- oxygen sensing --- hypoxia --- ferritin --- hereditary hyperferritinemia --- hereditary hypoferritinemia --- iron metabolism --- cataracts syndrome --- neurodegenerative disease --- n/a --- iron --- neurodegeneration --- NBIA --- hepcidin --- iron --- lung --- acute lung injury --- COPD --- lung infection --- cystic fibrosis --- iron --- anaemia --- infection --- malaria --- immunity --- brain development --- growth --- microbiome --- hepcidin --- ferritin --- iron supplementation --- infants --- children --- low and middle income countries --- liver --- iron --- hepcidin --- Mek/Erk --- Hfe --- Bmp/Smad --- iron --- mycobacteria --- immunity --- Alzheimer’s disease --- iron homeostasis --- ferroptosis --- senescence --- chelators --- macrophages --- iron --- metabolism --- inflammation --- iron --- ferritin --- acute kidney injury --- chronic kidney disease --- vascular calcification --- iron --- hepcidin --- ferroportin --- Interleukin-6 --- infection --- rheumatoid arthritis --- iron homeostasis --- iron absorption --- non-haem iron --- flavonoids --- developmental --- iron deficiency anemia --- neonatal --- transferrin receptor --- treatment --- hemochromatosis --- HFE --- natural history --- T lymphocytes --- MHC --- CD8+ T cells --- prevention --- iron homeostasis --- hepcidin --- protein binding --- peritoneal dialysis --- iron --- hepcidin --- iron regulatory proteins --- cardiomyocyte --- chronic heart failure --- pulmonary arterial smooth muscle cells --- pulmonary arterial hypertension --- iron --- brain --- neurophysiology --- cognition --- social behavior --- didox --- iron chelators --- antitumor compound --- iron metabolism --- RRM2 --- SLC40A1 --- ferroportin --- iron overload --- non-HFE --- ferritin --- hemochromatosis --- iron --- chelation --- neurodegenerative diseases --- pituitary --- brain --- hemopexin --- heme homeostasis --- iron homeostasis --- hemolysis --- haptoglobin --- ferroptosis --- inflammation --- biomarker --- heme oxygenase --- liver --- microbiome --- trauma --- hemorrhage --- iron metabolism --- hepcidin --- iron homeostasis --- ferroportin --- n/a

Iron as Therapeutic Targets in Human Diseases Volume 2

Authors: --- ---
ISBN: 9783039281145 9783039281152 Year: Pages: 440 DOI: 10.3390/books978-3-03928-115-2 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology --- Biochemistry
Added to DOAB on : 2020-04-07 23:07:08
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Abstract

Iron is an essential element for almost all organisms, a cofactor playing a crucial role in a number of vital functions, including oxygen transport, DNA synthesis, and respiration. However, its ability to exchange electrons renders excess iron potentially toxic, since it is capable of catalyzing the formation of highly poisonous free radicals. As a consequence, iron homeostasis is tightly controlled by sophisticated mechanisms that have been partially elucidated. Because of its biological importance, numerous disorders have been recently linked to the deregulation of iron homeostasis, which include not only the typical disorders of iron overload and deficiency but also cancer and neurodegenerative diseases. This leads iron metabolism to become an interesting therapeutic target for novel pharmacological treatments against these diseases. Several therapies are currently under development for hematological disorders, while other are being considered for different pathologies. The therapeutic targeting under study includes the hepcidin/ferroportin axis for the regulation of systemic iron homeostasis, complex cytosolic machineries for the regulation of the intracellular iron status and its association with oxidative damage, and reagents exploiting proteins of iron metabolism such as ferritin and transferrin receptor. A promising potential target is a recently described form of programmed cell death named ferroptosis, in which the role of iron is essential but not completely clarified. This Special Issue has the aim to summarize the state-of-the-art, and the latest findings published in the iron field, as well as to elucidate future directions.

Keywords

cinnamic acid derivatives --- soybean seed ferritin --- iron release --- binding ability --- Fe2+-chelating activity --- reducibility --- adverse event profile --- anaemia --- bioengineering --- labile iron --- intravenous iron --- iron-carbohydrate complex --- iron processing --- iron metabolism --- infection --- innate immunity --- hepcidin --- ferritin --- anemia of inflammation --- pharmaceutical targets --- iron deficiency anemia --- nutrient iron --- oral iron therapy --- FeSO4 --- NaFeEDTA --- non-transferrin-bound iron (NTBI) --- developing countries --- Indonesia --- neurodegeneration --- mitochondria --- therapy --- heme --- haem --- Iron-sulfur --- Friedreich Ataxia --- Oxidative stress --- Iron chelators --- iron deficiency --- anemia --- cancer --- hepcidin --- patient blood management --- malaria --- iron deficiency --- hepcidin --- TNF --- children --- Africa --- Anemia --- iron deficiency --- oral iron salts --- intravenous iron --- Sucrosomial® iron --- M cells --- bioavailability --- tolerability --- efficacy --- iron --- gut microbiota --- iron supplementation --- iron transporters --- mucosal immunity --- SCFA --- intestinal inflammation --- inflammatory bowel disease (IBD) --- colorectal cancer --- oxidative stress --- anaemia --- cardiovascular disease --- chronic kidney disease --- IV iron therapy --- bone homeostasis --- iron overload --- iron deficiency --- osteoclast --- osteoblast --- osteoporosis --- neurodegeneration with brain iron accumulation --- iron chelation therapy --- multifunctional iron chelators --- fluorescent iron chelator --- 3-hydroxy-4-pyridinone --- fluorophore --- rhodamine --- membrane interactions --- bacteria --- antibacterial activity --- histidine --- iron --- anemia --- oxidative stress --- kidney --- chelation --- iron --- retina --- age-related macular degeneration (AMD) --- iron --- lipid --- obesity --- cancer --- neurodegeneration --- iron chelation --- phlebotomy --- NCOA4 --- ferritinophagy --- iron homeostasis --- erythropoiesis --- ferroptosis --- cancer --- Tfr2 --- iron metabolism --- hepcidin --- erythropoiesis --- SNC --- ferritin --- iron mobilization --- chaotropes --- flavin nucleotide --- electron transfer --- kinetics --- ferritin --- iron --- iron delivery --- nanotechnology --- nanocage --- drug delivery --- inflammation --- serum biomarker --- iron metabolism --- hepcidin --- ferroportin --- hemochromatosis --- anemia --- hepcidin --- iron deficiency anemia --- iron dextran --- neonatal period --- pig --- supplementation --- Alzheimer’s disease --- neuroinflammation --- neurodegeneration --- cytokines --- neuroimmune responses --- iron --- genetic hemochromatosis --- non transferrin bound iron --- hepcidin --- ferroportin --- venesections --- Anemia of chronic disease --- anemia of inflammation --- hepcidin --- anti-hepcidin therapy --- iron supplementation --- macrophage --- central nurse macrophage --- red pulp macrophage --- Kupffer cell --- iron metabolism --- erythropoiesis --- erythroblastic islands --- erythrophagocytosis --- inflammation --- iron homeostasis --- lung diseases --- oxygen sensing --- hypoxia --- ferritin --- hereditary hyperferritinemia --- hereditary hypoferritinemia --- iron metabolism --- cataracts syndrome --- neurodegenerative disease --- n/a --- iron --- neurodegeneration --- NBIA --- hepcidin --- iron --- lung --- acute lung injury --- COPD --- lung infection --- cystic fibrosis --- iron --- anaemia --- infection --- malaria --- immunity --- brain development --- growth --- microbiome --- hepcidin --- ferritin --- iron supplementation --- infants --- children --- low and middle income countries --- liver --- iron --- hepcidin --- Mek/Erk --- Hfe --- Bmp/Smad --- iron --- mycobacteria --- immunity --- Alzheimer’s disease --- iron homeostasis --- ferroptosis --- senescence --- chelators --- macrophages --- iron --- metabolism --- inflammation --- iron --- ferritin --- acute kidney injury --- chronic kidney disease --- vascular calcification --- iron --- hepcidin --- ferroportin --- Interleukin-6 --- infection --- rheumatoid arthritis --- iron homeostasis --- iron absorption --- non-haem iron --- flavonoids --- developmental --- iron deficiency anemia --- neonatal --- transferrin receptor --- treatment --- hemochromatosis --- HFE --- natural history --- T lymphocytes --- MHC --- CD8+ T cells --- prevention --- iron homeostasis --- hepcidin --- protein binding --- peritoneal dialysis --- iron --- hepcidin --- iron regulatory proteins --- cardiomyocyte --- chronic heart failure --- pulmonary arterial smooth muscle cells --- pulmonary arterial hypertension --- iron --- brain --- neurophysiology --- cognition --- social behavior --- didox --- iron chelators --- antitumor compound --- iron metabolism --- RRM2 --- SLC40A1 --- ferroportin --- iron overload --- non-HFE --- ferritin --- hemochromatosis --- iron --- chelation --- neurodegenerative diseases --- pituitary --- brain --- hemopexin --- heme homeostasis --- iron homeostasis --- hemolysis --- haptoglobin --- ferroptosis --- inflammation --- biomarker --- heme oxygenase --- liver --- microbiome --- trauma --- hemorrhage --- iron metabolism --- hepcidin --- iron homeostasis --- ferroportin --- n/a

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