about
The impact of long-term exposure to space environment on adult mammalian organisms: a study on mouse thyroid and testisAcid sphingomyelinase as target of Lycium Chinense: promising new action for cell healthIbrutinib treatment of a patient with relapsing chronic lymphocytic leukemia and sustained remission of Richter syndrome.Radiation and Thyroid Cancer.Critical role for the protons in FRTL-5 thyroid cells: nuclear sphingomyelinase induced-damage.Loss of parafollicular cells during gravitational changes (microgravity, hypergravity) and the secret effect of pleiotrophinNuclear lipid microdomain as resting place of dexamethasone to impair cell proliferation.Gentamicin arrests cancer cell growth: the intriguing involvement of nuclear sphingomyelin metabolismA firmer understanding of the effect of hypergravity on thyroid tissue: cholesterol and thyrotropin receptorThe role of intranuclear lipids.Very-long-chain fatty acid sphingomyelin in nuclear lipid microdomains of hepatocytes and hepatoma cells: can the exchange from C24:0 to C16:0 affect signal proteins and vitamin D receptor?Why high cholesterol levels help hematological malignancies: role of nuclear lipid microdomains.Hypovitaminosis D3, Leukopenia, and Human Serotonin Transporter Polymorphism in Anorexia Nervosa and Bulimia NervosaNuclear lipid microdomain as place of interaction between sphingomyelin and DNA during liver regeneratione-Cadherin in 1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine-Induced Parkinson Disease.Lipid microdomains in cell nucleusIn Vitro Protective Effects of Lycium barbarum Berries Cultivated in Umbria (Italy) on Human Hepatocellular Carcinoma Cells.Serum deprivation alters lipid profile in HN9.10e embryonic hippocampal cells.Nuclear Lipids in the Nervous System: What they do in Health and Disease.Lysosomal alpha-mannosidase and alpha-mannosidosis.Impact of Gravity on Thyroid Cells.Severe hypocholesterolaemia is often neglected in haematological malignancies.Effect of 1alpha,25-dihydroxyvitamin D3 in embryonic hippocampal cells.The nuclear ceramide/diacylglycerol balance depends on the physiological state of thyroid cells and changes during UV-C radiation-induced apoptosis.Nuclear sphingomyelin pathway in serum deprivation-induced apoptosis of embryonic hippocampal cells.How microgravity changes galectin-3 in thyroid follicles.Reinterpretation of mouse thyroid changes under space conditions: the contribution of confinement to damage.Plasmalogens in rat liver chromatin: new molecules involved in cell proliferation.The thyroid lobes: the different twins.VDR independent induction of acid-sphingomyelinase by 1,23(OH)2 D3 in gastric cancer cells: Impact on apoptosis and cell morphology.Mouse Thyroid Gland Changes in Aging: Implication of Galectin-3 and Sphingomyelinase.Neutral Sphingomyelinase Behaviour in Hippocampus Neuroinflammation of MPTP-Induced Mouse Model of Parkinson's Disease and in Embryonic Hippocampal Cells.Origin of α-mannosidase activity in CSF.Cytogenetic/mutation profile of chronic lymphocytic leukemia/malignant melanoma collision tumors of the skin.Effect of Vitamin D in HN9.10e Embryonic Hippocampal Cells and in Hippocampus from MPTP-Induced Parkinson's Disease Mouse Model.Thyroid cell growth: sphingomyelin metabolism as non-invasive marker for cell damage acquired during spaceflight.Signal transducer and activator of transcription 3 and sphingomyelin metabolism in intranuclear complex during cell proliferation.Alpha-Mannosidosis: Therapeutic Strategies.The Many Facets of Sphingolipids in the Specific Phases of Acute Inflammatory Response.Sphingolipids in Inflammation.
P50
Q28730256-85C68E1E-ED49-487D-A194-19BBD44900A0Q28821632-0A3C9F31-6288-4653-ADD1-4338448AF5D2Q33443635-709C1A79-A69B-4B82-BFBC-0438CAD41C3EQ33754785-88664C96-89A8-439C-84A0-2697ECD54749Q34072231-6C3151AF-FE2D-4728-8581-369829597F16Q34531427-28E0EDD2-EF34-4BE6-99C6-F9EB0EFD7118Q34685101-62E81654-7BEC-49CC-B6B8-516D48279EE5Q35138856-4138C125-44F9-4FD0-A3AD-604CCE1DA059Q35174947-8EF3B286-BEAC-407A-A98A-4F8B06095257Q35935663-C81811EE-6179-41E4-BC11-4DC8E68DD9BDQ36063642-C7CAB733-FE10-4AA0-9C16-AAFB5F673E0CQ36454507-43452FC0-AB97-4D19-BAEB-1E1BFC9C5050Q36556352-43EDD30C-2FE0-4CC9-A946-AC235A510620Q36820344-B6B59A48-3E27-45F5-8E24-42A43309DCBCQ36856915-A9D17064-0384-484E-AE68-58D54C43B647Q36992851-8731A7DC-C8EA-4D24-8217-07D06E5590E2Q37443560-748713A0-E0E2-43B6-A36F-F63699082A37Q38923532-632A81CA-12AD-4778-80E3-AD93A4EC2BDBQ38986890-C0FE089F-8839-415C-89A9-856DD4DC9664Q38998879-608EFB01-CE92-4959-A584-E61CB04F8593Q39283124-BAD4C9C6-0B8B-4331-9C0A-2454FE963C5DQ39708664-3239B609-ACB3-4DE7-8492-137396AA96A5Q39825191-EE1E2860-9420-460F-ADEC-4C23DAC8B47AQ39953706-0832691E-F512-4AC1-8315-4C5C8FFB233CQ40397398-4716A989-F24C-4399-BCD7-C71AE2F66909Q41906428-06491519-4152-4AB2-9F79-3AC1DE0E29E8Q43718046-8BD5C7A1-636D-4F16-B23D-106118252798Q45076202-DF876C22-92DC-4912-90E4-6B0AF30C81A3Q46242897-5CE8BE13-DE28-403C-9E90-822236DCE893Q47382108-03D62263-2B8B-4D23-993E-066A4F1B18EFQ48155995-F84086A5-0829-47F5-BBEA-69D5F2E6DB1FQ48222862-0DD759C5-B995-4889-A3C7-192BEA63D159Q48237927-71374E0C-D8BA-416F-AA5E-003D62B5CBE5Q49180122-832A43AC-7B0A-4F4D-A819-D0846FAE66B8Q50296610-79781BD6-B9D1-40E5-84E0-D79F4F2E8D31Q53163887-81F383DF-87E7-4085-936F-BAD062F89628Q53553551-5F45EA71-4F7D-4460-9993-2B9C24E04D38Q55007551-9F343FC0-B642-4597-9888-7C4B6D8B50D4Q55091012-ED0A1304-FE9A-4BDE-8C49-834B35D77E5AQ55131161-42740949-01B8-477F-8156-C0DEE665FAF4
P50
description
Forscher
@de
chercheur
@fr
investigador
@es
researcher
@en
ricercatore
@it
wetenschapper
@nl
研究者
@zh
name
Elisabetta Albi
@ast
Elisabetta Albi
@en
Elisabetta Albi
@es
Elisabetta Albi
@nl
type
label
Elisabetta Albi
@ast
Elisabetta Albi
@en
Elisabetta Albi
@es
Elisabetta Albi
@nl
altLabel
Albi E
@en
prefLabel
Elisabetta Albi
@ast
Elisabetta Albi
@en
Elisabetta Albi
@es
Elisabetta Albi
@nl
P1053
K-3369-2016
P106
P1153
6602862474
P31
P4012
P496
0000-0002-5745-5343