about
Early feeding of fortified breast milk and in-hospital-growth in very premature infants: a retrospective cohort analysis.The Effects of Lung Protective Ventilation or Hypercapnic Acidosis on Gas Exchange and Lung Injury in Surfactant Deficient Rabbits.Effect of Increased Enteral Protein Intake on Growth in Human Milk-Fed Preterm Infants: A Randomized Clinical Trial.Choline and polyunsaturated fatty acids in preterm infants' maternal milk.Transport of long-chain polyunsaturated fatty acids in preterm infant plasma is dominated by phosphatidylcholine.Lung surfactant: Function and composition in the context of development and respiratory physiology.5-Methyltetrahydrofolate and thiamine diphosphate in cord-blood erythrocytes of preterm versus term newborns.Choline supply of preterm infants: assessment of dietary intake and pathophysiological considerations.Shigella flexneri transformants expressing type 1 (mannose-specific) fimbriae bind to, activate, and are killed by phagocytic cells.Developmental changes in polyunsaturated fetal plasma phospholipids and feto-maternal plasma phospholipid ratios and their association with bronchopulmonary dysplasia.Myristate is selectively incorporated into surfactant and decreases dipalmitoylphosphatidylcholine without functional impairment.Lung surfactant in a cystic fibrosis animal model: increased alveolar phospholipid pool size without altered composition and surface tension function in cftrm1HGU/m1HGU mice.Oxidative stress markers and micronutrients in maternal and cord blood in relation to neonatal outcome.Phosphatidylcholine metabolism of rat trachea in relation to lung parenchyma and surfactant.The anatomy, physics, and physiology of gas exchange surfaces: is there a universal function for pulmonary surfactant in animal respiratory structures?Surfactant metabolism and anti-oxidative capacity in hyperoxic neonatal rat lungs: effects of keratinocyte growth factor on gene expression in vivo.No evidence from controlled trials to support the hypothesis that slow feeding advancement in preterm infants reduces the risk of necrotizing enterocolitis. Reply to the letter to the editor by S. Meyer and M. Butte: feeding regimens and necrotisingPhosphatidylcholine kinetics in neonatal rat lungs and the effects of rhuKGF and betamethasone.Dipalmitoylphosphatidylcholine is not the major surfactant phospholipid species in all mammals.Plasma phosphatidylcholine alterations in cystic fibrosis patients: impaired metabolism and correlation with lung function and inflammation.Plasma phospholipids indicate impaired fatty acid homeostasis in preterm infants.Retrospective cohort analysis on pancreatic enzyme substitution in very low birthweight infants with postnatal growth failure.Choline concentrations are lower in postnatal plasma of preterm infants than in cord plasma.rhKGF stimulates lung surfactant production in neonatal rats in vivo.Surfactant in newborn compared with adolescent pigs: adaptation to neonatal respiration.Residual cftr expression varies with age in cftr(tm1Hgu) cystic fibrosis mice: impact on morphology and physiology.Developmental changes in rat surfactant lipidomics in the context of species variability.Distribution of intracellular and secreted surfactant during postnatal rat lung development.Effect of increased enteral protein intake on plasma and urinary urea concentrations in preterm infants born at < 32 weeks gestation and < 1500 g birth weight enrolled in a randomized controlled trial - a secondary analysis.Increased palmitoyl-myristoyl-phosphatidylcholine in neonatal rat surfactant is lung specific and correlates with oral myristic acid supplyCholine and choline-related nutrients in regular and preterm infant growthEffects on Fatty Acid Metabolism of a New Powdered Human Milk Fortifier Containing Medium-Chain Triacylglycerols and Docosahexaenoic Acid in Preterm InfantsCholine Supplementation in Cystic Fibrosis-The Metabolic and Clinical ImpactLectinophagocytosis of type 1 fimbriated (mannose-specific) Escherichia coli in the mouse peritoneumImpaired regulation of surfactant phospholipid metabolism in the isolated rat lung after nitrogen dioxide inhalationRat gastric hydrophobic barrier: modulation of phosphatidylcholine molecular species by dietary lipidsSynthesis and release of phosphatidylcholine by isolated porcine gastric mucous cells in primary cultureA method for the isolation and preparation of surfactant from tracheobronchial aspirates in infants and children for quantitative and pulsating bubble analysisComposition of phospholipid classes and phosphatidylcholine molecular species of gastric mucosa and mucusPhospholipid synthesis in isolated porcine gastric mucous cells
P50
Q35030193-3E2568CD-8190-4D4E-8C58-93CF81E8EC08Q35913407-94A413D0-D25E-432C-89EA-DFA35D502974Q38384182-ABA59C8F-2F58-4403-B8A0-BE8334E1C133Q38392731-9B29CB2E-18B2-4947-8808-3251E5DB89F1Q38668215-F63B0E0E-1AB3-417A-BA43-5D729B43F5BAQ38969865-AE84AB69-700B-4C32-B689-B2470559F76AQ39356286-9C0C8E7E-7839-4D17-8357-55E2CF4D90C6Q39555876-0A990D67-55F3-4E57-A004-47025AB21241Q40266799-C37508A7-94CC-48EE-982C-4285EF08D4F1Q40546104-C5EE576E-67E3-4658-BBE9-580B5942FEECQ42920102-29D50EA0-2F74-415E-ABB8-452801CC491DQ43043598-B324E6A3-F4A8-42AB-8AEE-15B17D345BABQ43527467-00CCF4F1-9685-4566-B0B1-A8A5F708BCA6Q44543774-74443D0D-DA98-4C41-BA00-D54B752BC6C2Q44820108-DA611940-F6DE-4C45-8081-7FA629CA5E49Q44880447-34DA81D9-2AC0-40F3-992E-D5D223F53D33Q45839378-84D7A031-A6D2-40C9-975E-597726738F68Q46585024-1FB42E75-0C58-472C-A477-B8525F34D21EQ46612946-0E8B5E0F-D745-4AA8-BADC-761D9A5EBED9Q46756552-30A66100-1E42-45E4-AAE0-D29740304331Q46941235-D8B9DD7A-23B2-41E8-A9FC-E775E972644BQ47184335-9A5195E4-517B-483B-8F99-C8754EA3698FQ48590274-2E582167-DD82-4A69-8552-54A18A783053Q51481652-A944BB89-47CA-4044-8431-F6580BE415A7Q51647084-3381EB8D-E47B-4E39-BC93-22CCBB8674A2Q51694563-AA29A306-42E5-482C-BCBC-BCD0D594DC45Q51979868-40332CA0-13A1-49AB-BEEC-A5BD8DCD115DQ51987500-5EBBA17A-DE2A-441A-B5CB-B629ADCBFE3FQ55070370-DA0C0542-4ACF-4129-A190-0A73D34771BEQ56638879-96B3CF2A-4518-447E-9E3B-3CEE51F41FDBQ57294260-D44053CA-1536-4AD1-8888-5DCED280610DQ61805166-5030C4E4-4C49-4E77-B8FF-53F221ED6CA8Q64081780-3404D5DF-D4B5-4BF1-B735-7788011A6975Q64450548-3C040F83-D29E-43F6-A5B8-A74B524E11B6Q70762274-E2634226-E60A-4641-A706-7DBA5D4EB2CBQ71314823-D477A50E-0755-4502-BC7C-836967097CCEQ71721867-345E37A8-1982-45E4-8DCC-BF615FE9C278Q71865579-7C5BF204-D938-4CFA-8FFD-77DC169AFF87Q72109704-6A30CAAC-4CA8-4486-A834-73832E07FEBAQ72352604-1CBC73E2-88E6-4F67-BB8F-BBB4F44B4BFB
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
W Bernhard
@ast
W Bernhard
@en
W Bernhard
@es
W Bernhard
@nl
type
label
W Bernhard
@ast
W Bernhard
@en
W Bernhard
@es
W Bernhard
@nl
prefLabel
W Bernhard
@ast
W Bernhard
@en
W Bernhard
@es
W Bernhard
@nl
P108
P214
P106
P214
P31
P496
0000-0003-0307-223X
P734
P7859
viaf-30428822