scholarly article | Q13442814 |
P819 | ADS bibcode | 2007PNAS..10417058R |
P356 | DOI | 10.1073/PNAS.0707958104 |
P932 | PMC publication ID | 2040473 |
P698 | PubMed publication ID | 17940022 |
P5875 | ResearchGate publication ID | 5905546 |
P2093 | author name string | Jian Zhang | |
Jonathan S Stamler | |||
Michael Angelo | |||
James D Reynolds | |||
Gregory S Ahearn | |||
Fred Cobb | |||
P2860 | cites work | Red blood cells express a functional endothelial nitric oxide synthase | Q22299208 |
Essential roles of S-nitrosothiols in vascular homeostasis and endotoxic shock | Q28246441 | ||
Exercising skeletal muscle blood flow in humans responds to reduction in arterial oxyhaemoglobin, but not to altered free oxygen | Q28351698 | ||
Hemoglobin conformation couples erythrocyte S-nitrosothiol content to O2 gradients | Q30436525 | ||
Red blood cell regulation of microvascular tone through adenosine triphosphate. | Q54056545 | ||
Blood Flow Regulation by S-Nitrosohemoglobin in the Physiological Oxygen Gradient | Q58641869 | ||
S-nitrosohaemoglobin: a dynamic activity of blood involved in vascular control | Q59054161 | ||
Enhancement of S-Nitrosylation in Glycosylated Hemoglobin | Q59395571 | ||
Do Transfusions Get to the Heart of the Matter? | Q59465668 | ||
Nitrite-dependent vasodilation is facilitated by hypoxia and is independent of known NO-generating nitrite reductase activities | Q63413250 | ||
Effects of oxygen on red cells during liquid storage at +4 degrees C | Q70300939 | ||
Failure of red blood cell transfusion to increase oxygen transport or mixed venous PO2 in injured patients | Q70457005 | ||
Effect of stored-blood transfusion on oxygen delivery in patients with sepsis | Q70736891 | ||
The basis of defective oxygen delivery from stored blood | Q71540550 | ||
Relationship of post-transfusion viability to deformability of stored red cells | Q71651189 | ||
Restoration in vivo of erythrocyte adenosine triphosphate, 2,3-diphosphoglycerate, potassium ion, and sodium ion concentrations following the transfusion of acid-citrate-dextrose-stored human red blood cells | Q72374450 | ||
Defective gas-transport function of stored red blood-cells | Q73364582 | ||
Functional coupling of oxygen binding and vasoactivity in S-nitrosohemoglobin | Q73626318 | ||
S-nitrosohemoglobin in the fetal circulation may represent a cycle for blood pressure regulation | Q73876807 | ||
Concerted nitric oxide/oxygen delivery by hemoglobin | Q77907989 | ||
Arterial O2 content and tension in regulation of cardiac output and leg blood flow during exercise in humans | Q78020279 | ||
WBC reduction reduces storage-associated RBC adhesion to human vascular endothelial cells under conditions of continuous flow in vitro | Q78859732 | ||
Tissue hypoxia during bacterial sepsis is attenuated by PR-39, an antibacterial peptide | Q79174032 | ||
Blood transfusion--when is more really less? | Q80178310 | ||
Extrapulmonary effects of inhaled nitric oxide: role of reversible S-nitrosylation of erythrocytic hemoglobin | Q30440013 | ||
Export by red blood cells of nitric oxide bioactivity | Q32050891 | ||
Oxygen regulation of tumor perfusion by S-nitrosohemoglobin reveals a pressor activity of nitric oxide. | Q33214780 | ||
Blood bank conditions and RBCs: the progressive loss of metabolic modulation | Q33444127 | ||
Impaired vasodilation by red blood cells in sickle cell disease | Q33850500 | ||
Evolution of adverse changes in stored RBCs | Q34007600 | ||
A nitric oxide processing defect of red blood cells created by hypoxia: deficiency of S-nitrosohemoglobin in pulmonary hypertension | Q34078525 | ||
Routes to S-nitroso-hemoglobin formation with heme redox and preferential reactivity in the beta subunits | Q34469860 | ||
An S-nitrosothiol (SNO) synthase function of hemoglobin that utilizes nitrite as a substrate | Q34694150 | ||
Effect of hyperbaric oxygen on oxygen uptake and measurements in the blood and tissues in a normobaric environment | Q35327157 | ||
Red blood cell-derived ATP as a regulator of skeletal muscle perfusion | Q35621214 | ||
Effects of storage on efficacy of red cell transfusion: when is it not safe? | Q35629485 | ||
Assessment of nitric oxide signals by triiodide chemiluminescence | Q35844711 | ||
Risks of transfusion: outcome focus | Q35976507 | ||
Chemical physiology of blood flow regulation by red blood cells: the role of nitric oxide and S-nitrosohemoglobin | Q36040992 | ||
Assessments of the chemistry and vasodilatory activity of nitrite with hemoglobin under physiologically relevant conditions | Q36089728 | ||
Transfusion practice in massively bleeding patients: time for a change? | Q36230698 | ||
How do red blood cells cause hypoxic vasodilation? The SNO-hemoglobin paradigm | Q36496546 | ||
Clinical consequences of red cell storage in the critically ill. | Q36640505 | ||
S-nitrosylation of proteins with nitric oxide: synthesis and characterization of biologically active compounds | Q36780079 | ||
Transport and peripheral bioactivities of nitrogen oxides carried by red blood cell hemoglobin: role in oxygen delivery. | Q36786247 | ||
Nitric oxide in the human respiratory cycle. | Q38522683 | ||
Blood collection and transfusion in the United States in 1999. | Q40452830 | ||
Hemoglobin function in stored blood | Q40473082 | ||
Role of oxygen in arteriolar functional vasodilation in hamster striated muscle | Q41044596 | ||
Influence of hematocrit on cardiopulmonary function after acute hemorrhage | Q41454655 | ||
Microvascular perfusion upon exchange transfusion with stored red blood cells in normovolemic anemic conditions. | Q44221751 | ||
Anemia and blood transfusion in critically ill patients. | Q44266321 | ||
Rates of release of nitric oxide from HbSNO and internal electron transfer | Q44404668 | ||
Blood transfusion, independent of shock severity, is associated with worse outcome in trauma | Q44460486 | ||
Transduction of NO-bioactivity by the red blood cell in sepsis: novel mechanisms of vasodilation during acute inflammatory disease | Q44568254 | ||
Vasorelaxation by red blood cells and impairment in diabetes: reduced nitric oxide and oxygen delivery by glycated hemoglobin | Q44764243 | ||
Relationship of blood transfusion and clinical outcomes in patients with acute coronary syndromes | Q45092053 | ||
Biochemical parameters to assess viability of erythrocytes stored for transfusional use. | Q46078374 | ||
Mechanistic studies of S-nitrosothiol formation by NO*/O2 and by NO*/methemoglobin | Q46409853 | ||
Erythrocytes and the regulation of human skeletal muscle blood flow and oxygen delivery: role of erythrocyte count and oxygenation state of haemoglobin | Q46913555 | ||
Changes in physical properties of stored erythrocytes relationship to survival in vivo | Q47788673 | ||
Release of nitric oxide from S-nitrosohemoglobin. Electron transfer as a response to deoxygenation. | Q49324279 | ||
Red blood cells prevent inhibition of hypoxic pulmonary vasoconstriction by nitrite in isolated, perfused rat lungs. | Q50719639 | ||
S-nitrosohemoglobin: a mechanism for its formation in conjunction with nitrite reduction by deoxyhemoglobin. | Q50739637 | ||
P433 | issue | 43 | |
P407 | language of work or name | English | Q1860 |
P304 | page(s) | 17058-17062 | |
P577 | publication date | 2007-10-11 | |
P1433 | published in | Proceedings of the National Academy of Sciences of the United States of America | Q1146531 |
P1476 | title | S-nitrosohemoglobin deficiency: a mechanism for loss of physiological activity in banked blood | |
P478 | volume | 104 |
Q41224311 | A novel mouse model of red blood cell storage and posttransfusion in vivo survival. |
Q39649011 | Acid Sphingomyelinase Inhibition Prevents Hemolysis During Erythrocyte Storage |
Q33393342 | Among very-low-birth-weight neonates is red blood cell transfusion an independent risk factor for subsequently developing a severe intraventricular hemorrhage? |
Q33908060 | An association between vasomotion and oxygen extraction |
Q34213094 | Anaerobic storage of red blood cells |
Q39400244 | Analysis of the association between necrotizing enterocolitis and transfusion of red blood cell in very low birth weight preterm infants |
Q36638818 | Anemia and splenomegaly in cGKI-deficient mice |
Q48328520 | Anemia contributes to cardiovascular disease through reductions in nitric oxide |
Q33738712 | Anemia in critical illness: insights into etiology, consequences, and management |
Q49590375 | Anemia, red blood cell transfusions, and necrotizing enterocolitis. |
Q50211493 | Antagonists of the system L neutral amino acid transporter (LAT) promote endothelial adhesivity of human red blood cells. |
Q37173246 | Arginase regulates red blood cell nitric oxide synthase and export of cardioprotective nitric oxide bioactivity |
Q33919217 | Association between length of storage of red blood cell units and outcome of critically ill children: a prospective observational study |
Q26995444 | Association between red cell transfusions and necrotizing enterocolitis |
Q41216261 | Association of Hematocrit and Red Blood Cell Transfusion with Outcomes in Infants Undergoing Norwood Operation |
Q89090980 | Association of Perioperative Red Blood Cell Transfusions With Venous Thromboembolism in a North American Registry |
Q90183193 | Association of blood group and red blood cell transfusion with the incidence of antepartum, peripartum and postpartum venous thromboembolism |
Q36187328 | Association of haematocrit and red blood cell transfusion with outcomes in infants with shunt-dependent pulmonary blood flow and univentricular physiology |
Q38440868 | Biochemistry of storage lesions of red cell and platelet concentrates: A continuous fight implying oxidative/nitrosative/phosphorylative stress and signaling. |
Q37867191 | Blood transfusion: old blood, new blood or no blood |
Q37416199 | Blood transfusions, thrombosis, and mortality in hospitalized patients with cancer |
Q36220974 | Can nitric oxide-based therapy prevent bronchopulmonary dysplasia? |
Q50482785 | Characterization of red blood cell deformability change during blood storage. |
Q36288472 | Clinical implications of the loss of vasoactive nitric oxide during red blood cell storage |
Q24631086 | Decreased erythrocyte deformability after transfusion and the effects of erythrocyte storage duration |
Q36074364 | Deformability of transfused red blood cells is a potent determinant of transfusion-induced change in recipient's blood flow |
Q37224411 | Diabetes augments and inhaled nitric oxide prevents the adverse hemodynamic effects of transfusing syngeneic stored blood in mice |
Q38116906 | Does the storage age of transfused blood affect outcome in burn patients? |
Q36115205 | Effect of processing and storage on red blood cell function in vivo |
Q37867951 | Effects of storage of red cells |
Q35602868 | Effects of storage-aged red blood cell transfusions on endothelial function in hospitalized patients |
Q24658413 | Endogenous S-nitrosothiols protect against myocardial injury |
Q36048495 | Enzymatic mechanisms regulating protein S-nitrosylation: implications in health and disease |
Q36610274 | Erythrocyte storage increases rates of NO and nitrite scavenging: implications for transfusion-related toxicity |
Q50637912 | Evaluating red cell recoveries in clinical trials: where should we set the bar? |
Q34007600 | Evolution of adverse changes in stored RBCs |
Q97568379 | FEEding DURing red cell transfusion (FEEDUR RCT): a multi-arm randomised controlled trial |
Q38883048 | Factors Affecting Tissue Oxygenation in Erythrocyte Transfusions |
Q33730032 | Feeding practices and other risk factors for developing transfusion-associated necrotizing enterocolitis |
Q35988928 | Fresh red blood cell transfusion and short-term pulmonary, immunologic, and coagulation status: a randomized clinical trial. |
Q33962451 | Haemoglobin-based oxygen carriers: research and reality towards an alternative to blood transfusions |
Q50023595 | Hemodynamic Functionality of Transfused Red Blood Cells in the Microcirculation of Blood Recipients. |
Q35644835 | Hemoglobin βCys93 is essential for cardiovascular function and integrated response to hypoxia |
Q37603613 | Hemoglobin, nitric oxide and molecular mechanisms of hypoxic vasodilation |
Q38055209 | How we decide when a neonate needs a transfusion |
Q22306368 | Hypoxic Vasodilation by Red Blood Cells: Evidence for an S-Nitrosothiol-Based Signal |
Q35388882 | Impaired adenosine-5'-triphosphate release from red blood cells promotes their adhesion to endothelial cells: a mechanism of hypoxemia after transfusion. |
Q33956628 | Inclusion of a nitric oxide congener in the insufflation gas repletes S-nitrosohemoglobin and stabilizes physiologic status during prolonged carbon dioxide pneumoperitoneum |
Q39038557 | Insufficient nitric oxide bioavailability: a hypothesis to explain adverse effects of red blood cell transfusion |
Q89585628 | Intra-operative blood transfusion significantly increases the risk of post-operative pulmonary embolism |
Q37082006 | Loss of red cell chemokine scavenging promotes transfusion-related lung inflammation |
Q64965588 | MicroRNA Dysregulation Associated with Red Blood Cell Storage. |
Q33754405 | Microcirculatory effects of the transfusion of leukodepleted or non-leukodepleted red blood cells in patients with sepsis: a pilot study. |
Q38388853 | Molecular mechanisms of erythrocyte aging |
Q87405954 | Mortality risk is dose-dependent on the number of packed red blood cell transfused after coronary artery bypass graft |
Q34147686 | NO Metabolites Levels in Human Red Blood Cells are Affected by Palytoxin, an Inhibitor of Na(+)/K(+)-ATPase Pump. |
Q89125077 | Neonatal RBC transfusions: Do benefits outweigh risks? |
Q38017819 | Nitric oxide formation versus scavenging: the red blood cell balancing act. |
Q38987725 | Nitric oxide metabolites and arginase I levels in β-thalassemic patients: an Egyptian study |
Q37490715 | Nitric oxide production pathways in erythrocytes and plasma. |
Q36717720 | Nitric oxide signaling in the microcirculation |
Q38112049 | Nitric oxide transport in blood: a third gas in the respiratory cycle |
Q37887771 | Nitric oxide: a guardian for vascular grafts? |
Q101564342 | Nitrite in breast milk: roles in neonatal pathophysiology |
Q34659126 | Non-leukodepleted red blood cell transfusion in sepsis patients: beyond oxygenation, is there a risk of inflammation? |
Q28544807 | Packed red blood cells are an abundant and proximate potential source of nitric oxide synthase inhibition |
Q35461855 | Packed red cell transfusions alter mesenteric arterial reactivity and nitric oxide pathway in preterm lambs |
Q30653456 | Parallel assay of oxygen equilibria of hemoglobin |
Q37812994 | Peripheral arterial ischemic events in cancer patients |
Q35560929 | Plasma free hemoglobin and microcirculatory response to fresh or old blood transfusions in sepsis |
Q44166128 | Postoperative red blood cell transfusion and morbid outcome in uncomplicated cardiac surgery patients |
Q46525276 | Proceedings of the Food and Drug Administration's public workshop on new red blood cell product regulatory science 2016. |
Q38667400 | Prolonged Blood Storage Does Not Effect Survival in an Animal Model of Hemorrhagic Shock |
Q35020178 | Protein S-nitrosylation in health and disease: a current perspective |
Q35802303 | Pulmonary hypertension in lambs transfused with stored blood is prevented by breathing nitric oxide |
Q55172218 | RED BLOOD CELL STORAGE LESION. |
Q34324631 | Randomized study of washing 40- to 42-day-stored red blood cells. |
Q91990369 | Rates, Risk Factors, and Complications of Red Blood Cell Transfusion in Metastatic Spinal Tumor Surgery: An Analysis of a Prospective Multicenter Surgical Database |
Q91707140 | Red Blood Cell Deformability, Vasoactive Mediators, and Adhesion |
Q90333662 | Red Blood Cell Dysfunction in Critical Illness |
Q61667382 | Red Blood Cell Transfusion Trigger in Cardiac Disease |
Q34907759 | Red blood cell age and potentiation of transfusion-related pathology in trauma patients. |
Q43126885 | Red blood cell endothelial nitric oxide synthase does not modulate red blood cell storage hemolysis |
Q50468367 | Red blood cell storage increases hypoxia-induced nitric oxide bioavailability and methemoglobin formation in vitro and in vivo. |
Q38271912 | Red blood cell storage lesion |
Q61808576 | Red blood cell storage lesion: causes and potential clinical consequences |
Q33775661 | Red blood cell storage: the story so far. |
Q37432027 | Red blood cell transfusion and skeletal muscle tissue oxygenation in anaemic haematologic outpatients |
Q37844462 | Red blood cell transfusion for infants with single-ventricle physiology |
Q39113597 | Red blood cell transfusion of preterm neonates with a Grade 1 intraventricular hemorrhage is associated with extension to a Grade 3 or 4 hemorrhage |
Q35868123 | Red blood cell washing, nitrite therapy, and antiheme therapies prevent stored red blood cell toxicity after trauma-hemorrhage |
Q42826125 | Red blood cells stored for increasing periods produce progressive impairments in nitric oxide-mediated vasodilation |
Q46162960 | Red cell age and loss of function: advance or SNO-job? |
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Q26865972 | Relationship between red cell storage duration and outcomes in adults receiving red cell transfusions: a systematic review |
Q50605150 | Relationships among haemoglobin level, packed red cell transfusion and clinical outcomes in patients after cardiac surgery. |
Q36161837 | Renitrosylation of banked human red blood cells improves deformability and reduces adhesivity. |
Q36808426 | Repletion of S-nitrosohemoglobin improves organ function and physiological status in swine after brain death |
Q27023101 | Research opportunities in optimizing storage of red blood cell products |
Q34726945 | Restoration of intracellular ATP production in banked red blood cells improves inducible ATP export and suppresses RBC-endothelial adhesion |
Q33431426 | Risk of thrombosis in cancer and the role of supportive care (transfusion, catheters, and growth factors). |
Q90569411 | Role of Nitric Oxide Carried by Hemoglobin in Cardiovascular Physiology: Developments on a Three-Gas Respiratory Cycle |
Q43050724 | Role of the b93cys, ATP and adenosine in red cell dependent hypoxic vasorelaxation |
Q47221722 | S-Nitrosohemoglobin Levels and Patient Outcome After Transfusion During Pediatric Bypass Surgery |
Q40881465 | S-Nitrosylated fetal hemoglobin in neonatal human blood |
Q37010539 | S-nitrosylation therapy to improve oxygen delivery of banked blood |
Q36497166 | S-nitrosylation: integrator of cardiovascular performance and oxygen delivery |
Q37236843 | SNO-hemoglobin is not essential for red blood cell-dependent hypoxic vasodilation |
Q41891878 | Safety of red blood cell substitutes as compared to stored donor red blood cells |
Q38935716 | Specific Etiologies Associated With the Multiple Organ Dysfunction Syndrome in Children: Part 2. |
Q34625437 | Storage of Blood Components Does Not Decrease Haemostatic Potential: In vitro Assessment of Fresh versus Stored Blood Components Using Thromboelastography |
Q47241670 | The Effects of Red Blood Cell Transfusion on Functional Outcome after Aneurysmal Subarachnoid Hemorrhage |
Q37529281 | The effect of three different (-135°C) whole body cryotherapy exposure durations on elite rugby league players |
Q40799294 | The red blood cell storage lesion: the end of the beginning |
Q41575009 | The transfusion problem: role of aberrant S-nitrosylation |
Q93071487 | Transfusion of Anaerobically or Conventionally Stored Blood After Hemorrhagic Shock |
Q35623668 | Transfusion of human volunteers with older, stored red blood cells produces extravascular hemolysis and circulating non-transferrin-bound iron. |
Q42606596 | Transfusion of older red blood cells is associated with decreased graft survival after orthotopic liver transplantation |
Q37693437 | Transfusion of stored autologous blood does not alter reactive hyperemia index in healthy volunteers |
Q34171727 | Transfusion related morbidity in premature babies: Possible mechanisms and implications for practice |
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Q43782523 | Trends, risk factors and mortality among women with venous thromboembolism during labour and delivery: a population-based study of 8 million births. |
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Q34029776 | Vascular effects of the red blood cell storage lesion |
Q36061661 | Vitamin C in mouse and human red blood cells: an HPLC assay |
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