about
Pre-diabetes augments neuropeptide Y1- and α1-receptor control of basal hindlimb vascular tone in young ZDF ratsEffect of sepsis on skeletal muscle oxygen consumption and tissue oxygenation: interpreting capillary oxygen transport data using a mathematical model.Divergent effects of low-O(2) tension and iloprost on ATP release from erythrocytes of humans with type 2 diabetes: implications for O(2) supply to skeletal muscleA computational model of a microfluidic device to measure the dynamics of oxygen-dependent ATP release from erythrocytesCaV1.2/CaV3.x channels mediate divergent vasomotor responses in human cerebral arteries.Microvascular flow modeling using in vivo hemodynamic measurements in reconstructed 3D capillary networksFinite Element Model of Oxygen Transport for the Design of Geometrically Complex Microfluidic Devices Used in Biological Studies.Estimating blood flow in skeletal muscle arteriolar trees reconstructed from in vivo data using the Fry approach.Identification of L- and T-type Ca2+ channels in rat cerebral arteries: role in myogenic tone developmentA mathematical model of oxygen transport in intact muscle with imposed surface oscillations.A computational model of oxygen delivery by hemoglobin-based oxygen carriers in three-dimensional microvascular networks.Comprehensive In Situ Analysis of Arteriolar Network Geometry and Topology in Rat Gluteus Maximus Muscle.From one generation to the next: a comprehensive account of sympathetic receptor control in branching arteriolar trees.Modeling steady state SO2-dependent changes in capillary ATP concentration using novel O2 micro-delivery methods.Electrical communication in branching arterial networks.Toward a multiscale description of microvascular flow regulation: o(2)-dependent release of ATP from human erythrocytes and the distribution of ATP in capillary networks.A simple "streak length method" for quantifying and characterizing red blood cell velocity profiles and blood flow in rat skeletal muscle arterioles.Impact of Incremental Perfusion Loss on Oxygen Transport in a Capillary Network Mathematical Model.A computational model of the effect of capillary density variability on oxygen transport, glucose uptake, and insulin sensitivity in prediabetes.Calculations of oxygen transport by red blood cells and hemoglobin solutions in capillaries.Inhibiting nitric oxide overproduction during hypotensive sepsis increases local oxygen consumption in rat skeletal muscle.A Microvascular Wall Shear Rate Function Derived From In Vivo Hemodynamic and Geometric Parameters in Continuously Branching Arterioles.A computational model of oxygen transport in skeletal muscle for sprouting and splitting modes of angiogenesis.Effect of decreased O2 supply on skeletal muscle oxygenation and O2 consumption during sepsis: role of heterogeneous capillary spacing and blood flow.Simulations of capillary network oxygen transport during transient ischemia in the presence and absence of tissue myoglobin.Computational modeling of oxygen transport from complex capillary networks. Relation to the microcirculation physiomeSomatic evolution in the immune system: the need for germinal centers for efficient affinity maturationA computational study of the effect of vasomotion on oxygen transport from capillary networksA computational study of the effect of capillary network anastomoses and tortuosity on oxygen transportHyperinsulinemia does not cause de novo capillary recruitment in rat skeletal muscleA streak length-based method for quantifying red blood cell flow in skeletal muscle arteriolar networks
P50
Q28484245-E87A2F9E-CE1A-429C-875D-14E58BCB49E2Q30952847-8D5E0DFC-C97D-44C5-AB29-0A4264086340Q34092917-D649CB50-8C19-4FB1-AB8D-8F71914E74BAQ35060583-1713A46C-0B7F-44E6-B26A-D99666CC3F8EQ35543117-249EA819-59C0-43D5-A729-07409E036CF8Q36087295-A75FE034-4B12-4C99-9E35-68A8D67A7AC7Q36187639-C1531DC9-8DD3-4AA3-96DE-8B7EABDEED23Q36362705-536B69A0-C56A-4B5D-9031-826CDF393B64Q36528098-A42AB0FA-E235-4BE2-A7AE-11A65D55C5BAQ36724753-438CD250-9144-4A24-9386-557F4511B16FQ37340967-6B429021-6A32-4E7E-BEA1-5D62892817B4Q38848553-85E0B9B9-C1B0-48C2-ACC5-B869FFB9CC5FQ40964160-BDFD84E6-2FD8-43FF-BCA1-48C239B7CCF1Q41768538-B6C06D76-4D2C-404B-95F3-903B3C2FC485Q41831082-78D20C8F-31DC-4F40-82A6-0B3FC1AC0ABAQ42321513-0FE906A0-76E5-411A-AA64-7A1AA6F7B13EQ43840148-36D13560-432B-4992-B9AF-38A9493E39FBQ47729619-9A5A3805-9292-4B39-BFFA-848B2DE54D71Q48140957-0DE2B654-E93C-4D29-BF6F-1162F54C02E9Q48618035-57E41EC3-0AF3-4041-872B-CFF86679A28CQ50665757-7A670DDE-3D4C-4E12-BEFC-47DB0EEA8CB3Q50682538-AC4E613B-28B0-4B92-A56B-E2B1EB26D1B6Q51294964-858F3A74-0F25-48FC-8F72-C2D79FDE0825Q51956313-6ADE2C42-1CA5-4686-963C-C5C6BED5F1C8Q52022756-98CC49FF-C508-4A48-8DB2-A97915A8117AQ73410576-313D8F35-9402-4E33-ABFD-281C85FBA756Q73444111-1D3DCBC9-51FC-4E74-868A-353267709677Q74008034-E283640F-6261-4E6B-99F5-6DA3ADDCEF06Q74247189-1E7FB8F3-C697-4218-8BA6-2B1578451770Q90667524-69295573-2236-4EC4-85F8-697ECB7B961BQ91218058-B632EAA7-BD1E-401E-A30E-29FCEB67BBED
P50
description
onderzoeker
@nl
physicist, researcher
@en
հետազոտող
@hy
name
Daniel Goldman
@ast
Daniel Goldman
@en
Daniel Goldman
@es
Daniel Goldman
@fr
Daniel Goldman
@nl
Daniel Goldman
@sl
type
label
Daniel Goldman
@ast
Daniel Goldman
@en
Daniel Goldman
@es
Daniel Goldman
@fr
Daniel Goldman
@nl
Daniel Goldman
@sl
altLabel
Daniel I. Goldman
@en
prefLabel
Daniel Goldman
@ast
Daniel Goldman
@en
Daniel Goldman
@es
Daniel Goldman
@fr
Daniel Goldman
@nl
Daniel Goldman
@sl
P106
P1153
8151308600
P21
P31
P496
0000-0002-8707-5536