Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
about
Algorithm for identifying and separating beats from arterial pulse records.Systematic review of near-infrared spectroscopy determined cerebral oxygenation during non-cardiac surgeryBiological aortic age derived from the arterial pressure waveformHemodynamic effects of leg crossing and skeletal muscle tensing during free standing in patients with vasovagal syncope.Leg crossing improves orthostatic tolerance in healthy subjects: a placebo-controlled crossover study.Dissection of carotid sinus hypersensitivity: the timing of vagal and vasodepressor effects and the effect of body position.Hemodynamic mechanisms underlying prolonged post-faint hypotension.Cardiac output and sympathetic vasoconstrictor responses during upright tilt to presyncope in healthy humans.The main determinant of hypotension in nitroglycerine tilt-induced vasovagal syncope.Postexercise syncope: Wingate syncope test and effective countermeasure.Which hemodynamic parameter predicts nitroglycerin-potentiated head-up tilt test response?Orthostatic Intolerance Is Independent of the Degree of Autonomic Cardiovascular Adaptation after 60 Days of Head-Down Bed Rest.Left ventricular stroke volume quantification by contrast echocardiography - comparison of linear and flow-based methods to cardiac magnetic resonance.A definition of normovolaemia and consequences for cardiovascular control during orthostatic and environmental stress.Central and peripheral contributors to skeletal muscle hyperemia: response to passive limb movement.Continuous stroke volume estimation from aortic pressure using zero dimensional cardiovascular model: proof of concept study from porcine experiments.Understanding exercise-induced hyperemia: central and peripheral hemodynamic responses to passive limb movement in heart transplant recipients.Congestive heart failure with preserved ejection fraction is associated with severely impaired dynamic Starling mechanismEffects of pericardial constraint and ventricular interaction on left ventricular hemodynamics in the unloaded heart.Heart failure and movement-induced hemodynamics: partitioning the impact of central and peripheral dysfunction.Passive leg movement and nitric oxide-mediated vascular function: the impact of age.Limitations of stroke volume estimation by non-invasive blood pressure monitoring in hypergravityNon-Invasive Determination of Cardiac Output in Pre-Capillary Pulmonary Hypertension.Impact of body position on central and peripheral hemodynamic contributions to movement-induced hyperemia: implications for rehabilitative medicineNon-invasive pulsatile arterial pressure and stroke volume changes from the human finger.A differing role of oxidative stress in the regulation of central and peripheral hemodynamics during exercise in heart failure.Impaired skeletal muscle vasodilation during exercise in heart failure with preserved ejection fractionRelationship between sympathetic nerve activity and aortic wave reflection characteristics in postmenopausal women.Evidence for unloading arterial baroreceptors during low levels of lower body negative pressure in humans.Optimisation of cardiac resynchronization therapy in clinical practice during exercise.Hypovolemia explains the reduced stroke volume at altitude.Novel use of cardiac pacemakers in heart failure to dynamically manipulate the respiratory system through algorithmic changes in cardiac output.Noninvasive continuous hemodynamic monitoring.Single passive leg movement assessment of vascular function: The contribution of nitric oxide.Differential contribution of ACh-muscarinic and β-adrenergic receptors to vasodilatation in noncontracting muscle during voluntary one-legged exerciseLimb movement-induced hyperemia has a central hemodynamic component: evidence from a neural blockade study.Modelflow estimates of cardiac output compared with Doppler ultrasound during acute changes in vascular resistance in women.Non-invasive assessment of cardiac output at rest and during exercise by finger plethysmography.Simultaneous determination of the kinetics of cardiac output, systemic O(2) delivery, and lung O(2) uptake at exercise onset in men.Evaluating the efficacy of an active compression brace on orthostatic cardiovascular responses.
P2860
Q24814723-16AB82C4-3724-49E1-86F1-15091E5797EBQ27022316-7CC7DE22-1D0B-4E79-A20D-3D90D5CD36A6Q30469020-B40E2577-08E6-4A99-954D-268BBC4C465FQ33151909-0DB429BD-FA28-4259-A251-8222318ED812Q33153864-526F95D4-FA72-4E0E-B8B5-1069FF08760BQ33160049-7F2BF0C5-E07D-4894-B0D3-171F9C0D3219Q33160292-FCC1B02A-C60E-485B-90F6-E457B0F285FDQ33160962-F414AE84-B365-4564-8DEF-B5F9F24A0C62Q33161216-DECBAF46-F1D6-47FC-B2A8-DC52544510A6Q33163329-39B604AA-4B77-4503-919F-9BE973C7C7AFQ33165283-5D5ED27A-AEC3-4640-8FB5-23B840EAE5E8Q33166315-7B8197A7-CD58-4CEC-AD01-219B2D57706FQ33556801-997EF143-D741-4297-9423-07D13E7B5F41Q33816729-1D5C185A-D0CD-4056-A8AD-94896A6A8924Q33910829-D52212F5-7094-4BC3-88A1-3AF190540E8DQ33916330-1A0510E0-F862-4F9E-8067-829D294418E2Q34357729-CC29D00E-EFCE-47F7-863D-3D6C6F12F0AFQ34785045-7D730A1E-8373-45A0-9E00-ACC1AB2A3025Q34979758-B1AB2E49-EF9E-45CC-8CD7-DEAD4CB61972Q35040427-EE2CE0C7-537E-4F11-BE6B-5E4973D7B59CQ35178663-EF361013-8637-46D7-B682-EFBE331DBAF9Q35208215-57B7AE30-DC5D-4EB7-A226-750055E1B46DQ35726725-605EC219-AAEF-49C8-AC87-102951CAA0A1Q35767693-443511E3-EC67-4180-90D3-3DA964445E75Q36085316-5265E061-0D78-436F-85DA-411550C227BEQ36454221-C6EEB1F2-3231-451C-86F2-CEF2396FF3ADQ36805655-59A3BCF8-9EFB-4CB3-8B76-93B96ABA8298Q36981275-74B60A03-1AB0-4E96-882A-85882B71FF33Q37100134-51E491F6-928E-4C64-9321-8B41FECF4798Q37179806-BBD455C9-E344-4463-BB0E-072AE714667BQ37344111-ADC39A39-66B9-4BB6-8FA6-7501B84AF192Q37380890-C5199734-DC5F-4B13-A58C-B33038A670F7Q38018511-A4542F15-BCD9-4D41-80B2-4F8CD3B7C70DQ38599190-4C70C586-A639-4C7A-8332-E6B5BC7F8D5FQ41884597-2990CE20-A32A-4CB4-822C-34E256AD7848Q42129312-4375CA68-ED9C-462B-B7AC-FA408E9D64E6Q43191915-2F56ED47-C6C3-4308-AAC8-8533724DF0E8Q44522875-903BE1A6-8FE2-4374-A94C-CEDE57203D98Q46766031-A9B53022-BC14-437F-9377-31CC179DCF32Q46939425-A00E18B2-CDCE-49FF-93E9-B2B58F1FA694
P2860
Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
description
2003 nî lūn-bûn
@nan
2003 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2003 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
name
Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
@ast
Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
@en
type
label
Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
@ast
Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
@en
prefLabel
Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
@ast
Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
@en
P2093
P1476
Beat-to-beat noninvasive stroke volume from arterial pressure and Doppler ultrasound.
@en
P2093
Erik Jan van Lieshout
Johannes J van Lieshout
Karel H Wesseling
Karin Toska
Lars Walløe
Morten Eriksen
P2888
P304
P356
10.1007/S00421-003-0901-8
P577
2003-07-08T00:00:00Z