Seminars in Thoracic and Cardiovascular Surgery: Pediatric Cardiac Surgery Annual
Volume 8, Issue 1 , Pages 12-21 , 2005

Noninvasive assessment of cardiac output

References 

  1. Schlag G , Redl H , Hallstrom S . The cell in shock (The origin of multiple organ failure) . Resuscitation . 1991;21:137–180
  2. Shoemaker WC . Relationship of oxygen transport to the pathophysiology and therapy of shock states . Intensive Care Med . 1987;13:230–243
  3. Rhodes A , Bennett ED . Early goal-directed therapy (An evidence-based review) . Crit Care Med . 2004;32(suppl):S448–S450
  4. Tantalean J , Leon R , Santos A , et al.   Multiple Organ dysfunction syndrome in children . Pediatr Crit Care Med . 2003;4:181–185
  5. Proulx F , Gauthoer M , Nadeau D , et al.   Timing and predictors of death in pediatric patients with multiple organ system failure . Crit Care Med . 1994;22:1025–1031
  6. Hatherill M , Waggie Z , Purves L , et al.   Mortality and the Nature of metabolic acidosis in children with shock . Intensive Care Med . 2003;29:286–291
  7. Rivers EP , Ander DS , Powell D . Central venous oxygen saturation monitoring in the critically ill patient . Curr Opin Crit Care . 2001;7:204–211
  8. Han YY , Carcillo JA , Dragotta MA . Early reversal of pediatric-neonatal septic shock by community physicians is associated with improved outcomes . Pediatrics . 2003;112:793–799
  9. Rivers E , Nguyen B , Havstad S , et al.   Early goal-directed therapy in the treatment of severe sepsis and septic shock . N Engl J Med . 2001;345:1368–1377
  10. Alia I , Esteban A , Gordo F , et al.   A randomized and controlled trial of the effect of treatment aimed at maximizing oxygen delivery in patients with severe sepsis or septic shock . Chest . 1999;115:453–461
  11. Boyd O , Bennett E . Enhancement of perioperative tissue perfusion as a therapeutic strategy for major surgery . New Horiz . 1996;4:453–465
  12. Yu M , Burchell S , Hassaniya N , et al.   Relationship of mortality to increasing oxygen delivery in patients > 50 years of age (a prospective, randomized trial) . Crit Care Med . 1998;26:1011–1019
  13. Tibby SM , Murdoch AI . Monitoring cardiac function in intensive care . Arch Dis Child . 2003;88:46–52
  14. Izzo JL , Taylor AA . The sympathetic nervous system and baroreceptors in hypertension and hypotension . Curr Hypertens Rep . 1999;1:254–263
  15. Kimmerly DS , Shoemaker JK . Hypovolemia and neurovascular control during orthostatic stress . Am J Physiol Heart Circ Physiol . 2002;282:H645–H655
  16. Shen FM , Guan YF , Xie HH . Arterial baroreflex function determines the survival time in lipopolysaccharide-induced shock in rats . Shock . 2004;21:556–560
  17. Haljamae H . Pathophysiology of shock . Acta Anesthesiol Scand . 1993;98:3–6
  18. Dyess DL , Powell RW , Swafford AN . Redistribution of organ blood flow after hemorrhage and resuscitation in full-term piglets . J Pediatr Surg . 1994;29:1097–1102
  19. Dantzker DR . Monitoring tissue oxygenation (The search for the grail) . Chest . 1997;111:12–13
  20. Ceppa EP , Fuh KC , Bulkley GB . Mesenteric hemodynamic response to circulatory shock . Curr Opin Crit Care . 2003;9:127–132
  21. Kvarstein G , Mirtaheri P , Tonnessen TI . Detection of organ ischemia during hemorrhagic shock . Acta Anaesthesiol Scand . 2003;47:675–686
  22. Reilly PM , Wilkins KB , Fuh KC , et al.   The mesenteric hemodynamic response to circulatory shock (An overview) . Shock . 2001;15:329–343
  23. Tatevossian R , Wo C , Velmahos G , et al.   Transcutaneous oxygen and CO2 as early warning of tissue hypoxia and hemodynamic shock in critically ill emergency patients . Crit Care Med . 2000;28:2248–2253
  24. Convertino VA , Baumgartner N . Effects of hypovolemia on aortic baroreflex control of heart rate in humans . Aviat Space Environ Med . 1997;68:838–843
  25. Wood CE , Tong H . Central nervous system regulation of reflex responses to hypotension during fetal life . Am J Physiol . 1999;277:R1541–R1552
  26. Newton GE , Parker JD . Cardiac sympathetic responses to acute vasodilation (Normal ventricular function versus congestive heart failure) . Circulation . 1996;94:3161–3167
  27. Pang CCY . Autonomic control of the venous system in health and disease (Effects of drugs) . Pharm Theurapeut . 2001;90:179–230
  28. Modesti PA , Polidori G , Bertolozzi I , et al.   Impairment of cardiopulmonary receptor sensitivity in the early phase of heart failure . Heart . 2004;90:30–36
  29. Neumann T , Heusch G . Myocardial, skeletal muscle, and renal blood flow during exercise in conscious dogs with heart failure . Am J Physiol . 1997;273:H2452–H2457
  30. Heistad DD , Abboiud FM . Circulatory adjustments to hypoxia . Circulation . 1980;61:463–470
  31. Li SG , Randall DC , Brown DR . Roles of cardiac output and peripheral resistance in mediating blood pressure response to stress in rats . Am J Physiol . 1998;274:R1065–R1069
  32. Yamazaki F , Sone R . Modulation of arterial baroreflex control of heart rate by skin cooling and heating in humans . J Appl Physiol . 2000;88:393–400
  33. Anand KJ , Hickey PR . Halothane-morphine compared with high-dose sufentanil for anesthesia and postoperative analgesia in neonatal cardiac surgery . N Engl J Med . 1992;326:1–9
  34. Gournay V , Droulin E , Roze JC . Development of baroreflex control of heart rate in preterm and full term infants . Arch Dis Child Fetal Neonatal Ed . 2002;86:F151–F154
  35. Winberg P , Ergander U . Relationship between hear rate, left ventricular output, and stroke volume in preterm infants during fluctuations in heart rate . Pediatr Res . 1992;31:117–120
  36. Pladys P , Wodey E , Betremieux P , et al.   Effects of volume expansion on cardiac output in the preterm infant . Acta Paediatr . 1997;86:1241–1245
  37. Parker MM , Hazelzet JA , Carcillo JA . Pediatric considerations . Crit Care Med . 2004;32(suppl):S591–S594
  38. Ai K , Kotake Y , Satoh T , et al.   Epidural anesthesia retards intestinal acidosis and reduces portal vein endotoxin concentrations during progressive hypoxia in rabbits . Anesthesiology . 2001;94:263–269
  39. Berstein AD , Hersch M , Cheung H , et al.   The effect of various sympathomimetics on the regional circulations in hyperdynamic sepsis . Surgery . 1992;112:549–561
  40. Breslow MJ , Miller CF , Parker SD , et al.   Effect of vasopressors on organ blood flow during endotoxin shock in pigs . Am J Physiol . 1987;252:H291–H300
  41. Meakins JL , Marshall JC . The gut as the motor of multiple system organ failure . In:  Marston A ,  Buckley GB ,  Fiddian-Green R editor. Splanchnic Ischemia and Multiple Organ Failure . London: Edward Arnold; 1989;p. 339–348
  42. Aneman A , Pettersson A , Eisenhofer G , et al.   Sympathetic and renin-angiotensin activation during graded hypovolemia in pigs (Impact on mesenteric perfusion and duodenal mucosal function) . Shock . 1997;8:378–384
  43. Toung T , Reilly PM , Fuh KC , et al.   Mesenteric vasoconstriction in response to hemorrhagic shock . Shock . 2000;13:267–273
  44. Di Giantomasso D , May CN , Bellomo R . Vital organ blood flow during hyperdynamic sepsis . Chest . 2003;124:1053–1059
  45. Peters JW , Mack GW , Lister G . The importance of the peripheral circulation in critical illness . Intensive Care Med . 2001;27:1446–1458
  46. Groeneveld ABJ , Kolkman JJ . Gastrointestinal ischemia and splanchnic tonometry (A review of physiology, methodology, and clinical applications) . J Crit Care . 1994;9:198–210
  47. Deitch EA , Morrison J , Berg R , et al.   Effect of hemorrhagic shock on bacterial translocation, intestinal morphology, and intestinal permeability in conventional and antibiotic-decontamination rats . Crit Care Med . 1990;18:529–536
  48. Marshall JC , Nathens AB . The gut in critical illness (Evidence from human studies) . Shock . 1996;6:S10–S16
  49. Hansen PR . In vitro studies on responses to pentoxifylline and aminophylline of rat mesenteric resistance vessels . Eur J Pharmacol . 1994;261:105–110
  50. Fink MP , Kaups KL , Wang H , et al.   Maintenance of superior mesenteric arterial perfusion prevents increased intestinal mucosal permeability in endotoxic pigs . Surgery . 1991;110:154–161
  51. Marshall JC . An intensivist’s dilemma (Support of the splanchnic circulation in critical illness) . Crit Care Med . 1998;26:1637–1638
  52. Tibby SM , Hatherill M , Murdoch IA . Capillary refill and core-peripheral temperature gap as indicators of hemodynamic status in pediatric intensive care patients . Arch Dis Child . 1999;80:163–166
  53. Leonard PA , Beattie TF . Is measurement of capillary refill time useful as part of the initial assessment of children? . Eur J Emerg Med . 2004;11:158–163
  54. Gorelick MH , Shaw KN , Baker MD . Effect of ambient temperature on capillary refill in healthy children . Pediatrics . 1993;92:699–702
  55. Tibby SM , Hatherill M , Marsh MJ , et al.   Clinicians’ abilities to estimate cardiac index in ventilated infants and children . Arch Dis Child . 1997;77:516–518
  56. Wesseling KH , Jansen JR , Settels JJ , et al.   Computation of aortic flow from pressure in humans using a nonlinear, three-element model . J Appl Physiol . 1993;74:2566–2573
  57. Bos WJ , van den Meiracker AH , Wesseling KH , et al.   Effect of regional and systemic changes in vasomotor tone on finger pressure amplification . Hypertension . 1995;26:315–320
  58. Gevers M , van Genderingen HR , Lafeber HN , et al.   Accuracy of oscillometric blood pressure measurement in critically ill neonates with reference to the arterial pressure wave shape . Intensive Care Med . 1996;22:242–248
  59. Hoffman GM , Stuth EAE . Hypoplastic left heart syndrome . In:  Lake CL ,  Booker PD editor. Pediatric Cardiac Anesthesia . 4th Edition. Baltimore, MD: Lippincott Williams and Wilkins; 2004;p. 445–466
  60. Carcillo JA , Fields AI . Clinical practice parameters for hemodynamic support of pediatric and neonatal patients in septic shock (American College of Critical Care Medicine Task Force Committee Members) . Crit Care Med . 2000;30:1365–1378
  61. Kluckow M , Evans N . Relationship between blood pressure and cardiac output in preterm infants requiring mechanical ventilation . J Pediatr . 1996;129:506–512
  62. Linderkamp O , Strohhacker I , Versmold HT , et al.   Peripheral circulation in the newborn (interaction of peripheral blood flow, blood pressure, blood volume, and blood viscosity) . Eur J Pediatr . 1978;129:73–81
  63. Hoffman GM , Ghanayem NS , Tweddell JS . Prediction of changes in arterio-venous oxygen difference from blood pressure and end-tidal CO2 after high-risk neonatal cardiac repair . Anesthesiology . 1999;91:A1247
  64. Salmenpera M , Aittomaki J . Cardiac output monitoring (need for improvement?) . Acata Anesthesiol Scand . 2003;47:375–377
  65. Boldt J , Menges T , Wollbruck M , et al.   Is continuous cardiac output using thermodilution reliable in the critically ill patient? . Crit Care Med . 1994;22:1913–1918
  66. Rauch H , Muller M , Fleischer F , et al.   Pulse contour analysis versus thermodilution in cardiac surgery patients . Acta Anaesthesiol Scand . 2002;46:424–429
  67. L’E Orme RM , Pigott DW , Mihm FG . Measurement of cardiac output by transpulmonary arterial thermodilution using a long radial artery catheter (A comparison with intermittent pulmonary artery thermodilution) . Anaesthesia . 2004;59:590–594
  68. Chang AC , Kulik TJ , Hickey PR , et al.   Real-time gas exchange measurement of oxygen consumption in neonates and children after cardiac surgery . Crit Care Med . 1993;21:1369–1375
  69. Hoffman GM , Torres A , Forster HV . Validation of a volumeless breath-by-breath method for measurement of respiratory quotient . J Appl Physiol . 1993;75:1903–1910
  70. Ackland G , Grocott MP , Mythen MG . Understanding gastrointestinal perfusion in critical care (so near, and yet so far) . Crit Care . 2000;4:269–281
  71. Weil MH , Bisera J , Trevino RP , et al.   Cardiac output and end-tidal carbon dioxide . Crit Care Med . 1985;13:907–909
  72. Botero M , Kirby D , Lobato EB , et al.   Measurement of cardiac output before and after cardiopulmonary bypass (Comparison among aortic transit-time ultrasound, thermodilution, and noninvasive partial CO2 rebreathing) . J Cardiothorac Vasc Anesth . 2004;18:563–572
  73. Levy RJ , Chiavacci RM , Nicolsen SC , et al.   An evaluation of noninvasive cardiac output measurement using partial carbon dioxide rebreathing in children . Anesth Analg . 2004;99:1642–1647
  74. Cotter G , Moshkovitz Y , Kaluski E , et al.   Accurate noninvasive continuous monitoring of cardiac output by whole-body electrical impedance . Chest . 2004;125:1431–1440
  75. Jansen JR , Schreuder JJ , Mulier JP , et al.   A comparison of cardiac output derived from the arterial pressure wave against thermodilution in cardiac surgery patients . Br J Anaesth . 2001;87:212–222
  76. Bein B , Worthmann F , Tonner PH , et al.   Comparison of esophageal Doppler, pulse contour analysis, and real-time pulmonary artery thermodilution for the continuous measurement of cardiac output . J Thorac Cardiovasc Anesth . 2004;18:185–189
  77. Della Rocca G , Costa MG , Pompei L , et al.   Continuous and intermittent cardiac output measurement (Pulmonary artery catheter vs. aortic transpulmonary technique) . Br J Anaesth . 2002;88:350–356
  78. Imholz BP , Wieling W , van Montfrans GA , et al.   Fifteen years experience with finger arterial pressure monitoring (Assessment of the technology) . Cardiovasc Res . 1998;38:605–616
  79. van Lieshout JJ , Wesseling KH . Continuous cardiac output by pulse contour analysis? . Br J Anaesth . 2001;86:467–469
  80. Rasanen J , Peltola K , Leijala M . Superior vena caval and mixed venous oxyhemoglobin saturations in children recovering from open heart surgery . J Clin Monit . 1992;8:44–49
  81. Ladakis C , Myrianthefs P , Karabinis A , et al.   Central venous and mixed venous oxygen saturation in critically ill patients . Respiration . 2001;68:279–285
  82. Dantzker DR . Adequacy of tissue oxygenation . Crit Care Med . 1993;21:S40–S43
  83. van der Hoeven MA , Maertzdorf WJ , Blanco CE . Mixed venous oxygen saturation and biochemical parameters of hypoxia during progressive hypoxemia in 10- to 14-day-old piglets . Pediatr Res . 1997;42:878–884
  84. Hoffman GM , Ghanayem NS , Kampine JM , et al.   Venous saturation and the anaerobic threshold in neonates after the Norwood procedure for hypoplastic left heart syndrome . Ann Thorac Surg . 2000;70:1515–1520
  85. Hoffman GM , Tweddell JS , Ghanayem NS , et al.   Relationship between venous saturation and anaerobic metabolism in neonates following one or two ventricle procedures . Cardiol Young . 2001;11:9
  86. Kremzar B , Spec-Marn A , Kompan L , et al.   Normal values of SvO2 as therapeutic goal in patients with multiple injuries . Intensive Care Med . 1997;23:65–70
  87. Tweddell JS , Hoffman GM , Mussatto KA , et al.   Improved survival of patients undergoing palliation of hypoplastic left heart syndrome (Lessons learns from 115 consecutive patients) . Circulation . 2002;106(suppl 1):I82–I89
  88. Krafft P , Steltzer H , Hiesmayr M , et al.   Mixed venous oxygen saturation in critically ill septic shock patients (The role of defined events) . Chest . 1993;103:900–906
  89. Ruokonen E , Takala J , Kari A , et al.   Regional blood flow and oxygen transport in septic shock . Crit Care Med . 1993;21:1296–1303
  90. Marik PE . Gastric intramucosal pH (A better predictor of multiorgan dysfunction syndrome and death than oxygen-derived variables in patients with sepsis) . Chest . 1993;104:225–229
  91. Meier-Hellmann A , Hannemann L , Specht M , et al.   The relationship between mixed venous and hepatic venous O2 saturation in patients with septic shock . In:  Vaupel P editors. Oxygen Transport to the Tissues XV . New York: Plenum Press; 1994;p. 701–707
  92. Pollard V , Prough DS , DeMelo AE , et al.   Validation in volunteers of a near-infrared spectroscope for monitoring brain oxygenation in vivo . Anesth Analg . 1996;82:269–277
  93. Boushel R , Langberg H , Olesen J , et al.   Monitoring tissue oxygen availability with near infrared spectroscopy (NIRS) in health and disease . Scand J Med Sci Sports . 2001;11:213–222
  94. Fadel PJ , Keller DM , Watanabe H , et al.   Noninvasive assessment of sympathetic vasoconstriction in human and rodent skeletal muscle using near-infrared spectroscopy and Doppler ultrasound . J Appl Physiol . 2004;96:1323–1330
  95. Chaisson NF , Kirschner RA , Deyo DJ , et al.   Near-infrared spectroscopy-guided closed-loop resuscitation of hemorrhage . J Trauma . 2003;54(suppl):S183–S192
  96. Crookes BA , Cohn SM , Burton EA , et al.   Noninvasive muscle oxygenation to guide fluid resuscitation after traumatic shock . Surgery . 2004;135:662–670
  97. Kurth CD , Levy WJ , McCann J . Near-infrared spectroscopy cerebral oxygen saturation thresholds for hypoxia-ischemia in piglets . J Cereb Blood Flow Metab . 2002;22:335–341
  98. Levy WJ , Levin S , Chance B . Near-infrared measurement of cerebral oxygenation (Correlation with electroencephalographic ischemia during ventricular fibrillation) . Anesthesiology . 1995;83:738–746
  99. Austin EH , Edmonds HL , Auden SM , et al.   Benefit of neurophysiologic monitoring for pediatric cardiac surgery . J Thorac Cardiovasc Surg . 1997;114:707–715 717
  100. Nollert G , Jonas RA , Reichart B . Optimizing cerebral oxygenation during cardiac surgery (A review of experimental and clinical investigations with near infrared spectrophotometry) . Thorac Cardiovasc Surg . 2000;48:247–253
  101. Hoffman GM , Stuth EA , Jaquiss RD , et al.   Changes in cerebral and somatic oxygenation during stage 1 palliation of hypoplastic left heart syndrome using continuous regional cerebral perfusion . J Thorac Cardiovasc Surg . 2004;127:223–233
  102. Takasu A , Yagi K , Ishihara S , et al.   Combined continuous monitoring of systemic and cerebral oxygen metabolism after cardiac arrest . Resuscitation . 1995;29:189–194
  103. Hoffman G, Robertson FA, Berens R, et al: Relationship of cerebral and somatic oxygenation by two-site near infrared spectroscopy and venous saturation in neonates following the Norwood procedure. Presented at the World Congress of Anesthesiology
  104. Hoffman GM , Stuth EA , Berens RJ , et al.   Two-site near-infrared transcutaneous oximetry as a non-invasive indicator of mixed venous oxygen saturation in cardiac neonates . Anesthesiology . 2003;97:A-1393
  105. Jordan J , Shannon JR , Diedrich A , et al.   Interaction of carbon dioxide and sympathetic nervous system activity in regulation of cerebral perfusion in humans . Hypertension . 2000;36:383–388
  106. Malpas SC , Evans RG , Head GA , et al.   Contribution of renal nerves to renal blood flow variability during hemorrhage . Am J Physiol . 1998;274:R1283–R1294
  107. Levine BD , Giller CA , Lane LD , et al.   Cerebral versus systemic hemodynamics during graded orthostatic stress in humans . Circulation . 1994;90:298–306
  108. Kraut A , Barbiro-Michaely E , Mayevsky A . Differential effects of norepinephrine on brain and other less vital organs detected by a multisite multiparametric monitoring system . Med Sci Monit . 2004;10:BR215–BR220
  109. Hoffman GM , Ghanayem NS , Stuth ES , et al.   NIRS-derived somatic and cerebral saturation difference provides non-invasive real-time hemodynamic assessment of cardiogenic shock and risk of anaerobic metabolism . Anesthesiology . 2004;99:A1448

PII: S1092-9126(05)00006-2

doi: 10.1053/j.pcsu.2005.01.005

Seminars in Thoracic and Cardiovascular Surgery: Pediatric Cardiac Surgery Annual
Volume 8, Issue 1 , Pages 12-21 , 2005

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