Open-access From Echocardiographic Evaluation to Biomarkers Measurement: The Role of Myocardial Dysfunction in Mortality Associated with Sepsis

Abstract

Sepsis remains the leading cause of mortality and critical illness worldwide. Myocardial dysfunction is one of the most clinically relevant manifestations of sepsis and results from a complex interaction among genetic, molecular, metabolic, and structural changes. Despite the prominence given to the occurrence of systolic dysfunction during sepsis, the association between diastolic dysfunction and mortality is controversial, while diastolic dysfunction and right ventricular dysfunction are identified as independent predictors of mortality in the most recent studies. Elevation of biomarkers during sepsis may result from several mechanisms, and although the role of the B-type natriuretic peptide (BNP) and the N-terminal portion of its prohormone (NT-proBNP) as independent predictors of mortality is well defined, the same cannot be said about cardiac troponins due to conflicting results among currently available studies.

The objective of the present review is to discuss the pathophysiological mechanisms of myocardial dysfunction induced by sepsis in adults and the role of echocardiography and cardiac biomarkers as tools for prognostic evaluation in this clinical setting.

Keywords: Sepsis; Mortality; Biomarkers; Cardiac dysfunction

Introduction

Sepsis is a set of physiological, pathological, and biochemical abnormalities that can occur in response to infection caused by any pathological agent. Despite the advances in the treatment and support of critically ill patients, sepsis continues to be the main cause of mortality and severe disease throughout the world, with an estimated incidence of 17 million cases per year.1

Myocardial dysfunction is one of the manifestations of greater clinical relevance in sepsis and one of the organic dysfunctions that most early occurs in septic shock.2 By definition, it consists of reversible systolic and/or diastolic dysfunction of the left ventricle (LV) and/or right ventricle (RV) (Figure 1).3,4

Figure 1
Main mechanisms of cardiac dysfunction, along with its consequences and impact.

In recent years, myocardial dysfunction induced by sepsis became a focus of exhaustive investigation as an independent predictor of mortality in this clinical context, especially after the growing use of biomarkers of myocardial injury as indicators of poor prognosis in cardiovascular diseases.5

The objective of this review is to discuss the pathophysiological mechanisms of myocardial dysfunction induced by sepsis in adults and the role of echocardiography and cardiac biomarkers as tools for prognostic evaluation in this clinical scenario.

Pathophysiology

Sepsis-induced myocardial dysfunction is believed to result from a complex interaction among genetic, molecular, metabolic, and structural alterations that may have unique and independent contributions or very confusing and intricate interrelationships (Figure 2).6 The involved factors include:

Figure 2
Molecular factors involved in myocardial depression.

  • - Action of myocardial depressants: the combined action of tumor necrosis factor-alpha (TNF-α) with interleukin 1-beta (IL-1 β) is cardiodepressant and can play an important role in the early reduction of myocardial contractility observed in the course of sepsis.7 Furthermore, both induce the release of additional factors that may similarly affect the myocardial function, as for example, nitric oxide (NO), which in turn is also a cause of reduced glutathione, oxidative stress, and mitochondrial dysfunction.8,9 Although its exact role in the pathogenesis of myocardial dysfunction in sepsis is unknown, endothelin-1 has been demonstrated in animal models to directly affect the myocardial performance as well.10

  • - Alterations of calcium channels: the involvement of these channels with myocardial dysfunction can be explained by the relationship between intracellular calcium concentrations and cardiac contractility, but experimental models have shown that despite the reduction in L-type calcium channels observed in sepsis leading to a reduction in cardiac repolarization, there is no clear association between the resulting shortening of the duration of action potential and a possible reduction in myocardial contractility.11

  • - Toll-like receptors: toll-like receptors (TLRs) recognize specific pathogenic molecular patterns and play an important role in innate immunity. Experimental models have demonstrated that the activation of nuclear factor κB mediated by TLR4 plays an important role in the development of myocardial depression12 and that TLR3 knockout mice maintain a normal cardiac function even during sepsis.13

  • - Adrenergic hyperstimulation: in the early stage of sepsis, there is a massive release of catecholamines from the autonomous nervous system, intestine, leukocytes, and macrophages, resulting in hyperstimulation of alpha and beta-adrenergic receptors, which finally leads to their downregulation and resistance to circulating catecholamines.14,15

  • - Mitochondrial dysfunction: an adequate supply of adenosine triphosphate (ATP) is fundamental to the maintenance of myocardial contractility, and several mechanisms of mitochondrial lesion can play an important role in the development of myocardial dysfunction during sepsis, such as edema of the mitochondrial matrix, oxidative stress, alteration of membrane permeability, imbalance between biogenesis processes (growth and division), and mitophagy (removal of dysfunctional mitochondria by autophagy).16 Joseph et al.17 demonstrated that the activation of the NADPH oxidase 2 - an enzyme complex found in the plasma membrane and involved in the maintenance of immune function, cell growth, and apoptosis - is one of the responsible factors for the oxidative stress induced by sepsis, and that its inhibition decreases not only the production of oxygen-derived reactive species, but also preserves the mitochondrial function and homeostasis of intracellular calcium, relieving the systolic dysfunction induced by sepsis in vivo.17

  • - Necrosis and apoptosis of cardiomyocytes: focal myocardial necrosis and subendocardial necrosis have been identified in experimental models of sepsis, while necrosis of the contractile bands was identified by Schmittinger et al.18 in a prospective study involving the histological analysis of 20 biopsied human hearts.

  • - Myocardial infiltration: myocardial infiltration by neutrophils, monocytes, and macrophages is the main histological finding in septic cardiomyopathy. This inflammatory process is associated with interstitial edema, fibrosis, and formation of thrombi in the microcirculation.18,19

Left ventricular systolic dysfunction and mortality

LV systolic dysfunction has been the most studied and reported dysfunction in the literature, and despite reduced myocardial contractility occurring in 100% of the cases of severe sepsis,20 studies estimate that only 20 to 60% of the patients with septic shock have decreased LV ejection fraction (LVEF)21-23 in the first 3 days of treatment, with a gradual return to the baseline value around the tenth day from the onset of sepsis among the survivors.21

Despite the importance given to the occurrence of systolic dysfunction during sepsis, its association with mortality is controversial. Ognibene et al.24 observed that, paradoxically, patients with lower LVEF and greater LV end-diastolic volume (LVEDV) had a greater chance of surviving and recovering their myocardial function in the course of sepsis.24 Additionally, Vieillard-Baron et al.22 identified that acute and reversible left ventricular dysfunction was not associated with worse prognosis.

Narvaéz et al.25 reported a 22.8% incidence of septic cardiomyopathy among patients with severe sepsis or septic shock, with no difference in mortality when compared with patients with LVEF ≥ 50% and normalization of LV function after recovery from the acute event.25 De Geer et al.,26 using speckle tracking, observed that the global longitudinal strain is often reduced in patients with septic shock, either alone or associated with a reduction in the LVEF or the average mitral annular motion velocity measured by tissue Doppler (e’).26 The authors also observed that the global longitudinal strain presents a strong correlation with NT-proBNP levels on the first day of hospitalization, but is not significantly different between survivors and nonsurvivors, therefore, is not a good predictor of mortality.26

In a recent meta-analysis that included seven prospective observational studies evaluating the relationship between systolic dysfunction associated with sepsis and mortality, the presence of a new-onset systolic dysfunction was not a sensitive or specific predictor of mortality due to the heterogeneity and low statistical power of the studies involved.27

The assessment of the systolic function during sepsis can be a complex and challenging task,28 which may lead to the myocardial depression not being readily identified29 or the LVEF to be even overestimated, depending on the moment it is assessed.30 This occurs because the heart, despite being a central component of the cardiovascular system, is affected during sepsis by disorders of capillary permeability and peripheral vascular tonus, with fluid loss to the third space, absolute hypovolemia, and consequent decrease in preload, in addition to peripheral vasodilation with a direct reduction of the afterload and relative hypovolemia, leading to an additional decrease in preload.28

Since myocardial contractility is invariably reduced in sepsis, the LVEF ends up reflecting the balance between preload and afterload; in this way, despite the reduction of the intravascular volume directly affecting even more the myocardial function,31 the arterial vasodilation, by reducing the afterload, may temporarily mask the myocardial depression and allow the LV systolic function to be preserved, i.e., overestimated despite a severely compromised intrinsic contractility, while the correction of the vasoplegia by volume resuscitation and the use of vasopressors unveil the contractile deficit.30 In fact, Boissier et al.,32 using tissue Doppler and speckle tracking, showed that most patients with septic shock have reduced LV strain, and observed an inverse correlation between most indices of contractility and afterload.32 In addition, the diagnosis of systolic dysfunction in this clinical scenario can be hindered by the high prevalence of heart failure with reduced ejection fraction (HFREF) in the population, often done retrospectively by the observation of improvement in ventricular function through serial echocardiographic assessments.

Left ventricular diastolic dysfunction and mortality

Diastolic dysfunction is equally prevalent in the presence of sepsis, occurring in approximately 40% of the patients,33,34 although this number may vary according to the criteria used to evaluate the diastolic function. This has been observed in a study conducted by Clancy et al.,35 in which 60% of the patients evaluated on the first day of an episode of severe sepsis or septic shock presented diastolic dysfunction and 23% presented indeterminate diastolic function according to the guidelines published in 2016 by the American Society of Echocardiography along with the European Association of Cardiovascular Imaging, while 21% and 74% had diastolic dysfunction or indeterminate diastolic function, respectively, according to the 2009 guidelines of the American Society of Echocardiography.35

It is not yet clear whether diastolic dysfunction is induced by this condition or changed by its treatment (with volume expansion and use of vasopressors) or, even, if it is a preexisting condition aggravated by the infection.31 The prevalence of diastolic dysfunction is known to increase significantly with age,36 especially with the occurrence of comorbidities like hypertension and ischemic cardiopathy, characteristics often present in the target populations of the studies. The isolated presence of diastolic dysfunction is already in itself a marker of poor prognosis. Redfield et al.37 demonstrated by multivariate analysis that the isolated presence of any degree of diastolic dysfunction was strongly predictive of mortality, while Flu et al.38 showed that isolated diastolic dysfunction was associated with a higher risk of cardiovascular events in 30 days and cardiovascular mortality in the long term in patients undergoing open vascular surgery.38 Nevertheless, little is known about how the presence of diastolic dysfunction increases the risk of mortality in sepsis, but a very plausible hypothesis is that the abnormal relaxation of the LV potentiated by tachycardia induced by sepsis and/or decreased complacency could promote changes in cardiac hemodynamics in such a way that the normal cardiac output could only be maintained through increased LV filling pressures and greater atrial participation in ventricular filling.39

Once the left ventricular pressure rises disproportionately in response to a relatively small increase in volemia, such patients can progress with pulmonary venous congestion secondary to an overload of fluids required for volume resuscitation and enhanced by the widespread increase in capillary permeability secondary to endothelial dysfunction induced by sepsis.40

Regardless of the limitations presented, diastolic dysfunction has been singled out as an independent predictor of mortality by studies with tissue Doppler techniques for the evaluation of the properties of relaxation of the myocardium. Sturgess et al.,41 in a prospective observational study with patients admitted to intensive care with septic shock, concluded that after adjustment for disease severity, presence of cardiac disease, volemic management, and degree of diastolic dysfunction, the ratio between the speed of early diastolic transmitral flow by pulsed Doppler (E) and e’ - the E/e’ ratio - was an important independent predictor of in-hospital survival that allowed a better discrimination of survivors and nonsurvivors than cardiac biomarkers.41

Landesberg et al., in a study including 262 patients with severe sepsis and septic shock, observed that diastolic dysfunction was not only common but also represented an important predictor of mortality in this context. The authors observed that patients with isolated systolic dysfunction (LVEF ≤ 50%; 9% of the patients) and diastolic dysfunction (e’ < 8 cm/s; 40% of the patients) alone or associated with systolic dysfunction (14% of the patients) showed a significantly higher mortality than those without any type of dysfunction. In this study, a septal e’ < 8 cm/s was considered an independent predictor of mortality.42

Mourad et al.43 followed 72 patients with cancer admitted with septic shock to an intensive care unit and found that early diastolic dysfunction was a strong independent predictor of mortality in these patients and, once again, a lateral e’ < 8 cm/s was an echocardiographic parameter independently associated with mortality.43

In 2014, Landesberg et al.44 evaluated a new cohort of patients with severe sepsis and septic shock to investigate the manifestation of myocardial dysfunction that best correlates with troponin elevations and explain its association with mortality in sepsis. The authors concluded that diastolic dysfunction and RV dilation were the echocardiographic characteristics that best correlated with troponin levels and best independent predictors of in-hospital mortality than this biomarker, suggesting a potential contribution of these cardiac mechanical properties in the elevation of troponin levels and association with mortality in this clinical context. Once again, a septal e’ < 8 cm/s was an important risk marker of mortality.45

More recently, Rolando et al., in a prospective observational study with 53 patients with a mean age of 74 years, observed that diastolic dysfunction was present in 83% of this population and that the E/e’ ratio was the index of diastolic dysfunction that best correlated with decreased hospital survival on multivariate analysis.45

These findings have been corroborated by a meta-analysis comprising 16 studies and 1,507 patients with severe sepsis or septic shock, in which both a lower e’ and a higher E/e’ ratio had a significant association with mortality.46

Right ventricular dysfunction and mortality

Right ventricular systolic dysfunction, characterized by reduced contractility, increased right atrial pressure, and reduced venous return, has been reported in 30 to 50% of the patients during sepsis.47 This complication may occur isolated or in association with left ventricular systolic dysfunction, justifying in the latter case the maintenance of filling pressures in the left side within the limits of normality, even in the presence of important contractility deficit.20

Similar to what occurs with the LV, the RV ejection fraction (RVEF) is directly dependent on the coupling between contractility and afterload, but different from the systemic vascular resistance, which is initially reduced, pulmonary vascular resistance is increased since the early stages of sepsis by decreased production of NO48,49 and increased circulating levels of vasoactive substances, such as thromboxane, endothelin, and serotonin.50-53

An RV with an intrinsic reduction in contractility induced by sepsis becomes more sensitive to the increase in afterload secondary to pulmonary vascular dysfunction54 and only manages to maintain, at least initially, its systolic function through increased filling pressures provided by an adequate volume resuscitation; with fluid administration, there is an increase in cardiac index, central venous pressure, pulmonary capillary wedge pressure, and indices of end systolic and diastolic RV volumes, despite a progressive reduction in the ejection fraction of this ventricle.55

The failure of this compensatory mechanism becomes particularly more evident in patients on mechanical ventilation and in the presence of acute lung injury. In the first case, the effects of positive pressure on cardiac function lead to decreased venous return (hindering the increased filling pressures), elevation in pulmonary vascular resistance, and reduction in cardiac output due to increased intrathoracic pressure.56 In the second, the hyperinflation resulting from recruitment maneuver and the pulmonary collapse due to alveolar filling and protective ventilation strategies using very low tidal volumes can also elevate the pulmonary vascular resistance by an increased autonomic tonus reflex and hypoxic pulmonary vasoconstriction, respectively.57,58

Regardless of this mechanism of adaptation, the literature has demonstrated an association between right ventricular systolic dysfunction and mortality in sepsis, with studies pointing to a lower RVEF59,60 and, more recently, to a reduction in peak systolic velocity of the RV free wall on tissue Doppler in patients not surviving to sepsis compared with survivors.61,62

Vallabhajosyula et al.,63 in a historical cohort study of patients with severe sepsis or septic shock admitted to all intensive care units at Mayo Clinic between January 2007 and December 2014, showed that 55% of the patients met the diagnostic criteria for right ventricular dysfunction and, after adjustment for age, comorbidities, disease severity, presence of septic shock, and mechanical ventilation, concluded that the presence of right ventricular dysfunction was associated with worse survival at 1 year (risk ratio of 1.6, 95% confidence interval [95%CI] 1.2 - 2.1, p = 0.002).63 More recently, Orde et al.64 showed that right ventricular dysfunction was present in 32% of the patients with severe sepsis or septic shock evaluated by conventional echocardiography, and that this number rose to 72% when the evaluation was performed with speckle tracking; this “unmasked” dysfunction, especially when severe, was associated with a high mortality rate.64

Biomarkers and sepsis

Cardiac troponins (I and T) are important independent predictors of mortality in acute coronary syndrome without ST-segment elevation65 and other clinical conditions, such as end-stage renal disease,66 stroke,67 and pulmonary embolism.68

The elevation in troponin levels is relatively common in sepsis, occurring in approximately 60% of the patients;69 even though it is unclear why this happens, the manifestations of myocardial dysfunction that most correlated to the elevation in troponin levels have been recently demonstrated to be diastolic dysfunction and right ventricular dilation.44

The role of the troponins as a prognostic factor in sepsis is still under debate, with some studies70-72 having shown negative results in terms of increased mortality, and others concluded otherwise. John et al.73 showed a higher mortality at 28 days in patients with positive troponin I (32% versus 14%, p < 0.0001),73 while Vallabhajosyula et al.,74 in a retrospective cohort study, observed a relationship between troponin T elevation (≥ 0.01 ng/mL) on admission, in-hospital mortality (odds ratio [OR] 1.6, p = 0.003), and mortality at 1 year (OR 1.4, p = 0.04).74

BNP and NT-proBNP are two molecules secreted in response to atrial wall stretching and extensively used in the diagnosis and prognosis of heart failure. In the clinical context of sepsis, proinflammatory cytokines are believed to also exert an important role in the elevation of BNP levels. In vitro studies have shown the importance of interleukins 1 and 6 and TNF-α in inducing BNP secretion by cardiomyocytes,75,76 explaining the higher plasma concentrations of this biomarker even in individuals without heart failure, and its correlation with the levels of C-reactive protein, a traditional marker of inflammatory activity.77

In sepsis, the interpretation of increased levels of BNP and NT-proBNP can be hampered by the inflammation and other factors like age and renal insufficiency, although studies have demonstrated their importance as independent markers of mortality in this clinical scenario.77,78 Brueckmann et al.,79 for example, followed 57 patients diagnosed with severe sepsis and observed that patients with NT-proBNP levels > 1400 pmol/L showed a 3.9 times greater risk (relative risk [RR] 3.9, 95%CI 1.6 - 9.7) of dying from sepsis than patients with lower NT-proBNP values (p < 0.001).79 Khoury et al.80 studied 259 patients with sepsis and without cardiac failure and concluded using multivariate analysis that BNP is a strong predictor of in-hospital mortality at 90 days and 60 months, in addition to a better prognostic predictor than the Sepsis-related Organ Failure Assessment (SOFA) score for mortality at 90 days, and a better prognostic predictor of mortality at 60 months in low-risk groups.80

Final considerations

Evidence points to an association between myocardial dysfunction and sepsis as a relatively frequent event. The relationship between systolic dysfunction and mortality is still not defined, nor is the mechanism by which the diastolic dysfunction and the right ventricular dysfunction affect so adversely the evolution of patients with sepsis. There are no studies evaluating the effects of a differentiated strategy of treatment on the outcome of these patients. These gaps offer the opportunity for research and development of knowledge that can contribute to the treatment of such patients and, in the final analysis, improve their prognosis.

  • Sources of Funding
    There were no external funding sources for this study.
  • Study Association
    This article is part of the thesis of master submitted by Márcio da Silva Campista, from Universidade Federal Fluminense.
  • Ethics approval and consent to participate
    This article does not contain any studies with human participants or animals performed by any of the authors.

References

  • 1 Singer M, Deutschman CS, Seymour CW, Shankar-Hari M, Annane D, Bauer M, et al. The Third International Consensus definitions for sepsis and septic shock (Sepsis-3). JAMA. 2016;315(8):801-10.
  • 2 Court O, Kumar A, Parrillo J, Kumar A. Clinical review: myocardial depression in sepsis and septic shock. Crit Care. 2000;6(6):500-8.
  • 3 Bouhemad B, Nicolas-Robin A, Arbelot C, Arthaud M, Feger F, Rouby JJ. Isolated and reversible impairment of ventricular relaxation in patients with septic shock. Crit Care Med. 2008;36(3):766-74.
  • 4 Burns JR, Menapace FJ. Acute reversible cardiomyopathy complicating toxic shock syndrome. Arch Intern Med. 1982;142(5):1032-4.
  • 5 Zethelius B, Berglund L, Sundström J, Ingelsson E, Basu S, Larsson A, et al. Use of multiple biomarkers to improve the prediction of death from cardiovascular causes. N Engl J Med. 2008;358(20):2107-16.
  • 6 Kakihana Y, Ito T, Nakahara M, Yamaguchi K, Yasuda T. Sepsis-induced myocardial dysfunction: pathophysiology and management. J Intensive Care. 2016 Mar 23;4:22.
  • 7 Kumar A, Thota V, Dee L, Olson J, Uretz E, Parrillo JE. Tumor necrosis factor alpha and interleukin 1 beta are responsible for in vitro myocardial cell depression induced by human septic shock serum. J Exp Med. 1996;183(3):949-58.
  • 8 dos Santos CC, Gattas DJ, Tsoporis JN, Smeding L, Kabir G, Massom H, et al. Sepsis-induced myocardial depression is associated with transcriptional changes in energy metabolism and contractile related genes: a physiological and gene expression based approach. Crit Care Med. 2010;38(3):894-902.
  • 9 Cimolai MC, Alvarez S, Bode C, Bugger H. Mitochondrial mechanisms in septic cardiomyopathy. Int J Mol Sci. 2015;16(8):17763-78.
  • 10 Sharma AC, Motew SJ, Farias S, Alden KJ, Bosmann HB, Law WR, et al. Sepsis alters myocardial and plasma concentrations of endothelin and nitric oxide in rats. J Mol Cell Cardiol. 1997;29(5):1469-77.
  • 11 Stengl M, Bargak F, Sykora R, Chvojka J, Benes J, Krouzecky J, et al. Reduced L-type calcium current in ventricular myocytes from pigs with hyperdynamic septic shock. Crit Care Med. 2010;38(2):580-7.
  • 12 Kimmoun A, Levy B. Treatment of myocardial dysfunction in sepsis: the toll-like receptor antagonist approach. Shock. 2011;36(6):633-4.
  • 13 Gao M, Ha T, Zhang X, Liu L, Wang X, Kelley J, et al. Toll-like receptor 3 plays a central role in cardiac dysfunction during polymicrobial sepsis. Crit Care Med. 2012;40(8):2390-9.
  • 14 Silverman HJ, Penaranda R, Orens JB, Lee NH. Impaired beta-adrenergic receptor stimulation of cyclic adenosine monophosphate in human septic shock: association with myocardial hyporesponsiveness to catecholamines. Crit Care Med. 1993;21(1):31-9.
  • 15 Norbury WB, Jeschke MG, Herndon DN. Metabolism modulators in sepsis: propranolol. Crit Care Med. 2007;35(9 Suppl):S616-20.
  • 16 Cimolai MC, Alvarez S, Bode C, Bugger H. Mitochondrial mechanisms in septic cardiomyopathy. Int J Mol Sci. 2015;16(8):17763-78.
  • 17 Joseph L, Kokkinaki D, Valenti M, Kim G, Barca E, Tomar D, et al. Inhibition of NADPH oxidase 2 (NOX2) prevents sepsis-induced cardiomyopathy by improving calcium handling and mitochondrial function. JCI Insight. 2017;2(17). pii: 94248.
  • 18 Schmittinger CA, Dunser MW, Torgersen C, Luckner G, Lorenz I, Schmid S, et al. Histologic pathologies of the myocardium in septic shock: a prospective observational study. Shock. 2013;39(4):329-35.
  • 19 Celes MR, Prado CM, Rossi MA. Sepsis: going to the heart of the matter. Pathobiology. 2013;80(2):70-86.
  • 20 Parker MM, Shelhamer JH, Bacharach SL, Green MV, Natanson C, Frederick TM, et al. Profound but reversible myocardial depression in patients with septic shock. Ann Intern Med. 1984;100(4):483-90.
  • 21 Jardin F, Brun-Ney D, Auvert B, Beauchet A, Bourdarias JP. Sepsis-related cardiogenic shock. Crit Care Med. 1990;18(10):1055-60.
  • 22 Vieillard Baron a, Schmitt JM, Beauchet A, Augarde R, Prin S, Page B, et al. Early preload adaptation in septic shock? A transesophageal echocardiographic study. Anesthesiology. 2001;94(3):400-6.
  • 23 Vieillard-Baron A, Caille V, Charron C, Belliard G, Page B, Jardin F. Actual incidence of global left ventricular hypokinesia in adult septic shock. Crit Care Med. 2008;36(6):1701-6.
  • 24 Ognibene FP, Parker MM, Natanson C, Shelhamer JH, Parrillo JE. Depressed left ventricular performance. Response to volume infusion in patients with sepsis and septic shock. Chest. 1988;93(5):903-10.
  • 25 Narváez I, Canabal A, Martín C, Sánchez M, Moron A, Alcalá J, et al. Incidence and evolution of sepsis-induced cardiomyopathy in a cohort of patients with sepsis and septic shock. Med Intensiva. 2017 Oct 31. pii: S0210-5691(17)30237-1.
  • 26 De Geer L, Engvall J, Oscarsson A. Strain echocardiography in septic shock - a comparison with systolic and diastolic function parameters, cardiac biomarkers and outcome. Crit Care. 2015 Mar 26;19:122.
  • 27 Sevilla Berrios RA, O'Horo JC, Velagapudi V, Pulido JN. Correlation of left ventricular systolic dysfunction determined by low ejection fraction and 30-day mortality in patients with severe sepsis and septic shock: a systematic review and meta-analysis. J Crit Care. 2014;29(4):495-9.
  • 28 Fenton KE, Parker MM. Cardiac function and dysfunction in sepsis. Clin Chest Med. 2016;37(2):289-98.
  • 29 Parker MM, Shelhamer JH, Natanson C, Alling DW, Parrillo JE. Serial cardiovascular patterns in survivors and nonsurvivors of human septic shock: heart rate as an early predictor of prognosis. Crit Care Med. 1987;15(10):923-9.
  • 30 Repessé X, Charron C, Vieillard-Baron A. Evaluation of left ventricular systolic function revisited in septic shock. Crit Care. 2013;17(4):164.
  • 31 Antonucci E, Fiaccadori E, Donadello K, Taccone FS, Franchi F, Scolletta S. Myocardial depression in sepsis: from pathogenesis to clinical manifestations and treatment. J Crit Care. 2014;29(4):500-11.
  • 32 Boissier F, Razazi K, Seemann A, Bedet A, Thille A, de Prost N, et al. Left ventricular systolic dysfunction during septic shock: the role of loading conditions. Intensive Care Med. 2017;43(5):633-42.
  • 33 Poelaert J, Declerck C, Vogelaers D, Colardyn F, Visser CA. Left ventricular systolic and diastolic function in septic shock. Intensive Care Med. 1997;23(5):553-60.
  • 34 Bouhemad B, Nicolas-Robin A, Arbelot C, Arthaud M, Féger F, Rouby JJ. Isolated and reversible impairment of ventricular relaxation in patients with septic shock. Crit Care Med. 2008;36(3):766-74.
  • 35 Clancy D, Scully T, Slama M, Huang S, McLean A, Orde S. Application of updated guidelines on diastolic dysfunction in patients with severe sepsis and septic shock. Ann Intensive Care. 2017;7(1):121.
  • 36 Mejhert M, Persson H, Edner M, Kahan T. Epidemiology of heart failure in Sweden--a national survey. Eur J Heart Fail. 2001;3(1):97-103.
  • 37 Redfield MM, Jacobsen SJ, Burnett Jr JC, Mahoney DW, Bailey KR, Rodeheffer RJ. Burden of systolic and diastolic ventricular dysfunction in the community: appreciating the scope of the heart failure epidemic. JAMA. 2003;289(2):194-202.
  • 38 Flu WJ, van Kuijk JP, Hoeks SE, Kuiper R, Schouten O, Goei D, et al. Prognostic implications of asymptomatic left ventricular dysfunction in patients undergoing vascular surgery. Anesthesiology. 2010;112(6):1316-24.
  • 39 Mesquita ET, Socrates J, Rassi S, Villacorta H, Mady C. [Heart failure with preserved systolic function]. Arq Bras Cardiol. 2004;82(5):494-500.
  • 40 Bouhemad B, Nicolas-Robin A, Arbelot C, Arthaud M, Feger F, Rouby JJ. Acute left ventricular dilatation and shock-induced myocardial dysfunction. Crit Care Med. 2009;37(2):441-7.
  • 41 Sturgess DJ, Marwick TH, Joyce C, Jenkins C, Jones M, Masci P, et al. Prediction of hospital outcome in septic shock: a prospective comparison of tissue Doppler and cardiac biomarkers. Crit Care. 2010;14(2):R44.
  • 42 Landesberg G, Gilon D, Meroz Y, Georgieva M, Levin PD, Goodman S, et al. Diastolic dysfunction and mortality in severe sepsis and septic shock. Eur Heart J. 2012;33(7):895-903.
  • 43 Mourad M, Chow-Chine L, Faucher M, Sannini A, Brun JP, de Guibert JM, et al. Early diastolic dysfunction is associated with intensive care unit mortality in cancer patients presenting with septic shock. Br J Anaesth. 2014;112(1):102-9.
  • 44 Landesberg G, Jaffe AS, Gilon D, Levin PD, Goodman S, Abu-Baih A, et al. Troponin elevation in severe sepsis and septic shock: the role of left ventricular diastolic dysfunction and right ventricular dilatation. Crit Care Med. 2014;42(4):790-800.
  • 45 Rolando G, Espinoza E, Avid E, Welsh S, Del Pozo J, Vazquez R, et al. Prognostic value of ventricular diastolic dysfunction in patients with severe sepsis and septic shock. Rev Bras Ter Intensiva. 2015; 27(4):333-9.
  • 46 Sanfilippo F, Corredor C, Arcadipane A, Landesberg G, Vieillard-Baron A, Cecconi M, et al. Tissue Doppler assessment of diastolic function and relationship with mortality in critically ill septic patients: a systematic review and meta-analysis. Br J Anaesth. 2017;119(4):583-94.
  • 47 Vieillard-Baron A, Cecconi M. Understanding cardiac failure in sepsis. Intensive Care Med. 2014;40(10):1560-3.
  • 48 Ogata M, Ohe M, Katayose D, Takishima T. Modulatory role of EDRF in hypoxic contraction of isolated porcine pulmonary arteries. Am J Physiol. 1992;262(3 Pt 2):H691-7.
  • 49 Myers PR, Wright TF, Tanner MA, Adams HR. EDRF and nitric oxide production in cultured endothelial cells: direct inhibition by E. coli endotoxin. Am J Physiol. 1992;262(3 Pt 2):H710-8.
  • 50 Stewart DJ, Levy RD, Cernacek P, Langleben D. Increased plasma endothelin-1 in pulmonary hypertension: marker or mediator of disease? Ann Intern Med. 1991;114(6):464-9.
  • 51 Pittet JF, Morel DR, Hemsen A, Gunning K, Lacroix JS, Suter PM, et al. Elevated plasma endothelin-1 concentrations are associated with the severity of illness in patients with sepsis. Ann Surg. 1991;213(3):261-4.
  • 52 Herve P, Launay JM, Scrobohaci ML, Brenot F, Simonneau G, Petitpretz P, et al. Increased plasma serotonin in primary pulmonary hypertension. Am J Med. 1995;99(3):249-54.
  • 53 Sibbald W, Peters S, Lindsay RM. Serotonin and pulmonary hypertension in human septic ARDS. Crit Care Med. 1980;8(9):490-4.
  • 54 Boisser F, Katsahian S, Razazi K, Thille AW, Roche-Campo F, Leon R, et al. Prevalence and prognosis of cor pulmonale during protective ventilation for acute respiratory distress syndrome. Intensive Care Med. 2013;39(10):1725-33.
  • 55 Schneider AJ, Teule GJ, Groeneveld AB, Nauta J, Heidendal GA, Thijs LG. Biventricular performance during volume loading in patients with early septic shock, with emphasis on the right ventricle: a combined hemodynamic and radionuclide study. Am Heart J. 1988;116(1 Pt 1):103-12.
  • 56 Luecke T, Pelosi P. Clinical review: positive end-expiratory pressure and cardiac output. Crit Care. 2005;9(6):607-21.
  • 57 Pinsky MR. Cardiovascular issues in respiratory care. Chest. 2005;128(5 Suppl 2):592S-7S.
  • 58 Roosens CD, Ama R, Leather HA, Segers P, Sorbara C, Wouters PF, et al. Hemodynamic effects of different lung-protective ventilation strategies in closed-chest pigs with normal lungs. Crit Care Med. 2006;34(12):2990-6.
  • 59 Dhainaut JF, Lanore JJ, de Gournay JM, Huyghebaert MF, Brunet F, Villemant D, et al. Right ventricular dysfunction in patients with septic shock. Intensive Care Med. 1988;14 Suppl 2:488-91.
  • 60 Vincent JL, Reuse C, Frank N, Contempré B, Kahn RJ. Right ventricular dysfunction in septic shock: assessment by measurements using the thermodilution technique. Acta Anaesthesiol Scand. 1989;33(1):34-8.
  • 61 Harmankaya A, Akilli H, Gul M, Akilli NB, Ergin M, Aribas A, et al. Assessment of right ventricular functions in patients with sepsis, severe sepsis and septic shock and its prognostic importance: a tissue Doppler study. J Crit Care. 2013;28(6).1111.e7-1111e11.
  • 62 Furian T, Aguiar C, Prado K, Ribeiro RV, Becker L, Martinelli N, et al. Ventricular dysfunction and dilation in severe sepsis and septic shock: relation to endothelial function and mortality. J Crit Care. 2012;27(3).319.e9-15.
  • 63 Vallabhajosyula S, Kumar M, Pandompatam G, Sakhuja A, Kashyap R, Kashani K, et al. Prognostic impact of isolated right ventricular dysfunction in sepsis and septic shock: an 8-year historical cohort study. Ann Intensive Care. 2017;7(1):94.
  • 64 Orde SR, Pulido JN, Masaki M, Gillespie S, Spoon JN, Kane GC, et al. Outcome prediction in sepsis: speckle tracking echocardiography based assessment of myocardial function. Crit Care. 2014;18(4):R149.
  • 65 Heidenreich PA, Alloggiamento T, Melsop K, McDonald KM, Go AS, Hlatky MA. The prognostic value of troponin in patients with non-ST-elevation acute coronary syndromes: a meta-analysis. J Am Coll Cardiol. 2001;38(2):478-85.
  • 66 Dierkes J, Domrose U, Westphal S, Ambrosch A, Bosselmann HP, Neumann KH, et al. Cardiac troponin T predicts mortality in patients with end-stage renal disease. Circulation. 2000;102(16):1964-9.
  • 67 James P, Ellis CJ, Whitlock RM, McNeil AR, Henley J, Anderson NE. Relation between troponin T concentration and mortality in patients presenting with an acute stroke: observational study. BMJ. 2000;320(7248):1502-4.
  • 68 Giannitsis E, Muller-Bardorff M, Kurowski V, Weidtmann B, Wiegand U, Kampmann M, et al. Independent prognostic value of cardiac troponin T in patients with confirmed pulmonary embolism. Circulation. 2000;102(2):211-7.
  • 69 Innocenti F, Bianchi S, Guerrini E, Vicidomini S, Conti A, Zanobetti M, et al. Prognostic scores for early stratification of septic patients admitted to an emergency department-high dependency unit. Eur J Emerg Med. 2014;21(4):254-9.
  • 70 Tiruvoipati R, Sultana N, Lewis D. Cardiac troponin I does not independently predict mortality in critically ill patients with severe sepsis. Emerg Med Australas. 2012;24(2):151-8.
  • 71 Brivet F, Jacobs F, Colin P, Prat D, Grigoriu B. Cardiac troponin level is not an independent predictor of mortality in septic patients requiring medical intensive care unit admission. Crit Care. 2006;10(1):404.
  • 72 Muskoyama M, Nakao K, Hosada K, Suga S, Saito Y, Ogawa Y, et al. Brain natriuretic peptide as novel cardiac hormone in humans. Evidence for an exquisite dual natriuretic peptide system, atrial natriuretic peptide and brain natriuretic peptide. J Clin Invest. 1991;87(4):1402-12.
  • 73 John J, Woodward DB, Wang Y, Yan SB, Fisher D, Kinasewitz GT, et al. Troponin-I as a prognosticator of mortality in severe sepsis patients. J Crit Care. 2010;25(2):270-5.
  • 74 Vallabhajosyula S, Sakhuja A, Geske J, Kumar M, Poterucha J, Kashyap R, et al. Role of admission troponin-T and serial troponin-T testing in predicting outcomes in severe sepsis and septic shock. J Am Heart Assoc. 2017;6(9). pii: e005930.
  • 75 Thaik CM, Calderone A, Takahashi N, Colucci WS. Interleukin-1ß modulates growth and phenotype of neonatal rat cardiac myocytes. J Clin Invest. 1995;96(2):1093-9.
  • 76 Ma KK, Ogawa T, de Bold AJ. Selective upregulation cardiac brain natriuretic peptide at transcriptional and translational levels by pro-inflammatory cytokines and by conditioned medium derived from mixed lymphocyte reactions via p38 MAP kinase. J Mol Cell Cardiol. 2004;36(4):505-13.
  • 77 Rivers E P, McCord J, Otero R, Jacobsen G, Loomba M. Clinical utility of B-type natriuretic peptide in early severe sepsis and septic shock. J Intensive Care Med. 2007;22(6):363-73.
  • 78 Kandil E, Burack J, Sawas A, Bibawy H, Schwartzman A, Zenilman ME, et al. B-type natriuretic peptide: a biomarker for the diagnosis and risk stratification of patients with septic shock. Arch Surg. 2008;143(3):242-6.
  • 79 Brueckmann M, Huhle G, Lang S, Haase KK, Bertsch T, Weiss C, et al. Prognostic value of plasma N-terminal pro-brain natriuretic peptide in patients with severe sepsis. Circulation. 2005;112(4):527-34.
  • 80 Khoury J, Arow M, Elias A, Makhoul B, Berger G, Kaplan M, et al. The prognostic value of brain natriuretic peptide (BNP) in non-cardiac patients with sepsis, ultra-long follow-up. J Crit Care. 2017 Dec;42:117-122.

Publication Dates

  • Publication in this collection
    19 July 2018
  • Date of issue
    Nov-Dec 2018

History

  • Received
    07 Sept 2017
  • Reviewed
    04 Jan 2018
  • Accepted
    16 Jan 2018
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