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Pathophysiology, echocardiographic evaluation, biomarker findings, and prognostic implications of septic cardiomyopathy: a review of the literature

Abstract

Background

Sepsis is a common condition encountered by emergency and critical care physicians, with significant costs, both economic and human. Myocardial dysfunction in sepsis is a well-recognized but poorly understood phenomenon. There is an extensive body of literature on this subject, yet results are conflicting and no objective definition of septic cardiomyopathy exists, representing a critical knowledge gap.

Objectives

In this article, we review the pathophysiology of septic cardiomyopathy, covering the effects of key inflammatory mediators on both the heart and the peripheral vasculature, highlighting the interconnectedness of these two systems. We focus on the extant literature on echocardiographic and laboratory assessment of the heart in sepsis, highlighting gaps therein and suggesting avenues for future research. Implications for treatment are briefly discussed.

Conclusions

As a result of conflicting data, echocardiographic measures of left ventricular (systolic or diastolic) or right ventricular function cannot currently provide reliable prognostic information in patients with sepsis. Natriuretic peptides and cardiac troponins are of similarly unclear utility. Heterogeneous classification of illness, treatment variability, and lack of formal diagnostic criteria for septic cardiomyopathy contribute to the conflicting results. Development of formal diagnostic criteria, and use thereof in future studies, may help elucidate the link between cardiac performance and outcomes in patients with sepsis.

Background

Septic cardiomyopathy (SC) is often diagnosed when some acute perturbation in cardiac function exists in the setting of sepsis. At present, no formalized or consensus definition of SC exists, representing a critical knowledge gap. Complexity of the cardiovascular system, myriad methods of assessment, and variations in the pre-septic state of the heart make elucidation of a cause-and-effect relationship difficult.

SC has been recognized for 40 years [1, 2] and may be present in up to 44% of patients [3, 4], but it remains incompletely understood. While results are varied, some studies suggest that mortality is two to three times greater when SC is present [5, 6]. Understanding how the heart behaves is critical when making treatment decisions for septic patients. For example, aggressive fluid resuscitation has been integral in the treatment of sepsis for nearly two decades, but recent literature suggests that excessive fluid resuscitation is deleterious in some patients [7, 8]. Variations in myocardial performance could explain, at least in part, these observed differences.

Early studies utilized invasive assessment methods or radionuclide imaging [4, 9]; while providing a plethora of data, these techniques are of limited utility to emergency and critical care physicians given that they cannot be performed at the point-of-care and are difficult to repeat.

Echocardiography, however, is widely available, non-invasive, and easily repeatable, making it an optimal modality for evaluation of SC. Measurement of serum cardiac biomarkers provides separate, but related, information about the state of the heart [10] and thus may be complementary to echocardiographically derived data.

The purpose of this article is to review the extant literature on SC, with a focus on the evaluation and prognostic implications of various echocardiographic and laboratory measures thereof.

Pathophysiology

The pathophysiologic cascade of sepsis begins when the host immune system responds to an invading pathogen, resulting in activation of the innate immune response [11]. This culminates in the generation and release of pro-inflammatory mediators and signaling molecules that may be physiologic (beneficial) or pathologic (harmful) to the host; concomitant release of anti-inflammatory mediators occurs as well. These molecules, acting through varied signal transduction pathways, which in some cases alter gene expression, activate both positive and negative feedback loops within the immune system [12]. Recent advances in oxidative lipidomics have identified products of upstream lipid metabolism that are involved in the initiation (eicosanoids) and recovery phases (lipoxins, resolvins) [13]. Sepsis-induced dysregulation of the normal immune response can lead to a variety of deleterious effects, including SC, multi-system organ failure, and ultimately death in some patients [5] .

Septic shock is often classified as a type of “distributive” shock—relative hypovolemia resulting from maldistribution of circulating volume due to peripheral vasodilation, glycocalyx dysfunction, and increased capillary permeability. It has also been described as a biphasic disorder with an early, hyperdynamic phase (high cardiac output (CO), low systemic vascular resistance (SVR), warm extremities) and a late, hypodynamic phase (low CO, poor perfusion) [5, 6]. Circulating inflammatory mediators are believed to be the causative agents, acting directly on cardiomyocytes and the peripheral vasculature, which affects myocardial performance via alterations in SVR and venous return.

While preload augmentation has long been a primary intervention for sepsis and can increase CO via the Frank-Starling mechanism, its ability to do so depends on the functional state of the heart. However, measures of preload, such as central venous pressure (CVP) and inferior vena cava (IVC) dimensions, provide limited information on underlying cardiac function. Even when volume responsiveness is suggested by low CVP, increased respiratory variation of IVC diameter, or other invasive methods, guidance of resuscitation based on these measures has not been found to improve outcomes [14,15,16].

Changes in afterload also affect the ability of the heart to deliver blood to the peripheral tissues. Thus, a heart with poor intrinsic contractility may be able to increase CO when SVR is low—thereby giving the impression of normal function—when in fact systolic performance is impaired. This dysfunction may only become apparent when SVR returns to normal via natural (recovery from sepsis) or artificial means (vasopressor use). Boissier et al. [17] demonstrated such an inverse relationship between ejection fraction and SVR in septic patients.

An early hypothesis, based on animal models, was that SC was caused by global myocardial ischemia resulting from decreased coronary blood flow [18]. Subsequent investigation, including human studies, showed preserved or increased coronary perfusion in some septic patients [19]. Derangements in cardiomyocyte physiology are still believed to play a role, but at the microcirculatory, rather than the macrocirculatory, level [20]. Inflammatory molecules are thought to be responsible for this via pleiotropic effects [5]. Damage occurs via changes in endothelial permeability, leading to edema, increased neutrophil transduction into the interstitium, fibrin deposition, and in some cases, activation of the coagulation cascade [21]. Increased oxidative stress may induce mitochondrial dysfunction and disruption of normal calcium handling [22]—critical events given the high-energy demands of cardiac tissue. The exact mechanism that culminates in cardiac dysfunction is not clear; one theory posits that myocardial edema leads to disruption or malfunction of the contractile apparatus [23]. Autonomic dysregulation leading to decreased expression of adrenergic receptors and thus resistance to endogenous catecholamines may also be present [22]. Figure 1 illustrates the complex interactions between host and pathogen factors that contribute to the development of SC.

Fig. 1
figure 1

Pathophysiology of septic myocardial dysfunction. IL interleukin, iNOS induced nitric oxide synthase, PMN polymorphonuclear cell, TNF tumor necrosis factor

Despite such pathology, a cardinal feature of SC is its apparent reversibility, with many studies reporting that patients’ cardiac function recovered fully to their pre-morbid state [1, 5, 20, 24]. Cardiac magnetic resonance has detected changes suggesting myocardial edema or an altered metabolic state, a pattern distinct from that seen with ischemia and necrosis, the former being consistent with reversibility [25]. Thus, some theorize that SC represents a protective “hibernating” state [26], as has been demonstrated in subsets of patients with acute myocardial ischemia [27]. A reversible—and incompletely understood—takotsubo pattern has also been described in septic patients. The physiologic stresses of sepsis are thought to play a role, but its place within the SC continuum is not clear given the paucity of extant data [28].

Echocardiography: diagnosis and prognosis

A summary of the echocardiographic parameters that have been used in the evaluation of SC, and their limitations, is listed in Table 1. Table 2 summarizes the literature on echocardiography in SC discussed in the ensuing sections. According to GRADE guidelines [29], the quality of evidence on this topic is “low” or “very low”. A summary of the major limitations within the literature on septic cardiomyopathy is provided in Table 3.

Table 1 Summary of echocardiographic variables that have been used to evaluate septic cardiomyopathy
Table 2 Summary of selected articles on septic cardiomyopathy
Table 3 Gaps and general limitations of the septic cardiomyopathy literature

Left ventricle: systolic function

Ejection fraction

Systolic dysfunction, as measured by left ventricular ejection fraction (LVEF), was one of the first described parameters to assess for SC. Parker et al., in 1984 [1], reported that approximately 50% of their patients with septic shock had reduced LVEF. Counter-intuitively, they found low mean LVEF amongst survivors compared to non-survivors. Jardin et al. confirmed these findings [24] and further reported that LV parameters were unaffected by fluid-loading in non-survivors. Unfortunately, several follow-up studies found no difference in LVEF between survivors and non-survivors of septic shock [30, 31]. Two recent meta-analyses that included 1247 patients failed to find any meaningful relationship between LV parameters and mortality in septic shock [32, 33].

Global longitudinal strain

Strain imaging is a novel technique based on regional myocardial deformation. The most frequently used strain parameter is global longitudinal strain (GLS), which represents the mean longitudinal strain value from each segment of the LV [34].

Most commonly, GLS is calculated using speckle-tracking echocardiography (STE) [35]. STE is a semi-automated, post-processing computer algorithm that tracks user-selected regions of the myocardium (“speckles”) during the cardiac cycle. As fibers contract during systole, speckles move closer together, represented by negative values. Larger negative values represent greater deformation in systole and thus improved LV function (Fig. 2).

Fig. 2
figure 2

a Speckle-tracking analysis of a patient with normal systolic left ventricular (LV) function. 2D image showing speckles within the LV being tracked by the ultrasound Machine Software (A). Graphical representation of movement of speckles throughout the cardiac cycle (x-axis, longitudinal strain; y-axis, time in msec), with each line representing a different segment of the LV; large negative values represent movement of speckles towards one another during contraction representing normal function (B). Bullseye map showing global longitudinal strain values throughout the LV (C). b Speckle-tracking analysis of a patient with severely reduced left ventricular (LV) systolic function. A 2D image showing speckles within the LV being tracked by the ultrasound machine software (A). Graphical representation of movement of speckles throughout the cardiac cycle (x-axis, longitudinal strain; y-axis, time in msec) with each line representing a different segment of the LV; note smaller negative values with variable time to peak strain representing reduced LV function with mechanical dyssynchrony (B). Bullseye map showing global longitudinal strain values throughout the LV; blue zones represent areas of the LV where there is lengthening of the segments during systole rather than shortening (C)

Strain imaging has the ability to detect subtle changes in LV systolic function prior to decline in LVEF [36]. A meta-analysis by Kalam et al. found that GLS was a better predictor of adverse outcomes, including mortality, than LVEF patients with heart failure and other cardiac diseases [37]. Ng et al. [38] found that patients with septic shock had more LV dysfunction, as measured by GLS, than matched controls with sepsis but without shock. Chang et al. [39] prospectively enrolled 111 ICU patients with septic shock. LVEF was similar between in-hospital survivors and non-survivors, but GLS was significantly better in survivors compared to non-survivors, with an even greater difference for ICU mortality [39]. Palmieri et al. [40] reported similar findings. When dichotomized to “normal” (< − 14%) or “abnormal”, Innocenti et al. [41] reported lower mortality at 7 and 28 days for those with normalized GLS.

Conversely, Orde et al. [42] found that although a greater number of patients had LV dysfunction identified by STE than LVEF (69 versus 33%), there was no difference in GLS between survivors and non-survivors at 30 days or 6 months; De Geer et al. [43] also found no difference or improvement in GLS between survivors and non-survivors at 30 and 90 days. Finally, Zaky et al. [44] reported similar strain values in survivors and non-survivors; however, apical segments were excluded from their strain analysis, making interpretation of these results somewhat difficult. In terms of feasibility of performing STE in septic patients, studies have reported exclusion rates for poor image quality from 1.5–20% [40,41,42,43, 45, 46]. De Geer et al. [46] found GLS to be the most reproducible measure for assessing cardiac function in patients with septic shock, with intraclass correlation coefficients for inter- and intraobserver variability of 0.91 (0.74–0.95, p < 0.001), and 0.89 (0.55–0.97, p = 0.002), respectively.

Other considerations

Systolic function can also be assessed using tissue Doppler imaging (TDI)-derived velocity of the mitral annulus or by mitral annular plane systolic excursion (MAPSE). Peak systolic velocity of the mitral annulus, denoted S′, has been shown to have prognostic value in a variety of cardiovascular illnesses [47] and is relatively afterload-independent [17]. MAPSE is the linear distance the mitral annulus moves towards the LV apex during systole and has demonstrated similar utility [48].

The evidence with regard to the utility of these variables in septic patients is conflicting. Weng et al. [49] found a linear correlation between S′ and LVEF in septic shock, and that non-survivors had higher S′ than survivors; Boissier et al. [17] reported similar findings. A study of septic patients with LVEF > 50% also noted lower S′ in survivors compared to non-survivors [50]. Conversely, Chang et al. [39] found no association between S′ and ICU or in-hospital mortality.

Left ventricle: diastolic function

In the absence of infiltrative or restrictive cardiac disease, diastole is the main determinant of LV compliance [51]. While initially low in SC, regardless of systolic function, as diastolic function worsens, left ventricular end-diastolic pressure (LVEDP) can rise. Preload augmentation, via increased left ventricular end-diastolic volume, can lead to further elevation in LVEDP—Brown et al. [52] found that diastolic dysfunction (DD) was more common in patients administered larger volumes of IVF. Mahjoub et al. [53] reported less increase in LVEDP in volume-responsive septic patients than in non-responders, demonstrating the varied effects of IVF-loading, depending on underlying cardiac function. A putative explanation of the detrimental effects of DD in sepsis is that elevated left-sided pressure increases pressure in the pulmonary circulation, the right heart, and the peripheral tissues, which leads to increases in extravascular lung water (EVLW) and tissue edema.

The preferred method for evaluation of diastolic function is TDI-derived velocity of the mitral annuls during early diastole (e’), with lower values corresponding to worse diastolic function [51]. The ratio of the peak trans-mitral inflow velocity in early diastole (E) to early diastolic mitral annular velocity (E/e’) has been found to correlate with left-atrial pressure—a surrogate for pulmonary capillary wedge pressure [51]; higher values reflect increased pressure.

Prognostic ability of E/e’ and e’ have been evaluated in septic patients, with conflicting results. Three studies reported lower e’ in non-survivors compared to survivors [54,55,56]; two others found that elevated E/e’ was an independent predictor of in-hospital mortality [56, 57]. A 2015 meta-analysis [58] of 636 patients found a prevalence of DD of 20–57% and a relative risk of death of 1.82 (1.12–2.97, p = 0.002; I2 = 77%). A 2017 update [59], of 1507 patients, found lower lateral e’ and higher E/e’ amongst non-survivors. Interestingly, Brown et al. [52] found increased mortality only for patients with low-grade DD (impaired relaxation with minimally elevated LVEDP); however, these patients received significantly less fluid than those with more severe DD—2.6 versus 5.5 l—prior to the initial echocardiogram and thus they may have been inadequately resuscitated. While e’ is considered to be relatively preload independent [51], this latter finding suggests there is a link between fluid loading and derangement in diastolic function. In contrast, several other studies failed to detect an association between DD and mortality (early or late—up to 1 year) in severe sepsis and septic shock [30, 31, 39, 43, 49].

Lanspa et al. [60] found better feasibility of a simplified diastolic evaluation compared to the 2009 American Society for Echocardiography (ASE) guidelines, without loss of predictive value (see Tables 1 and 2 for further details).

Right ventricle

Dysfunction of the right ventricle (RV) contributes to morbidity and mortality in a variety of conditions, including heart failure and pulmonary hypertension [61, 62]. Tricuspid annular plane systolic excursion (TAPSE) is the easiest and most reproducible measure of RV function [63]. Reduced TAPSE has been correlated with increased mortality in critical illness [64] and detected in septic ICU patients when compared to non-septic ICU controls [38, 65]. Whether RV dysfunction is a manifestation of disease severity—and thus associated with poor outcomes—or a causative factor of morbidity and mortality is unknown. Contributors to RV dysfunction include LV dysfunction, hypoxia, hypercarbia, mechanical ventilation with high positive end-expiratory pressure, atelectasis, and fluid overload [42, 62]. Pulmonary hypertension induced (or exacerbated by) acute respiratory distress syndrome or pulmonary sources of sepsis can also contribute to RV dysfunction; isolated RV dysfunction may be more common in patients with these conditions compared to those without.

Reported prevalence of RV dysfunction in sepsis varies, from 31 to 83% [31, 57]. As with other echocardiographic variables, investigation of RV parameters has produced conflicting results. Traditional parameters of increased RV size and dysfunction have been associated with increased mortality in some studies [55, 66], but not others [31, 39, 54, 57]. A retrospective study of 388 septic ICU patients [67] found isolated RV dysfunction to be an independent predictor of 1-year mortality; combined RV/LV dysfunction showed no such relationship. A meta-analysis of 412 patients found no association between RV function and mortality [32]. Orde et al. [42] reported that reduced RV free wall strain (by STE) was associated with 6-month mortality (− 16.0 ± 5.7 versus − 19.3 ± 4.9, p ≤ 0.05); these results are promising but require validation.

Biomarkers

Abnormal cardiac biomarkers, primarily troponin and natriuretic peptides (NPs), are another potential indicator of myocardial dysfunction that provide unique but related information about the heart [10]. Troponin elevation in the setting of sepsis may reflect altered cardiomyocyte permeability or necrosis from vascular injury rather than atherosclerotic disease [68], but determining whether it is related to SC or another condition (e.g., renal disease) is difficult.

Contemporary troponin assays (cTnI, cTnT) have been studied in septic patients, with concentrations generally rising with increasing disease severity; short-term non-survivors often have greater elevations than survivors [10, 69], but the results are not uniform [70]. Vallabhajosysula et al. [71] reported that, in septic ICU patients, elevated TnT on admission was associated with higher in-hospital and 1-year mortality compared to patients whose TnT was not elevated; no such associations were found for elevated ΔTnT. High-sensitivity troponin (hsTnT) has also been reported to rise with increasing severity of sepsis, but with unclear prognostic implications: Rosjo et al. [70] reported greater hsTnT elevation in non-survivors, but no independent association with mortality; Masson et al. [72] found that an elevated hsTnT on day 7 (but not day 1) and a > 20% rise from day 1 to day 2 were associated with increased mortality.

B-type NP (BNP), which is released in response to wall stress, reflects myocardial loading conditions and provides indirect functional information—as the heart moves towards the unfavorable portion of the Frank-Starling curve, wall stress, and BNP, rise [73, 74]. As with BNP, amino-terminal pro-BNP (NT-proBNP) may be elevated in sepsis, particularly with increasing disease severity, and is more likely to be elevated in non-survivors compared to survivors [69, 72,73,74,75]. In one study, NT-proBNP was a better predictor of 90-day mortality than hsTnT [72]. Concomitant study of biomarkers and echocardiographic variables has not produced reliable results. No associations have been found between LV systolic function and contemporary troponin assays [31, 44]; one study reported an inverse relationship between LVEF and hsTnT [54], another found a weak association between hsTnT and declining GLS (r = 0.35) [43], and a third found no relationship [55]. Dilation of the RV and LV DD have been variably associated, with direct correlations for cTnT, hsTnT, and NT-proBNP in some studies [54, 55, 76], but not in others [31]. Sturgess et al. [56] found that E/e’ > 15 was a better predictor of in-hospital mortality than TnT or NTproBNP.

Some of this variability may be due to the fact that cardiac biomarker concentrations above the reference range are common in sepsis, with prevalence as high as 84% for cTnT [77], 98% for NT-proBNP [75], and 100% for hsTnT [70]. Existing data are limited by residual confounding from clinical contributors, including age, disease severity, comorbidities (including flow-limiting CAD), and treatment. Pending future studies, existing information on cardiac biomarkers can be summarized by noting that abnormalities in the setting of sepsis are likely, but such abnormalities, in and of themselves, do not equate to a diagnosis of SC, nor do they provide clear, independent prognostic information.

Implications for treatment

Currently, no treatment recommendations exist that specifically address the presence of SC. Patients with SC may be at greater risk for excessive fluid resuscitation and more likely to require inotropic support, as hypoperfusion would less likely be corrected by IVF administration alone. However, data comparing use of vasopressors, inotropes, and other treatments in patients with and without SC are scant and subject to extensive confounding. Where treatment data are stratified by presence or absence of SC [31, 44, 52, 78], only two found significant differences between groups. Brown et al. [52] found that patients with less severe DD received less IVF than those with more significant abnormalities (2.6 versus 5.5 l). Pulido et al. [31] reported higher doses of noradrenaline (norepinephrine) in patients with LV and RV systolic dysfunction, but no overall difference in the number of patients receiving it. Establishment of a standardized, objective definition of SC and adoption of more uniform study protocols amongst research groups would improve understanding of differences in treatment requirements for patients with SC.

Positive inotropic agents have the same putative benefits of vasopressors—increasing CO, thereby improving oxygen delivery to the peripheral tissues. Recommendations to titrate therapy to central venous oxygen saturation > 65% are of uncertain utility, as a normal value does not necessarily indicate adequate resuscitation [79]. Furthermore, excessive β stimulation may be harmful, and there is some evidence that β-blockade may be beneficial in some patients [80]. Preliminary trials of levosimendan, a calcium sensitizer and positive inotrope, reported reduced mortality [81], but no benefit was found in a subsequent larger study [82].

Conclusions

SC is a multi-factorial process that involves complex interactions between host and pathogen factors, and a full understanding of the disease process remains elusive. Prognostic implications of echocardiographic and biomarker findings are precluded by conflicting data from extant literature. Formal diagnostic criteria for SC do not exist; development of these, and studies based thereon, should be priorities for future research.

Abbreviations

ASE:

American society of echocardiography

BNP:

B-type natriuretic peptide

CAD:

Coronary artery disease

CI:

Confidence interval

CO:

Cardiac output

cTnT/cTnI:

Contemporary troponin T/I

CVP:

Central venous pressure

DT:

Mitral inflow deceleration time

EDV:

End diastolic volume

ESV:

End systolic volume

GLPS:

Global longitudinal peak strain

GLS:

Global longitudinal strain

HR:

Hazard ratio

hsTnT:

High-sensitivity troponin T

ICU:

Intensive care unit

IVC:

Inferior vena cava

LAVI:

Left atrial volume index

LV:

Left ventricle

LVEF:

Left ventricular ejection fraction

MAPSE:

Mitral annular plane systolic excursion

msec:

Millisecond

NP:

Natriuretic peptide

NT pro-BNP:

Amino-terminal pro-BNP

OR:

Odds ratio

Sa:

Tissue doppler velocity measurement of mitral annulus

SC:

Septic cardiomyopathy

SN:

Sensitivity

SP:

Specificity

STE:

Speckle tracking echocardiography

SVR:

Systemic vascular resistance

TDI:

Tissue doppler imaging

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Acknowledgements

The authors would like to acknowledge Daniel Foley, BS for the creation of Fig. 1.

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RE and PL conceived the article; AS created the tables; CR created the conceptual framework of Fig. 1 and provided basic science expertise for the pathophysiology section; all of the authors contributed substantially to drafting and revising the manuscript and have given final approval of the submitted draft; RE takes responsibility for the manuscript as a whole.

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Correspondence to Robert R. Ehrman.

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Competing interests

PL received consulting fees from the following companies/organizations: Novartis Pharmaceuticals, Cardiorentis Inc., Trevena Inc., Apex Innovations, Roche Diagnostics, Siemens, Shire, Sciex. PL received consulting fees from the following institutions/organizations: Novartis Pharmaceuticals, Cardiorentis Inc., Trevena Inc., Amgen, BMS, Edwards Lifesciences, AHRQ (1 R01 HS025411), NHLBI (1 R34 HL136986 and 5 R01 HL127215), NIH Admin (1 U24 NS100680), PCORI (FC14-1409-21,656), Blue Cross Blue Shield of MI Foundation. The other authors have no competing interests.

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Ehrman, R.R., Sullivan, A.N., Favot, M.J. et al. Pathophysiology, echocardiographic evaluation, biomarker findings, and prognostic implications of septic cardiomyopathy: a review of the literature. Crit Care 22, 112 (2018). https://0-doi-org.brum.beds.ac.uk/10.1186/s13054-018-2043-8

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