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01.12.2016 | Research | Ausgabe 1/2016 Open Access

Annals of Intensive Care 1/2016

Prognostic impact of left ventricular diastolic function in patients with septic shock

Zeitschrift:
Annals of Intensive Care > Ausgabe 1/2016
Autoren:
Céline Gonzalez, Emmanuelle Begot, François Dalmay, Nicolas Pichon, Bruno François, Anne-Laure Fedou, Catherine Chapellas, Antoine Galy, Claire Mancia, Thomas Daix, Philippe Vignon

Background

Septic shock remains the leading cause of death in the intensive care unit (ICU), with an increasing incidence and a current mortality of approximately 30 % [13]. Many experimental and clinical studies extensively documented the presence of a reversible sepsis-induced cardiomyopathy which involves the systolic and diastolic functions of both ventricles [47]. The pathophysiology of septic cardiomyopathy is complex [8], and its prognostic impact remains controversial [911].
Heart failure with preserved ejection fraction is highly prevalent in the general population and associated with a high morbidity and mortality [12, 13]. In ICU patients, left ventricular (LV) diastolic dysfunction is frequently depicted using Doppler echocardiography [14]. Specifically, reversible abnormal LV relaxation has been reported during the early phase of septic shock [15, 16]. A recent meta-analysis suggests that LV diastolic dysfunction is associated with the mortality of severe sepsis and septic shock [17]. However, this meta-analysis suffered from substantial limitations. First, the size of study populations varied greatly, leading to a wide range of prevalence of LV diastolic dysfunction (20–57 %). Second, two cohorts involved two-third of the global population included in the meta-analysis and were enrolled by the same investigating center [9, 18]. Third, the studied population was heterogeneous since patients were hemodynamically assessed for either a severe sepsis or a septic shock [17]. Accordingly, we sought to assess the potential impact of LV diastolic function on ICU survival in a population of septic shock patients, with respect to other known prognostic factors.

Methods

This descriptive, retrospective, single-center study was approved by our institutional ethics committee which waived the need for informed consent.

Study population

Patients were eligible if (1) they were hospitalized in the Medical–Surgical ICU of Limoges University Hospital between December 2009 and December 2014 with a septic shock; (2) they were hemodynamically assessed using transthoracic (TTE) or transesophageal echocardiography (TEE) within the first 24 h of shock, and (3) digital recording of the echocardiographic examination was available for off-line measurements. Patients’ characteristics on ICU admission, comorbidities assessed by the Charlson’s score [19] and severity scores including the Simplified Acute Physiology Score (SAPS) II score [20] and the Sequential Organ Failure Assessment (SOFA) score [21] were recorded. In each patient, the following information was retrieved from electronic medical records or paper charts, as required: site of infection, time lag between the development of septic shock and the first administration of antibiotic therapy, appropriateness of initial antibiotic therapy and volume of fluids administered prior to hemodynamic assessment. During the ICU stay, the following parameters were recorded: maximal dose of catecholamines, use of substitutive steroids therapy, invasive mechanical ventilation and renal replacement therapy. At the time of septic shock diagnosis, the following biological values were obtained: pH, PaO2/FiO2 ratio, lactate, platelet count, serum creatinine, bilirubin, alanine aminotransferase and the presence of a disseminated intravascular coagulation [22]. Dobutamine was administered in the presence of severe LV systolic dysfunction without fluid responsiveness but persisting signs of tissue hypoperfusion, and no patient received beta-blockers, milrinone or levosimendan.

Definitions

Sepsis was defined by the presence of at least two criteria of systemic inflammatory response syndrome associated with a clinically or microbiologically documented, or a highly suspected infection. Severe sepsis was defined as a sepsis associated with at least one organ failure different from that responsible for the infection. Septic shock was defined as a severe sepsis associated with low blood pressure despite adequate vascular filling which required a vasopressor support [23, 24]. The onset of septic shock was defined by the time of the first occurrence of recurrent or persistent hypotension (systolic blood pressure <90 mmHg or mean blood pressure <65 mmHg) despite adequate fluid loading (i.e., at least 30 mL/kg) [24]. Appropriateness of initial antibiotic therapy referred to the susceptibility of isolated microorganism rather than the time lag prior to its initiation. Previously determined rules to evaluate appropriateness of initial antibiotic therapy have been followed [25, 26]. Antibiotic therapy was considered appropriate if the first-line treatment included at least one antibiotic active in vitro on the isolated microorganism. When no microorganism was found, the antibiotic therapy was considered appropriate if it was in accordance with broadly accepted guidelines for the expected site infection [25]. This information was recorded by an independent investigator who was unaware of patients’ outcome.

Echocardiography

Hemodynamic assessment was performed by experienced intensivists highly trained in critical care echocardiography [27]. We perform TEE examination in all ventilated patients with septic shock and no contraindication for esophageal intubation, in conjunction with TTE for tissue Doppler assessment as a standard of care. All measurements were performed on a dedicated workstation (Xcelera™, Philips) by an independent expert who was unaware of patients’ data and outcome.
In the four-chamber view, the following echocardiographic parameters were measured: LV ejection fraction (EF) calculated conventionally from both the LV end-diastolic volume (LVEDV) and LV end-systolic volume (LVESV) using the monoplane modified Simpson’s rule [28]; maximal velocity of mitral Doppler E and A waves recorded at the tip of valvular leaflets, and E/A ratio (sinus rhythm); tissue Doppler imaging E′ wave maximal velocity measured on the lateral mitral annulus, and lateral E/E′ ratio [29]; right ventricular (RV) and LV end-diastolic area ratio (RVEDA/LVEDA) [30]. Pulse wave Doppler velocity–time integral of LV outflow tract (LVOT VTI) was measured in the apical five-chamber view or in the 120° transgastric view to indirectly assess LV stroke volume. The collapsibility index of the superior vena cava (ΔSVC) was measured using TEE M-mode in the long-axis view of the great vessels to assess fluid responsiveness [31]. A potential paradoxical motion of the interventricular septum was identified in the short-axis view of the heart. Its association with RV dilatation (i.e., RVEDA/LVEDA > 0.6) defined acute cor pulmonale [30].
LV diastolic dysfunction was defined by the presence of a lateral E′ maximal velocity <10 cm/s [32]. LV dilatation was defined by an indexed LV end-diastolic volume (LVEDVi) >75 ml/m2, irrespective of gender [28].

Statistical analysis

Results are presented as means ± standard deviations and percentages. Quantitative variables were compared between patients who died in the ICU and patients who were discharged alive using Student’s t test or Mann and Whitney’s test when data were not normally distributed. Qualitative variables were compared between groups using the χ 2 test or Fisher’s exact test, when necessary.
A stepwise multivariate logistic regression analysis was performed to identify independent variables associated with ICU mortality. All variables with a p value <0.20 in the univariate analysis were incorporated into the model. The significance of parameters which remained in the final model was tested after adjusting for the SAPS II score. Odds ratio and their 95 % confidence intervals (CI) were determined. To assess the potential impact of the severity of LV diastolic dysfunction on prognosis, patients were divided based on quartiles of lateral E′ maximal velocity. A two-tailed p value <0.05 was considered statistically significant.

Results

Five hundred and forty patients were admitted to our ICU with a septic shock during the study period. In 304 of them (56 %), echocardiography was not available due to the absence of digital recordings or to a low image quality precluding accurate measurements, and 12 patients (2 %) failed to meet all diagnostic criteria of septic shock. Finally, 223 patients were included into the study (140 men [63 %]; age 64 ± 13 years; SAPS II 55 ± 18; SOFA 10 ± 3; Charlson 3.5 ± 2.5) and 204 of them (91 %) were under invasive mechanical ventilation. The source of infection was documented in 185 patients (83 %), and a bacteremia was identified in 85 patients (38 %). Sepsis originated from intra-abdominal infection in 87 patients (39 %), a pulmonary infection in 48 patients (22 %), an urogenital infection in 37 patients (17 %) and a skin or joint and bones infection in 12 patients (5 %). Seventy-eight patients died in the ICU, accounting for a 35 % mortality rate.
When compared with survivors, patients who died in the ICU had significantly higher SAPS II and SOFA scores and had more frequently an underlying hematologic malignancy (Table 1). No significant inter-group difference in infection characteristics was found. Patients who died in the ICU had significantly lower pH (7.27 ± 0.17 vs. 7.32 ± 0.12: p = 0.03), higher lactate (6.3 ± 5.3 vs. 4.1 ± 3.7 mmol/L: p = 0.0004) and creatinine levels (225 ± 144 vs. 180 ± 140 µmol/L: p = 0.03) and exhibited more frequently a disseminated intravascular coagulation (10/78 [13 %] vs. 11/145 [8 %]: p = 0.002) at the time of shock diagnosis than their counterparts (Table 1). The delay of initial antibiotic therapy was longer (4.3 ± 10.6 vs. 1.8 ± 4.0 h: p = 0.02), and antibiotics were less frequently appropriate (63/78 [81 %] vs. 135/145 [93 %]: p = 0.005) in non-survivors than in patients discharged alive from the ICU. Similarly, patients who died in the ICU received a greater dose of vasopressors (1.25 ± 1.17 vs. 0.55 ± 0.47 µg/kg/min: p < 0.0001) than survivors and required more frequently the administration of epinephrine (35/78 [45 %] vs. 33/145 [23 %]: p = 0.0006), renal replacement therapy (19/78 [24 %] vs. 19/145 [13 %]: p = 0.04) and mechanical ventilation (77/78 [99 %] vs. 127/145 [88 %]: p = 0.0012) (Table 1). After initial fluid resuscitation, hemodynamic parameters were not significantly different between groups (Table 2). While mean LVEF, mean LVEDV and mean ΔSVC were similar between groups, non-survivors exhibited slightly yet significantly lower LV stroke volume reflected by a decreased mean LVOT VTI (16 ± 6 vs. 17 ± 5 cm: p = 0.03) and larger RV cavity, as reflected by a significantly greater RVEDA/LVEDA ratio (0.77 ± 0.83 vs. 0.59 ± 0.17: p = 0.01) without associated paradoxical septal motion (Table 2). The prevalence of hyperkinetic LV (LVEF > 70 %) was low in the two study groups (2/78 [3 %] vs. 10/145 [7 %]: p = 0.17). Actual LV dilatation was rarely observed, with the same frequency in both groups (8/78 [10 %] vs. 14/145 [10 %]: p = 0.89). Mean value of lateral E′ maximal velocity was significantly lower in patients who died in the ICU when compared with survivors (10.5 ± 3.7 vs. 11.9 ± 4.5 cm/s: p = 0.04), whereas mean E/E′ lateral only tended to be higher in those patients without reaching statistical significance (Table 2). The proportion of LV diastolic dysfunction tended to be higher in non-survivors than in their counterparts, even if the difference was not significant (28/78 [36 %] vs. 41/145 [28 %]: p = 0.15). In the lower quartile of E′ lateral maximal velocity values (E′ lateral ≤ 8.2 cm/s), the proportion of deceased patients tended to be higher, whereas the opposite trend was observed in the higher quartile (E′ lateral ≥ 14.1 cm/s) (Table 3).
Table 1
Clinical characteristics of the study population
Parameters
Global population (n = 223)
Survivors (n = 145)
Non-survivors (n = 78)
p
Patients characteristics
Age (years)
64 ± 13
63 ± 13
64 ± 13
0.74
Male (n)
140 (63)
93 (64)
47 (60)
0.57
SAPS II
55 ± 18
49 ± 15
66 ± 17
<0.0001
SOFA
10 ± 3
9 ± 3
11 ± 3
<0.0001
Charlson
3.5 ± 2.5
3.4 ± 2.6
3.6 ± 2.1
0.56
Cancer (n)
35 (16)
23 (16)
12 (15)
0.93
Hematologic malignancy (n)
10 (4)
1 (0.7)
9 (12)
0.0004
Chronic renal failure (n)
14 (6)
7 (5)
7 (9)
0.22
Cirrhosis (n)
12 (5)
5 (3)
7 (9)
0.08
Infection characteristics
Documented infection
185 (83)
123 (85)
62 (80)
0.31
Bacteremia
105 (47)
65 (45)
40 (51)
0.36
Abdominal
87 (39)
57 (41)
30 (41)
0.96
Pulmonary
48 (22)
31 (22)
17 (23)
0.94
Urogenital
37 (17)
26 (19)
11 (15)
0.46
Skin or joint and bones
12 (5)
1 (7)
3 (4)
0.14
Other origin
30 (13)
16 (13)
13 (15)
0.21
Biology
pH
7.30 ± 0.14
7.32 ± 0.12
7.27 ± 0.17
0.03
Lactates (mmol/L)
4.9 ± 4.4
4.1 ± 3.7
6.3 ± 5.3
0.0004
PaO2/FiO2
177 ± 113
180 ± 116
171 ± 108
0.57
Creatinine (µmol/L)
196 ± 143
180 ± 140
225 ± 144
0.03
Bilirubin (µmol/L)
22 ± 35
20 ± 24
27 ± 49
0.12
ALAT (IU/L)
134 ± 335
115 ± 302
167 ± 389
0.28
Hemoglobin (g/dL)
11 ± 2
11 ± 2
11 ± 3
0.69
White blood cells (G/L)
15.5 ± 14.5
15.5 ± 12.3
15.6 ± 18.1
0.93
Platelets (G/L)
211 ± 151
217 ± 157
199 ± 138
0.40
DIC (n)
21 (9)
11 (8)
10 (13)
0.002
Treatment characteristics
Delay of antibiotic therapy (h)
2.7 ± 7.1
1.8 ± 4.0
4.3 ± 10.6
0.02
Antibiotics administered <3 h
174 (78)
119 (84)
55 (71)
0.06
Appropriate initial antibiotic therapy
198 (88)
135 (93)
63 (81)
0.005
Fluid therapy (L)
4.4 ± 3.7
4.4 ± 3.6
4.6 ± 3.9
0.74
Noradrenaline (n)
205 (92)
134 (95)
71 (91)
0.72
Epinephrine (n)
68 (30)
33 (23)
35 (45)
0.0006
Dobutamine (n)
11 (5)
6 (4)
5 (6)
0.45
Maximal dose of vasopressorsa (µg/kg/min)
0.79 ± 0.85
0.55 ± 0.47
1.25 ± 1.17
<0.0001
Hydrocortisone Hemisuccinate (n)
22 (10)
11 (8)
11 (14)
0.12
Renal replacement therapy
38 (17)
19 (13)
19 (24)
0.04
Invasive mechanical ventilation
204 (91)
127 (88)
77 (99)
0.0012
Results are expressed as means ± standard deviations; numbers in brackets are percentages
SAPS II Simplified Acute Physiology Score, SOFA Sequential Organ Failure Assessment, ALAT alanine aminotransferase, DIC disseminated intravascular coagulation
aDuring the ICU stay
Table 2
Hemodynamic parameters and echocardiographic findings at the time of assessment
Parameters
Global population (n = 223)
Survivors (n = 145)
Non-survivors (n = 78)
p
Hemodynamic parameters
sBP (mmHg)
112 ± 29
113 ± 28
109 ± 31
0.34
dBP (mmHg)
63 ± 17
64 ± 16
62 ± 18
0.36
mBP (mmHg)
77 ± 20
78 ± 19
75 ± 22
0.35
HR (bpm)
109 ± 25
107 ± 24
112 ± 27
0.19
CVP (mmHg)
11 ± 5
11 ± 5
11 ± 6
0.72
Echocardiography
LVEF (%)
48 ± 17
49 ± 17
46 ± 18
0.39
LVEDV (mL)
93 ± 36
95 ± 37
90 ± 34
0.37
LVOT VTI (cm)
16 ± 5
17 ± 5
16 ± 6
0.03
E wave (cm/s)
80 ± 27
80 ± 25
79 ± 30
0.49
A wave (cm/s)
82 ± 27
82 ± 27
82 ± 27
0.89
E/A
1.03 ± 0.55
1.05 ± 0.58
0.99 ± 0.46
0.85
Lateral E′ wave (cm/s)
11.4 ± 4.3
11.9 ± 4.5
10.5 ± 3.7
0.04
E/E′ lateral
8.0 ± 3.8
7.7 ± 3.7
8.5 ± 4.0
0.26
RVEDA/LVEDA
0.66 ± 0.51
0.59 ± 0.17
0.77 ± 0.83
0.01
Paradoxical septal motion (n)
14 (6)
7 (5)
7 (9)
0.23
ΔSVC (%)
14 ± 13
15 ± 13
14 ± 12
0.97
Results are expressed as means ± standard deviations; numbers in brackets are percentages
sBP systolic blood pressure, mBP mean blood pressure, dBP diastolic blood pressure, HR heart rate, CVP central venous pressure, LVEF left ventricular ejection fraction, LVEDV left ventricular end-diastolic volume, LVOT VTI left ventricular outflow tract velocity–time integral, RVEDA right ventricular end-diastolic area, LVEDA left ventricular end-diastolic area, ΔSVC collapsibility index of the superior vena cava
Table 3
Distribution of patients according to quartiles of lateral E′ maximal velocity
Quartiles
Survivors (n = 145)
Non-survivors (n = 78)
p
Lateral E′ ≥ 14.1 cm/s
31 (21)
11 (14)
0.14
10.9 ≥ lateral E′ < 14.1 cm/s
30 (21)
13 (17)
8.2 ≥ lateral E′ < 10.9 cm/s
17 (12)
13 (17)
8.2 ≥ lateral E′ < 14.1 cm/s
21 (14)
20 (26)
Numbers in brackets are percentages
In the multivariate analysis, the inappropriateness of initial antibiotic therapy, the maximal dose of vasopressors during ICU stay, the SOFA score and E′ lateral maximal velocity (OR 1.12 [95 % CI 1.01–1.24] per decrease of 1 cm/s; p = 0.02) were significantly associated with ICU mortality (Table 4). After adjusting for the SAPS II score, the initial inappropriate antibiotic therapy and the maximal dose of vasopressors remained independent factors related to ICU mortality. In contrast, a trend was only observed for lateral E′ maximal velocity (OR 1.11 [CI 95 % 0.99–1.23]: p = 0.07) (Table 4).
Table 4
Multivariate analysis to determine prognostic factors associated with ICU mortality
Parameters
Odds ratio [95 % CI]
p
Without adjustment
Inappropriate initial antibiotic therapy
4.17 [1.33–12.5]
0.03
Maximal dose of vasopressors (per mg/h)
1.38 [1.16–1.63]
0.01
SOFA (per point)
1.16 [1.02–1.32]
0.02
Lateral E′ maximal velocity (per decrease of 1 cm/s)
1.12 [1.01–1.24]
0.02
When adjusting for SAPS II
Inappropriate initial antibiotic therapy
5.88 [1.64–20.00]
0.007
Maximal dose of vasopressors (per mg/h)
1.26 [1.08–1.47]
0.004
Lateral E′ maximal velocity (per decrease of 1 cm/s)
1.11 [0.99–1.23]
0.07
SOFA Sequential Organ Failure Assessment, SAPS Simplified Acute Physiology Score

Discussion

In the present study, independent factors related to ICU mortality in septic shock patients were the inappropriate initial antibiotic therapy, the maximal dose of vasopressors used during ICU stay, the SOFA score and a decreased lateral E′ maximal velocity indicating altered LV diastolic properties. After adjusting for the SAPS II score, inappropriate antibiotic therapy and maximal dose of vasopressors were the sole factors independently associated with ICU mortality, while a trend was only observed for lateral E′ maximal velocity.
LV diastolic dysfunction was observed in 31 % of our patients, in keeping with the prevalence reported previously in patients hemodynamically assessed for severe sepsis and septic shock, which ranged between 20 % [15, 16] and 57 % [33]. Such variations may be related to the use of different definitions for LV diastolic dysfunction, different timing of echocardiographic assessment relative to the sepsis course, and distinct clinical settings (i.e., severe sepsis vs. septic shock). Using the currently recommended criteria [32], we and others previously identified a reversible LV diastolic dysfunction in 20 % of septic shock patients [15, 16]. The marked smaller sample size of these previous studies when compared with the present cohort may account for this discrepancy. The current study confirms that true LV enlargement is uncommon in septic shock patients [15, 34]. The potential protective effect of LV cavity dilatation on outcome has long been suggested in septic patients [7]. Its prognostic significance is currently debated and remains to confirm in large-scale studies [35].
Measurement of tissue Doppler E′ wave maximal velocity at the mitral annulus reflects the lengthening velocity of LV longitudinal myocardial fibers during early diastole. Accordingly, a reduced E′ velocity <8 cm/s when measured on septal mitral annulus and <10 cm/s when measured on lateral mitral annulus are diagnostic of LV diastolic dysfunction [32]. We previously showed the high precision of this measurement in critically ill patients, as reflected by a 4 and 2 % inter- and intra-observer reproducibility, respectively [29]. Accordingly, the small absolute difference in lateral E′ maximal velocities observed between groups in the current study is greater than expected reproducibility of measurement. We purposely measured E′ maximal velocity on the lateral aspect of the mitral annulus because we previously found that this parameter was relatively independent of LV loading conditions, as opposed to septal E′ maximal velocity [29]. Nevertheless, Mahjoub et al. [36] recently reported that the increase in E′ maximal velocity secondary to fluid loading was significantly greater in septic patients with fluid responsiveness, whereas non-responders to a fluid challenge exhibited larger increase in E/E′ ratio reflecting higher LV filling pressure after blood volume expansion. In our patients, mean ΔSVC, which has previously been validated as a marker of fluid responsiveness [31], was similar in survivors and in non-survivors. Moreover, mean fluid volume administered to our septic patients prior to hemodynamic assessment was also similar in both groups. Accordingly, fluid resuscitation has presumably not influenced lateral E′ maximal velocity in the present cohort of septic shock patients.
Although LV diastolic dysfunction alters the prognosis of many cardiac diseases [12, 13], its prognostic impact in septic shock remains controversial. Several studies failed to identify LV diastolic dysfunction as a potential predictor of outcome in septic patients [10, 15]. In contrast, a recent meta-analysis reported a relationship between abnormal LV relaxation as assessed by E′ maximal velocity and death in septic patients [17]. In a cohort of 262 patients with severe sepsis and septic shock, Landesberg et al. [9] showed that LV diastolic dysfunction was the strongest predictor of short-term mortality, even after adjusting for the APACHE II score. ICU mortality was also related to the severity of LV diastolic dysfunction [9]. In keeping with these results, lateral E′ maximal velocity was independently associated with ICU mortality in our septic shock patients. Nevertheless, a nonsignificant trend only persisted when adjusting for the SAPS II score and was observed when dividing the current cohort according to quartiles of lateral E′ maximal velocity. A similar trend was observed when using a cutoff value of 10 cm/s for defining LV diastolic dysfunction [32] and when comparing its prevalence between non-survivors and survivors. The potential impact of LV diastolic dysfunction on ICU mortality of septic shock patients may be related to various factors. Abnormal relaxation results in a reduced early LV filling, an increased contribution of left atrial contraction to late LV filling and a progressive increase in LV filling pressure [14]. Marked hypovolemia, tachycardia and high rate of acute atrial fibrillation in sepsis [37] contribute to further reduce early LV filling by shortening the duration of diastole and subsequently to decrease cardiac output. The relative increase in LV filling pressures associated with diastolic dysfunction could facilitate a positive fluid balance, which prognostic impact has recently been suggested [38, 39]. This may worsen non-cardiogenic pulmonary edema associated with sepsis [40], or even lead to right cardiac failure [18], as suggested by the increased RVEDA/LVEDA ratio without associated acute cor pulmonale in our patients who died in the ICU.
As previously reported [26], inappropriate initial antibiotic therapy was the strongest predictor of ICU mortality in the present cohort of septic shock patients. In our patients, the 4.17 odds ratio for ICU death was in agreement with the fivefold higher risk of death observed by Kumar et al. [26]. Inappropriate initial antibiotic therapy remained significantly associated with ICU mortality after adjusting for SAPS II score with a 5.88 odds ratio. In addition to the SOFA score, the maximal dose of vasopressors administered to our septic shock patients was also an independent risk factor for ICU mortality. Higher mean dose of vasopressors administered to non-survivors may reflect the presence of a more severe circulatory failure with profound vasoplegia, which has long been related to unfavorable outcome [7]. Higher mortality rate in septic shock patients presenting with a hyperkinetic hemodynamic profile associating markedly increased cardiac output and low systemic vascular resistance has also been reported in echocardiographic studies [34, 41]. In our patients, mean LVEF was similar between survivors and non-survivors, and the prevalence of hyperkinetic profile was not significantly different between groups. The low prevalence of marked hyperkinetic states reflected by a LVEF > 70 % in septic shock patients presumably explains this result due to our underpowered study [34]. Nevertheless, currently available studies have been conducted on limited sample size [7, 34], or failed to enroll consecutive patients [41]. Accordingly, the prognostic value of LV hyperkinesia as a marker of profound sepsis-induced vasoplegia remains to confirm in a large prospective cohort of consecutive patients with septic shock who are hemodynamically assessed using echocardiography.
Although various other factors have been shown to be prognostic in patients with septic shock, including comorbidities [42], site of infection [43], bacteriological documentation [44], causative microorganism [45] and initial management [25], none of these factors was associated with ICU mortality in the present cohort of septic shock patients.
The present study has several limitations. Due to its retrospective design, the absence of available echocardiographic recordings in a substantial proportion of eligible patients constitutes a selection bias. Nevertheless, our cohort appears representative of septic shock patients admitted to the ICU, with a 35 % mortality rate [1, 2], a large proportion of patients under ventilator [43, 44] and a mean SOFA score of 10 reflecting the presence of sepsis-induced multiple organ failure [44]. Since LV diastolic dysfunction is commonly associated with age, high blood pressure, diabetes and ischemic heart disease, it may be present prior to the development of septic shock in a large proportion of patients, rather that induced by sepsis [14]. The potential worsening of LV diastolic function secondary to the development of septic shock and its reversibility with the control of the causative infection could not be documented in the present study since echocardiography was not serially performed. Nevertheless, no prospective study has yet repeatedly assessed LV diastolic properties in a large cohort of septic shock patients. Accordingly, only few information on the course of LV diastolic properties during the management of septic shock is currently available, and the reversibility of sepsis-induced LV diastolic dysfunction remains to be confirmed [15, 16]. Since septal E′ maximal velocity was not measured in our patients, we could not use the traditional diagnostic criteria of LV diastolic dysfunction based on mean septal and lateral E′ maximal velocities and mean E/E′ ratio [32]. Nevertheless, E′ maximal velocity appears to be less dependent of LV loading conditions when recorded at the lateral rather than at the septal mitral annulus [29]. Finally, the dose of vasopressors and inotropes which may have altered LV diastolic properties at the time of echocardiographic assessment has not been recorded.

Conclusion

The present study confirms the frequency of LV diastolic dysfunction at the initial phase of septic shock. LV diastolic function assessed by the measurement of lateral E′ maximal velocity was independently associated with ICU mortality, in conjunction with the inappropriateness of the initial antibiotic therapy, the maximal dose of vasopressors administered and the SOFA score. After adjusting for the SAPS II score, a nonsignificant trend was only observed for E′ lateral maximal velocity. Due to the retrospective design of the present study and limitations of currently reported series, a prospective multicenter study allowing the longitudinal assessment of a large cohort of patients with septic shock using serial echocardiographic examinations is required to definitely confirm the potential prognostic role of LV diastolic dysfunction in this highly prevalent disease.

Key messages

  • Left ventricular diastolic dysfunction is frequently observed in ICU patients who are hemodynamically assessed using echocardiography for a septic shock.
  • Left ventricular diastolic function assessed using lateral E′ maximal velocity was independently associated with ICU death in conjunction with inappropriate initial antibiotic therapy, maximal dose of vasopressors and SOFA score.
  • After adjusting for SAPS II score, only a nonsignificant trend was observed between lateral E′ maximal velocity and ICU mortality.
  • A large-scale multicenter study is needed to definitely confirm the prognostic role of left ventricular diastolic dysfunction in septic shock patients.

Authors’ contributions

Celine Gonzalez and Philippe Vignon analyzed data, and Emmanuelle Begot, Nicolas Pichon, Bruno François, Anne-Laure Fedou, Catherine Chapellas, Antoine Galy, Claire Mancia and Thomas Daix participated in data acquisition. Philippe Vignon independently performed all echocardiographic measurement. François Dalmay performed the statistical analysis. Céline Gonzalez and Philippe Vignon drafted the manuscript. All authors read and approved the final manuscript.

Competing interests

The authors declare that they have no competing interests.
Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://​creativecommons.​org/​licenses/​by/​4.​0/​), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
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Dieses Fachbuch macht mit den wichtigsten chronisch entzündlichen Gelenk- und Wirbelsäulenerkrankungen vertraut. Anhand von über 40 instruktiven Fallbeispielen werden anschaulich diagnostisches Vorgehen, therapeutisches Ansprechen und der Verlauf …

Herausgeber:
Rudolf Puchner

2016 | Buch

Ambulant erworbene Pneumonie

Was, wann, warum – Dieses Buch bietet differenzierte Diagnostik und Therapie der ambulant erworbenen Pneumonie zur sofortigen sicheren Anwendung. Entsprechend der neuesten Studien und Leitlinien aller wichtigen Fachgesellschaften.

Herausgeber:
Santiago Ewig

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