Effect of initial infusion rates of fluid resuscitation on outcomes in patients with septic shock: a historical cohort study

This is a retrospective cohort study of adult (≥ 18 years of age) medical intensive care unit (MICU) patients in Mayo Clinic, Rochester, MN, from January 1, 2006, through May 31, 2018, who had a diagnosis of septic shock and underwent resuscitation with IV fluids. Using hospital electronic health records (EHR), we screened MICU patients for eligibility. We identified septic shock patients who received fluid resuscitation > 30 ml/kg within the first 24 h and excluded patients with other types of shock [hypovolemic shock, cardiogenic shock, obstructive shock based on the International Classification of Diseases-10 (ICD-10) code of discharge diagnosis], those without Minnesota research authorization, vulnerable adults, prisoners, individuals with known pregnancy at the time of index admission, and patients who stayed in the MICU for < 48 h. The study was reviewed and approved by the Institutional Review Board (#18-008349) at Mayo Clinic, Rochester. Informed consent was waived for patients with Minnesota research authorization due to the minimal risk nature of the study.

Sepsis was defined as an increase in the Sequential [Sepsis-related] Organ Failure Assessment (SOFA) score of 2 points or more, which caused by presumed or confirmed infection (Sepsis-3) [2]. To minimize the effect of temporal changes in the care of patients with sepsis during the study period and to confirm the accuracy of the included patients, the septic shock cases had to meet all three following criteria (1) diagnosis of septic shock based on ICD-10 code of discharge diagnosis, (2) criteria of sepsis described by Sepsis-3, and (3) mean arterial pressure (MAP) < 65 mmHg with vasopressor use and serum lactate level > 2 mmol/l along with an antibiotic prescription.

To minimize the effect of pre-hospital fluid resuscitation, we only included patients whose first recorded mean arterial pressure of < 65 mmHg occurred in MICU, and there was no record of vasopressor utilization prior to MICU admission. Time zero (T₀) was defined as the first time that MAP was < 65 mmHg or serum lactate was > 2 mmol/l. Shock reversal time (T_r) was defined as the time in which MAP was > 65 mmHg without vasopressors and lactate < 2 mmol/l. Time to shock reversal was calculated as the duration between T_r and T_0.

The initial fluid resuscitation rate (ml/kg/min) was calculated as the volume of 30 ml/kg of the actual body weight on admission divided by the time (min) to complete. Although the literature in support of the use of 30 ml/kg of crystalloid for initial volume resuscitation among septic shock patients is scarce, it is considered as one of the major recommendations by SSC₂₀₁₆. Therefore, we chose 30 ml/kg of crystalloid as a cutoff for the inclusion of patients in our study. In a recent study, investigators demonstrated that failure to deliver 30 ml/kg within 3 h of diagnosis of sepsis was associated with increased odds of in-hospital mortality, irrespective of other comorbidities [24]. Patients were categorized into four groups based on the resuscitation time: ≤ 1 h, 1.1–2 h, 2.1–3 h, and > 3 h for groups 1 to 4, respectively. The corresponding fluid rate for the groups described above were ≥ 0.5, 0.25–0.49, 0.17–0.24, and < 0.17 ml/kg/min, respectively (Fig. 1).

Pre-resuscitation lactate was defined as the lactate level closest (from 48 h before T₀ to 2 h after T₀) to T₀, post-resuscitation lactate was defined as the lactate level closest to T₃ (3 h after T₀), and lactate clearance was determined by its decline between pre- and post-resuscitation lactate levels. The doses of the vasopressors were described by Vasoactive-Inotropic Score (VIS; [VIS = dopamine dose (mcg kg⁻¹ min⁻¹) + dobutamine dose (mcg kg⁻¹ min⁻¹) + 100 × epinephrine dose (mcg kg⁻¹ min⁻¹) + 10,000 × vasopressin dose (units kg⁻¹ min⁻¹) + 100 × norepinephrine dose (mcg kg⁻¹ min⁻¹) + 100 × phenylephrine dose (mcg kg⁻¹ min⁻¹)]) [25]. Fluid balance was defined as the difference of the fluid intake and output and was adjusted based on hospital admission weight. Acute Physiology And Chronic Health Evaluation (APACHE) III and SOFA scores were automatically calculated. Charlson comorbidity index (CCI) was determined at hospital admission.

Baseline variables including patient demographics, hospital admission weight, hemodynamic variables, sites of infection, APACHE III and SOFA scores, and CCI were collected from the Multidisciplinary Epidemiology and Translational Research in Intensive Care (METRIC) DataMart [26]. The primary outcome was the time to shock reversal. Secondary outcomes included lactate clearance, weight-adjusted fluid balance in the first 3 h of resuscitation and throughout MICU stay, weight-adjusted fluid infusion between T₃ and MICU discharge, timing of vasopressor initiation, temporal trends of VIS in the first 24 h calculated every 3 h, MAP and heart rate changes within the first 3 h of resuscitation, need and length of mechanical ventilation, SOFA day 1 to day 2 score changes, time to alive discharge from MICU and hospital, and finally MICU, hospital, and 28-day mortality (Fig. 1).

We summarized the data using frequencies and percentages for categorical variables and medians and interquartile ranges for continuous variables. We also compared data distributions across fluid resuscitation rate groups using chi-square and Kruskal-Wallis tests for categorical and continuous data, respectively.

The time of pre-resuscitation reported lactate was 0 (− 3.6, 1.1) h from T₀, and the time of post-resuscitation reported lactate was 3.8 (1.5, 10.6) h after T₃. The lactate clearance during initial fluid resuscitation was significantly different among groups (P < .001); group 4 had less lactate reduction compared to group 1 (0.2 vs. 0.5 mg/dl; P < .001). Group 4 also had minimal change in MAP at 3 h, compared to group 1, who had a median increase of 4.3 mmHg (P = .04). A lower initial fluid resuscitation rate was associated with a later vasopressor use after septic shock onset (P < .001). A higher initial fluid resuscitation rate was associated with a higher mean fluid balance at 3 h (P < .001), but not with the mean fluid balance for the rest of the MICU stay (P = .1). The volume of infused fluid from T₃ to the MICU discharge was significantly higher in group 4 compared to groups 1 (168 vs. 107 ml/kg, P < .001) and 2 (168 vs. 124 ml/kg, P < .001). Relative to group 4, fewer patients in group 1 required mechanical ventilation (OR = 1.91; 95% CI = 1.34, 2.73; P = .001), and for the ones who needed mechanical ventilation, the duration was shorter (mean = 1.88; 95% CI = 0.40, 3.36 days; P = .01). Group 1 also had a more significant decline in SOFA score compared to groups 3 (− 3 vs. − 2; P < .05) and 4 (− 3 vs. − 2, P < .001) (Table 2).

The proportions of alive discharges from ICU and hospital (P < .001 for both) significantly differed among the groups. Similarly, MICU (P < .001) and hospital durations (P < .001) were different. Compared to group 4, group 1 had a shorter MICU (2.9 vs.4.9 days; P < .001) and hospital (10.1 vs. 17.7 days; P < .001) stay. The 28-day mortality was also significantly different among the groups (P < .001). Compared to group 4, group 1 had lower 28-day mortality (16.0% vs.34.0%; P < .001) (Table 2). Using 0.25 ml/kg/min as threshold for intravascular fluid replacement rate, patients with a higher fluid rate (≥ 0.25 ml/kg/min) were more likely to survive at 28 days (HR = 0.71; 95% CI 0.60–0.85; P < .001) compared to ones with a lower fluid rate (< 0.25 ml/kg/min) (Fig. 3b).

Table 3 and Fig. 4 show associations between fluid resuscitation rate and VIS at various time points. Fluid rate of < 0.17 ml/kg/min and increased weight were associated with lower VIS scores at all time points. Increased length of ICU stay, APACHE III, and SOFA scores were associated with increased VIS scores.