Although our patients received morphine and midazolam as sedatives and analgesics before entering the study, they were discontinued due to the FDA-approved analgesic effects of DXM and only DXM continued. DMX is known as a lipophilic drug, with high distribution volume and a half-life about 6 min. Compared with clonidine, DXM is an alpha-2 agonist with an affinity of more than 8-fold to adrenergic receptors. It also has sedative, analgesic, and anti-anxiety effects. In this respect, phase 3 clinical trials had demonstrated that DXM with a dose of 0.2-0.7 µg/kg/h could have sedative and analgesic effects on the patients undergoing post-surgical ventilation, without respiratory depression after separation from the machine. The side effects mostly observed for this drug were also nausea, hypotension, and bradycardia. In the studies investigating pharmacokinetics of DXM in the patients with severe renal insufficiency (
i.e. creatinine clearance of less than 30), the half-life of the elimination had decreased. The mean half-life of the drug in healthy people had been by 2.5 h; however, in the patients with hepatic failure, it had been prolonged. As a result, the dose of this drug in the patients with septic shock needed to be reduced in case of liver involvement, depending on the degree of hepatic failure (
7,
10 and
11).
In a research carried out by Marcos et al. (2015), on Syrian golden hamsters, the groups had been evaluated in terms of microcirculatory parameters, venous leukocyte-endothelial reactions, as well as correlation between intravenous leukocyte-endothelial interactions and capillary perfusion changes, variations in MAP, and heart rate; suggesting that DXM had reduced adhesion and circulation of leukocytes and capillary density.
On the other hand, DXM had lowered heart rate without any significant drop in MAP (
12). In the present study, DXM increased MAP due to its agonistic effects on alpha-2 receptors although it decreased heart rate.
In another study by Yu
et al. (2014) examining the difference between effects of propofol and DXM with 10 mg/mL concentrations on the preload of 16 endotoxemic rabbits receiving norepinephrine, it had been confirmed that propofol had increased heart rate, without affecting contractility of myocardium and vascular resistance; in contrast, DXM had augmented cardiac contractility and vascular resistance at high doses (
13). As we detected in our study, the DXM increased MAP by affecting on systemic vascular resistance.
In the investigation by Geloen, use of clonidine and DXM in septic shock patients had correspondingly improved venous return along with heart rate, leading to maintained MAP. In the patients undergoing liver transplantation treated with the given drugs, an increase in DBP had been also associated with a decrease in heart rate and a reduced need for vasopressors (
6).
However, the study by Penttilä had demonstrated that DXM had lowered SBP and DBP in healthy males and the etiology had remained still unclear because of the alteration of sensitivity of the receptors in septic shock. Due to the effects of DXM on presynaptic alpha-1 receptors, SBP and DBP had increased in the present study.
Besides, in a case study conducted by Leroy
et al., (2017) on a 29-week-old child with septic shock secondary to necrotizing enterocolitis, clonidine had been initiated at a dose of 1 μg/kg/h continued by infusion for 13 h after taking the initial steps and the results had revealed that clonidine could improve blood circulation and subsequently decrease norepinephrine dose requirement (
14,
15). In the present study, DXM by 0.6 µg/kg/h concentration during 12-h infusion could reduce norepinephrine dose requirement but the rate of reduction of norepinephrine was not sufficient to completely eliminate it and there was still a trace of dependence on vasopressors.
In 1993, Dyck
et al., had performed a study on pharmacokinetics of DXM for intravenous and intramuscular administration, with a dose of 2 μg/kg in healthy volunteers, and showed that the percentage of metabolic biomarker of DXM in comparison with the intravenous administered dose, had been by 73 ± 11%. After intramascular injection, average arrival time to maximum concentration had been 12 min (at a range of 2-60 min) and average maximum concentration had been 81.2 ± 0.27 ng/mL. After intravenous administration of DXM, dual changes in blood pressure had been observed. During the first 5 min of intravenous injection by 2 μg/kg, MAP had increased by 22% and heart rate had decreased by 27% from baseline. Within 4 h after injection, MAP had also decreased by 20% from baseline and heart rate had reached less than 5% of the initial values. The hemodynamic profile had not shown any acute changes after intramuscular administration. Within 4 h after intramuscular injection, MAP and heart rate had subsequently decreased by 20% and 10%, respectively (
16). In the present study, intravenous infusion of DXM also reduced heart rate at 3, 5, 6, and 9 h and increased MAP at 2, 8 and 11 h. It should be noted that the effect of the lowest dose was mediated mainly by arteriolar vasoconstriction, probably due to its cumulative effect.
Moreover, in a study by Lin et al., (2009), the effects of simultaneous administration of morphine and DXM for anxiolytic effects had been reported and the results had suggested that morphine at a dose of 1 mg/mL accompanied by 5 µg/mL of DXM had reduced the dose of morphine by 29% within 24 h despite an increase in the analgesic effect from the second hour after surgery.
MAP had decreased and pulse rate was higher in the group receiving DXM. Within 4 to 24 h, the incidence of nausea had been lower in DXM group. In general, in this study, performed on 100 women undergoing hysterectomy, the use of this drug had not induced bradycardia or hypotension, respiratory depression, and excessive sedation in the patients (
17).
In this study, since individuals with septic shock had failed to have spontaneous oral nutrition, they had been mainly fed through nasogastric tube and nausea had been assessed by the amount of fluid returned through it. Accordingly, the results revealed that the drug had not increased nausea in these patients compared with the control group.
Although DXM couldn’t have significant changes in APACHE II, SOFA, hospital and ICU stay, this drug could increase the MAP that is very important in septic shock patients.
Diagram of participants (according to CONSORT 2010 guidelines)
Heart rate changes in DXM and control groups over 12 h (mean ± SE) (P < 0.01)
SBP changes in DXM and control groups over 12 h (mean ± SE) (P = 0.002)
DBP changes in DXM and control groups over 12 h (mean ± SE) (P = 0.32)
MAP changes in DXM and control groups over 12 h (mean ± SE) (P = 0.021)
Mean norepinephrine dose changes in DXM and control groups over 12 h (mean ± SE) (P = 0.12)
| SOFA score | Mean ± SD control | Mean ±.SD DXM | p-value |
|---|
| Baseline | 9.3 ±2.8 | 9.5 ±.2.4 | 0.71 |
| Second day | 8.5 ± 3.1 | 8.1 ± 3 | 0.9 |
| Seventh day | 4.2 ±4.5 | 5 ± 4.1 | 0.3 |