Schnider and Eleveld Models for Propofol Target-Controlled Infusion Anesthesia: A Clinical Comparison
by
Federico Linassi
1,2,*,
Paolo Zanatta
2,
Leonardo Spano
3,
Paolo Burelli
4,
Antonio Farnia
2 and
Michele Carron
3
1
Department of Pharmaceutical and Pharmacological Sciences, Università Degli Studi di Padova, Via Marzolo 5, 35131 Padova, Italy
2
Department of Anesthesiology and Critical Care, Treviso Regional Hospital, AULSS 2 Marca Trevigiana, Piazzale Ospedale 1, 31100 Treviso, Italy
3
Department of Medicine—DIMED, Section of Anesthesiology and Intensive Care, University of Padova, 35100 Padova, Italy
4
Department of Breast Oncologic Surgery, Treviso Regional Hospital, AULSS 2 Marca Trevigiana, Piazzale Ospedale 1, 31100 Treviso, Italy
*
Author to whom correspondence should be addressed.
Life 2023, 13(10), 2065; https://doi.org/10.3390/life13102065
Submission received: 18 September 2023
/
Revised: 10 October 2023
/
Accepted: 12 October 2023
/
Published: 16 October 2023
(This article belongs to the Section Medical Research)
Abstract
:Background: Various pharmacokinetic/pharmacodynamic (PK/PD) models have been developed to accurately dose propofol administration during total intravenous anesthesia with target-controlled infusion (TIVA-TCI). We aim to clinically compare the performance of the Schnider model and the new and general-purpose Eleveld PK/PD model during TIVA-TCI. Methods: We conducted a prospective observational study at a single center, enrolling 78 female patients, including 37 adults (aged < 65 years) and 41 elderly patients (aged ≥ 65 years). These patients underwent breast surgery with propofol-remifentanil TIVA-TCI guided by the bispectral index (BIS) for depth of anesthesia monitoring (target value 40–60) and the surgical plethysmographic index (SPI) for antinociception monitoring (target value 20–50) without neuromuscular blockade. The concentration at the effect site of propofol (CeP) at loss of responsiveness (LoR) during anesthesia maintenance (MA) and at return of responsiveness (RoR), the duration of surgery and anesthesia (min), the time to RoR (min), the propofol total dose (mg), the deepening of anesthesia events (DAEs), burst suppression events (BSEs), light anesthesia events (LAEs) and unwanted spontaneous responsiveness events (USREs) were considered to compare the two PK/PD models. Results: Patients undergoing BIS-SPI-guided TIVA-TCI with the Eleveld PK/PD model showed a lower CeP at LoR (1.7 (1.36–2.25) vs. 3.60 (3.00–4.18) μg/mL, p < 0.001), higher CePMA (2.80 (2.55–3.40) vs. 2.30 (1.80–2.50) μg/mL, p < 0.001) and at RoR (1.48 (1.08–1.80) vs. 0.64 (0.55–0.81) μg/mL, p < 0.001) than with the Schnider PK/PD model. Anesthetic hysteresis was observed only in the Schnider PK/PD model group (p < 0.001). DAEs (69.2% vs. 30.8%, p = 0.001) and BSEs (28.2% vs. 5.1%, p = 0.013) were more frequent with the Eleveld PK/PD model than with the Schnider PK/PD model in the general patient population. DAEs (63.2% vs. 27.3%, p = 0.030) and BSEs (31.6% vs. 4.5%, p = 0.036) were more frequent with the Eleveld PK/PD model than with the Schnider PK/PD model in the elderly. Conclusions: The Schnider and Eleveld PK/PD models impact CePs differently. A greater incidence of DAEs and BSEs in the elderly suggests more attention is necessary in this group of patients undergoing BIS-SPI-guided TIVA-TCI with the Eleveld PK/PD than with the Schnider model.
1. Introduction
Target-controlled infusion (TCI) is a widely used computer-controlled method for achieving and maintaining a stable concentration at the effect site of propofol (CeP) based on physiological parameters, such as the patient’s age, weight, height, and gender during total intravenous anesthesia (TIVA) [1,2]. The TIVA-TCI system uses a population-derived pharmacokinetic/pharmacodynamic (PK/PD) model incorporated in a computer-controlled infusion pump to determine the initial bolus dose and, subsequently, to reach and maintain the target CeP [1,2].
Various PK/PD models have been developed to accurately dose propofol administration during TIVA-TCI [1,2]. There is no evidence to support the use of one PK/PD model in preference over another and all PK/PD models have proven reliable in clinical practice [3]. One limitation of widely employed PK/PD models for propofol is that they were developed mainly using healthy volunteers or patients and not with challenging populations, such as children and obese or elderly patients whose body composition or elimination mechanisms may be structurally different from those of the lean adult patient population [2,3].
The Eleveld propofol PK/PD model (from here on referred to as “model” for convenience) was developed for a broad population range as TIVA-TCI for children, adults, elderly subjects, and obese adults undergoing general anesthesia [4]. However, in a prospective study comparing the predictive performance of the Eleveld model with other models in a TCI system, for PK, the Eleveld model showed a clinically acceptable performance in children, adults, and obese adults undergoing general anesthesia, but not in older subjects, where a great bias (27%) was observed [5].
The aim of this study was to investigate, primarily, the performance of the Schnider and Eleveld models comparing the CeP at loss of responsiveness (LoR) during anesthesia maintenance and at the return of responsiveness (RoR), and, secondarily, the incidence of unwanted events during anesthesia in adult patients undergoing TIVA-TCI with one of the two models.
2. Materials and Methods
2.1. Study Design
This prospective observational study, involving adult patients undergoing oncologic breast surgery at the Treviso Regional Hospital AULSS 2 Marca Trevigiana Piazzale Ospedale 1, 31100, Treviso (Italy), where TIVA-TCI is routinely used as the preferred anesthesia technique for patients undergoing surgery under general anesthesia, was approved by the local Institutional Ethical Committee (approval number 681/CE Marca). All subjects participating in the trial provided written informed consent. The trial was registered prior to patient enrollment at ISRSCTN registry (ISRCTN41934206; principal investigator: Linassi Federico; link to trial registry: https://www.isrctn.com/ISRCTN41934206, date of registration: 25 October 2022).
2.2. Study Population
From 30 October to 23 December 2022, female (≥18 years) patients undergoing surgical procedures (quadrantectomy or mastectomy) for breast cancer were consecutively recruited. Oncologic breast surgery is a well-standardized procedure typically performed on female patients with fewer health issues and a lower risk of bleeding, hypotension, and hemodynamic instability compared to other surgeries in our hospital.
The STROBE (Strengthening the Reporting of Observational Studies in Epidemiology) checklist was followed.
Patients with an American Society of Anesthesiologists (ASA) physical status classification of >3; a body mass index (BMI, kg/m2) of ≥35 (due to the limitations of Schnider TCI model in managing obese patients); neurodegenerative (e.g., Alzheimer’s disease, Parkinson’s disease) or cerebrovascular (e.g., transient ischemic attack, stroke) diseases; psychiatric disorders; and respiratory (i.e., asthma, chronic obstructive pulmonary disease), cardiovascular (e.g., chronic heart failure, coronary artery disease, arrhythmia, peripheral vascular disease), kidney (e.g., end-stage renal disease), and liver (e.g., cirrhosis) diseases were excluded due to their potential to affect cognitive functions and the individual’s response to anesthesia. Patients in continuous therapy with anxiolytics or antidepressant drugs or with a history of alcohol or psychoactive drug abuse were not enrolled due to brain effects and risks associated with differences in enzyme induction. Patients requiring perioperative anxiolysis or intraoperative vasoactive drugs or receiving neuromuscular blocking agents during surgery were also excluded to avoid the risk of underestimating unwanted spontaneous responsiveness events (USREs). Patients who were deaf or hard of hearing at preoperative evaluation were not enrolled.
The patient assignment to either the Schnider model group or the Eleveld model group was by chance, independently of patient scheduling, based on alternation between Schneider and Eleveld model users within the framework of a daily 6 h shift rotation of the anesthesiologists involved in the study, who adopted a priori the model they were used to or most familiar with during the study period [1,3].
2.3. General Anesthesia
Before anesthesia induction, continuous electrocardiography, pulse oximetry, and noninvasive blood pressure measurements were conducted and an intravenous line in the arm for TIVA-TCI was established. A bilateral electrode strip (COVIDien IIC, Mansfield, MA, USA) was placed on the patient’s forehead and linked to an XP monitor (Monitor BIS Module A-2000 Revision 3.12) to evaluate the level of consciousness and depth of anesthesia using the bispectral index (BIS). The BIS was calculated using a computer algorithm that analyzes the frontal lobe electroencephalogram (EEG) and displays it as a number on the BIS view monitor. BIS values range from 0 to 100. A value of 0 represents an absence of brain activity, and 100 represents an awake state. BIS values between 40 and 60 represent adequate general anesthesia for surgery, values less than 40 represent a deep hypnotic state, and values greater than 60 represent a light hypnotic state [6].
Concerning analgesia, the nociception–antinociception balance was monitored using the surgical plethysmographic index (SPI) [7,8]. The SPI is a normalized score that is based on a photoplethysmographic analysis of the pulse wave and the heartbeat interval. The values of the SPI range from 0 to 100. Maintaining a value between 20 and 50 is generally recommended during general anesthesia in adult patients [7,8,9] and this was the target in this study.
Induction and maintenance of anesthesia were performed using TIVA-TCI. CeP and Ce of remifentanil (CeR) were achieved using a uSP6000 syringe pump infusion system (Arcomed AG, Kloten, Switzerland), using the Schnider [10,11] or Eleveld [4] models for propofol and the Minto [12,13] model for remifentanil. The starting CeP was set at 1 μg/mL and continued at CeP increments of 0.5 μg/mL up to CeP 3–4 μg/mL (for patients <50 years of age) or 2–3 μg/mL (for patients >50 years of age) [1,4]. An investigator blinded to group allocation checked for LoR, defined as spontaneous eye closure associated with the inability to execute simple verbal commands (loss of connected spontaneous responsiveness)—for example, ‘Anne! Open your eyes!’—every 10 s after the propofol infusion was started. The TIVA-TCI was then adjusted by changes of 0.5 μg/mL at intervals of ≥1 min until the BIS reached the target value of 40–60 [14] after anesthesia induction and whenever a change of BIS target was observed during anesthesia maintenance. CePMA1 and CePMA2 were the CePs registered at the beginning and end of the BIS-SPI-guided anesthesia maintenance, respectively. Specifically, CePMA1 was the CeP observed after having evaluated BIS and SPI five times at one-minute intervals simultaneously to confirm the steady state, while CePMA2 was the last value of CeP during anesthesia maintenance before stopping TIVA-TCI at the end of the surgery.
To blunt noxious stimulation [15] without affecting LoR [16], the starting CeR was set at 0.8 ng/mL before starting propofol infusion and, after LoR, it was adjusted for intraoperative analgesia to a target SPI of 20–50 through changes of 0.5 ng/mL at intervals of ≥1 min until reaching the suggested SPI range [1,17,18,19].
After LoR, a laryngeal mask was placed, and volume-controlled protective lung ventilation was started.
At the end of the surgery, 30 mg ketorolac tromethamine, 1 g paracetamol, and 4 mg ondansetron were given intravenously for pain and postoperative nausea and vomiting (PONV) prophylaxis, respectively. Then, TIVA-TCI was targeted to a CeP of 0 μg/mL and a CeR of 0 ng/mL. With the return of spontaneous ventilation at RoR, defined as spontaneous eye-opening, obtained without providing auditory or tactile stimulation during the awakening process, associated with the ability to execute simple verbal commands after eye-opening (return of connected spontaneous responsiveness)—for example, ‘Anne! Shake my hand!’—the laryngeal mask was removed. The patient was then transferred to the post-anesthesia care unit.
2.4. Clinical Endpoints and Variables
Data were collected regarding age (years); BMI (kg/m2); American Society of Anesthesiologists (ASA) physical status; CeP (μg/mL) at LoR during anesthesia maintenance (CePMA1 and CePMA2) and at RoR; duration of surgery and anesthesia (min); time to RoR, defined as time to RoR after turning CeP = 0 at the end of the surgery; and propofol total dose (mg).
The primary endpoint was to evaluate the difference in CePs during anesthesia performed with the Schnider and Eleveld models. The secondary endpoints were to evaluate the difference in the incidence of unwanted events during anesthesia performed with the two PK/PD models: lightening of anesthesia event (LAE), defined as BIS > 60 [6]; deepening of anesthesia event (DAE), defined as BIS < 40 [6]; unwanted spontaneous responsiveness event, defined as any involuntary movement (i.e., movement of extremities) or somatic reaction (i.e., coughing, chewing, grimacing, breathing against a ventilator, or inadequate ventilation because of vocal cord closure) in combination with a significant hemodynamic response (i.e., tachycardia (>100 bpm) and hypertension (mean arterial pressure > 120% of baseline or mean arterial pressure ≥ 100 mmHg)) during anesthesia maintenance [7,8,9]; a burst suppression event (BSE), which is defined as a burst suppression ratio > 0. To avoid false positives occurring at low BSR values, according to the literature, BSR > 5% was chosen. Thus, a BSE was therefore defined as a BSR >5% episode, which means at least 3 s of suppressed activity in 1 min of EEG activity [9,20,21].
An investigator who was not involved in delivering anesthesia to patients recorded the data of the variables on a paper data-collection form. This investigator was in charge of electronically recording and storing the BIS data and any unwanted events during anesthesia. Data about CePs were collected from the display of the TIVA-TCI at the respective time points.
2.5. Statistical Analysis
Estimating the mean and standard deviation [22] from the median and range of the Median Absolute Performance Error between the Eleveld model and the Schnider model in adults [5], the sample size was based on the following assumptions: a significant Mean Absolute Performance Error difference of 4% between two models in adults, a standard deviation of 6.3%, type I error equal to 0.05, and type II error equal to 0.2 (power [1 − β] = 0.8). Considering these assumptions, the sample size was calculated as 78 patients, equally divided between the Eleveld model group (39 patients) and the Schnider model group (39 patients).
Descriptive analysis was used to summarize the characteristics of the sample. Median and interquartile range (IQR) values were reported for continuous variables. A two-tailed Mann–Whitney U test was used to compare continuous variables between the Eleveld model group and the Schnider model group. Categorical data were reported as an absolute number and as a percentage (%) and compared using an χ2 or Fisher’s exact test when more than 20% of cells have expected frequencies < 5 [23]. Friedman’s two-way ANOVA and the Wilcoxon signed-rank test were used to determine whether there was a statistically significant difference in CePs across the four time points and between paired data, respectively, in each model group. Bravais–Pearson’s correlation test was used to determine the strength and direction of association between CePs and age, height, body weight, and BMI. Correlation coefficients (CCs), 95% confidence intervals (95%CI), and p-values were determined. To determine the relationships between the dependent categorical (e.g., dichotomous) variable (i.e., unwanted events during anesthesia) and one or more independent categorical variables (i.e., demographic characteristics, PK/PD model), a multiple logistic regression analysis was performed to calculate odds ratios (ORs) with 95%CI [24]. Multicollinearity was assessed using variance inflation factors. The Akaike information criterion and backward/forward stepwise regression analysis were used to choose the best model. Statistical significance was set at p-value < 0.05. All statistical analyses were performed using R version 3.4.0 (21 April 2017).
3. Results
A total of 86 women undergoing breast oncologic surgery were enrolled. Eight patients had to be excluded from the study. Thus, 78 patients, comprising 37 adults and 41 elders, were considered (Figure 1).
Demographic characteristics and data about all patients—adults and elders—are reported in Supplementary Material Content (SMC1-Table S1). CePs differed significantly across the four time points within group analysis (p < 0.001), mainly due to a significant difference between CeP at RoR and other CePs (p < 0.001) in both model groups. Unwanted events during anesthesia were observed in 53.8% of the total patients. An LAE was observed in 3.8%, a USRE in 3.8%, a DAE in 50%, and a BSE in 16.7% of the total cases (SMC1-Table S1). Beyond age and ASA, there were no significant differences between the adults and the elders (SMC1-Table S1).
3.1. Comparison between the Total Population of Patients in the Schnider and Eleveld Model Groups
There were no differences in demographic characteristics, propofol dose, duration of surgery, duration of anesthesia, and time to RoR between the two model groups of patients (Table 1).
At LoR, CeP, and BIS were significantly lower in the Eleveld model group than in the Schnider model group (Table 1, Figure 2). During maintenance of anesthesia, CePs were significantly higher in the Eleveld model group than in the Schnider model group (Table 1, Figure 2). At RoR, CeP was significantly higher in the Eleveld model group than in the Schnider model group (Table 1, Figure 2). The ΔCeP, defined as the difference between CeP LoR and CeP ROR, was significantly different between the models (Table 1), with the hysteresis effect significant only for the Schnider model. No other significant differences were observed (Table 1).
The incidence of total unwanted events during anesthesia was higher in the Eleveld model group than in the Schnider model group (74.4% vs. 33.3% of patients; p = 0.001). A significant difference in the incidence of unwanted events during anesthesia related to a deepening—not a lightening—of anesthesia level was observed between the two groups (Table 1).
Concerning the impact of demographic characteristics on CePs, only a significant correlation was observed between age and CeP at RoR in the Schnider model group (CC [95%CI] = −0.493 [−0.7–(−0.21)], p = 0.001) (Supplementary Material Content-SMC2-Figures S1–S4).
At logistic regression analysis, the Eleveld model, when compared with the Schnider model, was associated with an increased risk of DAEs (OR [95%CI]: 5.06 [1.94–13.20], p < 0.001) and BSEs (OR [95%CI]: 7.27 [1.49–35.40], p = 0.014), and a reduced risk of LAEs and USREs (OR [95%CI]: 0.04 [0.01–0.12], p < 0.001) during TIVA-TCI (Supplementary Material Content-SMC3-Table S2).
3.2. Comparison between the Schnider Model Group and the Eleveld Model Group in Adults and in Elders
There were no significant differences in demographic characteristics, total propofol dose, and the duration of surgery and anesthesia between the two model groups of patients in both adults and elders (Table 1).
At all the time points, CePs differed significantly; they were lower at LoR and higher during maintenance of anesthesia and at RoR in the Eleveld model group than in the Schnider model group in both adults and elders (Table 1). A significant hysteresis effect was observed in the Schnider model group in both adults and elders (Table 1). At LoR and RoR, BIS differed significantly in adults but not in elders; it was lower at LoR and higher at RoR in the Eleveld than in the Schnider model group (Table 1). Moreover, the time to LoR did not differ significantly between the two model groups in both adults and elders, while the time to RoR was significantly higher in the Eleveld model group than in the Schnider model group in adults but not in elders (Table 1).
The Incidence of total unwanted events during anesthesia was higher in the Eleveld than in the Schnider model group in adults (85% vs. 35% of patients; p = 0.003) and in elders (63.2% vs. 31.8% of patients; p = 0.063).
No significant difference in the incidence of unwanted events related to a lightening of anesthesia level was observed between the two model groups in both adults and elders (Table 1). A significant difference in the incidence of unwanted events related to a deepening of anesthesia level was observed between the two model groups for DAEs in both adults and elders and for BSEs only in elders (Table 1).
4. Discussion
Differences in the PK/PD profile between the Schnider and Eleveld models may justify our findings. The Schnider model, a three-compartment mammillary model, has fixed values for the volume of distribution in the central compartment (V1) and in the second peripheral volume of distribution (V3); adjusts the volume of distribution in the peripheral compartment (V2) for age; and uses height, weight, and sex as covariates of metabolic clearance [3]. The Eleveld model has no fixed values for V1, V2, or V3, and demographic variables such as age, weight, height, and sex were identified as covariates to improve the prediction performance of the model [2]. In general, CeP reaches the targeted propofol concentration more quickly in a patient when a PK/PD model with a smaller V1 or decreased clearance is used than it does when the model has a larger V1 or clearance [25]. The plasma effect site equilibration rate constant (ke0) further affects CeP [25]. A PK/PD model with a high ke0 produces a fast equilibration between plasma and effect site concentration, which results in a higher CeP at LoR and lower CeP at RoR compared to that in a PK/PD model that has a low ke0 [26,27,28]. The fact that ke0 is higher and fixed in the Schnider model (0.456 min−1) [2] and lower (0.146 min−1) but scaled by (weight/70)-0.25 in the Eleveld model [4] may support the difference in CePs between the two model groups observed in our study.
The phenomenon in which anesthetic induction occurs at higher drug concentrations than the concentrations at emergence is called hysteresis [29,30]. It is attributed to neural inertia, the central nervous system’s inherent resistance to change between consciousness and unconsciousness based on discontinuous behaviors of sensory and motor-related thalamocortical networks at anesthesia induction and emergence [29]. However, hysteresis is not solely attributable to neural inertia [29], but also to the kinetics of drug equilibration [30]. Using a PK/PD model with a fast ke0 resulted in different CePs at LoR and at RoR, thus showing anesthetic hysteresis, while using a PK/PD model with a slow ke0 resulted in similar CePs at LoR and RoR, thus showing no anesthetic hysteresis [27]. Thus, a difference in kinetics of drug equilibration [30] and subsequent different timings for CeP to reach the target concentration may explain why hysteresis was significantly observed in the Schnider model group [27] but obscured in the group in which it was adopted as an effect site equilibration model that readily collapses hysteresis [30].
Different aspects should be considered when explaining a difference in the occurrence of unwanted events during anesthesia between the Schnider and Eleveld model groups. A given V1 [2,3] associated with a given ke0 [27,28] may affect the initial propofol dose delivered, as observed in a computer simulation [31], during anesthesia induction with incremental doses [3]. When the CeP is increased, the TCI system briefly increases the plasma concentration to an optimal level above the target effect site concentration before temporarily stopping the infusion to allow the plasma concentration to decrease to the level of the target CeP [3]. The magnitude of the optimal plasma concentration overshoot—the peak plasma concentration that generates a gradient sufficient to cause the most rapid increase in effect site concentration but without overshooting the effect site concentration above its target—depends on the PK model [3] and critically on ke0 [3,28]. In a PK/PD model with a high V1 associated with a low ke0, compared with a PK/PD model with a low V1 associated with a high ke0 [2,3], a larger initial plasma concentration overshoot is needed to produce a greater concentration gradient between the plasma and effect site and, thus, hasten their equilibrium [3,28]. This may result in a higher risk of propofol overdose during induction of anesthesia with potentially adverse clinical consequences [28].
The Eleveld TCI model also showed a higher bias in Predictive Median Performance Error (MdPE) than the Schnider one in older patients, probably contributing to higher DAEs and BSEs in older subjects [5]. Despite aging producing alterations in cardiovascular physiology that increase the onset time of anesthetic drugs [32], an increase in sensitivity to the hypnotic drug in the elderly compared to adults [11] may exacerbate the effect of equilibration between plasma and effect site concentration and favor deep anesthesia events during TIVA-TCI in elderly patients, in particular BSEs [33], which deserve attention due to being related to postoperative delirium and neurocognitive disorders [21,34]—although this is still debated [35,36,37]. Furthermore, aging was shown to impact the depth of anesthesia monitoring and EEG-based monitoring systems; different studies have shown higher indices in elders than in young people under a comparable anesthetic plan [33,38]. Modulating the rate of propofol infusion after anesthesia induction on the basis of a difference between the expected and measured BIS, as in the Eleveld model which uses BIS as the measure of effect [2], may increase the risk of hypnotic overdosage and result in deep anesthesia events, particularly in elderly patients [33].
Eleveld TCI models should be used by anesthesiologists who are confident with this PK/PD model and knowledgeable about the PK/PD differences compared to the Schnider TCI model. When using the Eleveld TCI model for older patients, induction and initial anesthesia maintenance should be carried out in a stepwise manner with smaller variations in CePs compared to those in the Schnider TCI model. These adjustments should be guided by depth anesthesia monitoring.
This study has some limitations. First, only female patients undergoing breast surgery were involved in this observational study. Future studies should confirm our findings in a larger population of patients, including male patients and those who have undergone other types of surgery, and in an evaluation of the whole raw EEG and not only processed EEG information, particularly for the BSE evaluation.
Second, the role of remifentanil and SPI should be considered. Unconsciousness was maintained primarily by using a single hypnotic agent, such as propofol, that was titrated to recommended BIS values. However, even if remifentanil is not hypnotic, it may contribute to unconsciousness by suppressing nociceptive-induced responsiveness or arousal [39]. Monitoring the levels of both hypnosis and antinociception was shown to reduce episodes of inadequate anesthesia [7]; however, in relatively young and healthy patients undergoing elective surgery under TIVA-TCI guided by a processed EEG index and SPI, in comparison to standard monitoring alone, the reduction in unwanted anesthesia events could not be validated [8].
5. Conclusions
The Schnider and Eleveld models impact CePs differently, and the incidence of unwanted events during anesthesia varies. Since the Eleveld model showed a greater bias than the Schnider model in older subjects [5] and, in our study, the incidence of BSEs in elderly patients was higher in the Eleveld than in the Schnider model group, particular attention should be reserved for such a population of patients undergoing TIVA-TCI using the Eleveld model, and any phase of anesthesia should be guided by EEG monitoring, including raw waveforms and spectrograms.
Supplementary Materials
The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/life13102065/s1, SMC1-Table S1. Descriptive analysis of population of female patients undergoing breast surgery. SMC3-Table S2. Logistic regression analysis. SMC2-Figure S1. Dispersion graph of the relation between CeP LoR and age, height, body weight and BMI in female patients undergoing propofol total intravenous anesthesia (TIVA) with target controlled infusion (TCI) using Schnider PK-PD model (39 patients) and Eleveld PK-PD model (39 patients) for breast surgery. Bravais-Pearson’s correlation test was used to determine the strength and direction of association between CeP LoR and age, height, body weight, body mass index (BMI). Correlation coefficient (CC), 95% confidence interval (95%CI), and p-values were determined. SMC2-Figure S2. Dispersion graph of the relation between BIS-guided CePMA1 and age, height, body weight and BMI in female patients undergoing propofol undergoing propofol total intravenous anesthesia (TIVA) with targeted controlled infusion (TCI) using Schnider PK-PD model (39 patients) and Eleveld PK-PD model (39 patients) for breast surgery. Bravais-Pearson’s correlation test was used to determine the strength and direction of association between BIS-guided initial CeP and age, height, body weight, body mass index (BMI). Correlation coefficient (CC), 95% confidence interval (95%CI), and p-values were determined. SMC2-Figure S3. Dispersion graph of the relation between BIS-guided CePMA2 and age, height, body weight and BMI in female patients undergoing propofol undergoing propofol total intravenous anesthesia (TIVA) with target controlled infusion (TCI) using Schnider PK-PD model (39 patients) and Eleveld PK-PD model (39 patients) for breast surgery. Bravais-Pearson’s correlation test was used to determine the strength and direction of association between BIS-guided final CeP and age, height, body weight, body mass index (BMI). Correlation coefficient (CC), 95% confidence interval (95%CI), and p-values were determined. SMC2-Figure S4. Dispersion graph of the relation between CeP RoR and age, height, body weight and BMI in female patients undergoing undergoing propofol total intravenous anesthesia (TIVA) with targeted controlled infusion (TCI) using Schnider PK-PD model (39 patients) and Eleveld PK-PD model (39 patients) for breast surgery. Bravais-Pearson’s correlation test was used to determine the strength and direction of association between CeP RoR and age, height, body weight, body mass index (BMI). Correlation coefficient (CC), 95% confidence interval (95%CI), and p-values were determined.
Author Contributions
F.L.: study design, data acquisition, data analysis, writing of the manuscript, and final approval. P.Z.: data analysis, writing of the manuscript, and final approval. L.S.: data acquisition, data analysis, writing of the manuscript, and final approval. P.B.: study design, data acquisition, data analysis, and final approval of the manuscript. A.F.: study design, data analysis, writing of the manuscript, and final approval. M.C.: study design, data analysis, writing of the manuscript, and final approval. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Institutional Review Board Statement
The study was conducted in accordance with the Declaration of Helsinki, and approved by the Institutional Review Board (or Ethics Committee) of NRC ULSS2 Marca trevigiana (protocol code N. 681/CE Marca, 20 January 2022). The trial was registered prior to patient enrollment at ISRSCTN registry (ISRCTN41934206; Principal investigator: Linassi Federico; link to trial registry: https://www.isrctn.com/ISRCTN41934206, Date of registration: 25 October 2022).
Informed Consent Statement
Informed consent was obtained from all subjects involved in the study.
Data Availability Statement
Data is unavailable due to privacy restrictions.
Acknowledgments
Authors would like to thank Furlan Francesco, for his support in data acquisition.
Conflicts of Interest
The authors declare no conflict of interest.
Glossary
| PK/PD | pharmacokinetic/pharmacodynamic |
| TCI | target-controlled infusion |
| TIVA | total intravenous anesthesia |
| CeP | estimated concentration at the effector site of propofol |
| LoR | loss of responsiveness |
| RoR | return of responsiveness |
| SPI | surgical plethysmographic index |
| BMI | body mass index |
| BIS | bispectral Index |
| CePMA1 | initial CeP during maintenance of anesthesia |
| CePMA2 | final CeP during maintenance of anesthesia |
| LAE | lightening of anesthesia event |
| USRE | unwanted spontaneous responsiveness event |
| DAE | deepening of anesthesia event |
| BSE | burst suppression event |
References
- Al-Rifai, Z.; Mulvey, D. Principles of total intravenous anesthesia: Practical aspects of using total intravenous anesthesia. BJA Educ. 2016, 16, 276–280. [Google Scholar] [CrossRef]
- Vandemoortele, O.; Hannivoort, L.N.; Vanhoorebeeck, F.; Struys, M.M.R.F.; Vereecke, H.E.M. General Purpose Pharmacokinetic-Pharmacodynamic Models for Target-Controlled Infusion of Anaesthetic Drugs: A Narrative Review. J. Clin. Med. 2022, 11, 2487. [Google Scholar] [CrossRef]
- Absalom, A.R.; Mani, V.; De Smet, T.; Struys, M.M.R.F. Pharmacokinetic models for propofol-defining and illuminating the devil in the detail. Br. J. Anaesth. 2009, 103, 26–37. [Google Scholar] [CrossRef]
- Eleveld, D.J.; Colin, P.; Absalom, A.R.; Struys, M.M.R.F. Pharmacokinetic-pharmacodynamic model for propofol for broad application in anesthesia and sedation. Br. J. Anaesth. 2018, 120, 942–959. [Google Scholar] [CrossRef]
- Vellinga, R.; Hannivoort, L.N.; Introna, M.; Touw, D.J.; Absalom, A.R.; Eleveld, D.J.; Struys, M.M.R.F. Prospective clinical validation of the Eleveld propofol pharmacokinetic-pharmacodynamic model in general anesthesia. Br. J. Anaesth. 2021, 126, 386–394. [Google Scholar] [CrossRef]
- Escallier, K.E.; Nadelson, M.R.; Zhou, D.; Avidan, M.S. Monitoring the brain: Processed electroencephalogram and peri-operative outcomes. Anaesthesia 2014, 69, 899–910. [Google Scholar] [CrossRef]
- Chen, X.; Thee, C.; Gruenewald, M.; Wnent, J.; Illies, C.; Hoecker, J.; Hanss, R.; Steinfath, M.; Bein, B. Comparison of surgical stress index-guided analgesia with standard clinical practice during routine general anesthesia: A pilot study. Anesthesiology 2010, 112, 1175–1183. [Google Scholar] [CrossRef]
- Gruenewald, M.; Harju, J.; Preckel, B.; Molnár, Z.; Yli-Hankala, A.; Rosskopf, F.; Koers, L.; Orban, A.; Bein, B.; AoA Study Group. Comparison of adequacy of anesthesia monitoring with standard clinical practice monitoring during routine general anesthesia: An international, multicentre, single-blinded randomised controlled trial. Eur. J. Anaesthesiol. 2021, 38, 73–81. [Google Scholar] [CrossRef]
- Linassi, F.; Kreuzer, M.; Kratzer, S.; Olivieri, S.; Zanatta, P.; Schneider, G.; Carron, M. Unwanted spontaneous responsiveness and burst suppression in patients undergoing entropy-guided total intravenous anesthesia with target-controlled infusion: An observational prospective trial. J. Clin. Anesth. 2023, 86, 111045. [Google Scholar] [CrossRef]
- Schnider, T.W.; Minto, C.F.; Gambus, P.L.; Andresen, C.; Goodale, D.B.; Shafer, S.L.; Youngs, E.J. The influence of method of administration and covariates on the pharmacokinetics of Propofol in adult volunteers. Anesthesiology 1998, 88, 1170–1182. [Google Scholar] [CrossRef]
- Schnider, T.W.; Minto, C.F.; Shafer, S.L.; Gambus, P.L.; Andresen, C.; Goodale, D.B.; Youngs, E.J. The influence of age on Propofol pharmacodynamics. Anesthesiology 1999, 90, 1502–1516. [Google Scholar] [CrossRef]
- Minto, C.F.; Schnider, T.W.; Egan, T.D. Influence of age and gender on the pharmacokinetics and pharmacodynamics of remifentnil. I. Model development. Anesthesiology 1997, 86, 10–23. [Google Scholar] [CrossRef] [PubMed]
- Minto, C.F.; Schnider, T.W.; Shafer, S.L. Pharmacokinetics and pharmacodynamics of Remifentanil. II. Model application. Anesthesiology 1997, 86, 24–33. [Google Scholar] [CrossRef]
- Barakat, A.R.; Sutcliffe, N.; Schwab, M. Effect site concentration during propofol TCI sedation: A comparison of sedation score with two pharmacokinetic models. Anaesthesia 2007, 62, 661–666. [Google Scholar] [CrossRef]
- Nieuwenhuijs, D.J.; Olofsen, E.; Romberg, R.R.; Sarton, E.; Ward, D.; Engbers, F.; Vuyk, J.; Mooren, R.; Teppema, L.J.; Dahan, A. Response surface modeling of remifentanil-propofol interaction on cardiorespiratory control and bispectral index. Anesthesiology 2003, 98, 312–322. [Google Scholar] [CrossRef]
- Koo, B.N.; Lee, J.R.; Noh, G.J.; Lee, J.H.; Kang, Y.R.; Han, D.W. A pharmacodynamic analysis of factors affecting recovery from anesthesia with propofol-remifentanil target controlled infusion. Acta Pharmacol. Sin. 2012, 33, 1080–1084. [Google Scholar] [CrossRef]
- Struys, M.M.; Vanpeteghem, C.; Huiku, M.; Uutela, K.; Blyaert, N.B.; Mortier, E.P. Changes in a surgical stress index in response to standardized pain stimuli during Propofol-Remifentanil infusion. Br. J. Anesth. 2007, 99, 359–367. [Google Scholar] [CrossRef]
- Ledowski, T.; Burke, J.; Hruby, J. Surgical pleth index: Prediction of postoperative pain and influence of arousal. Br. J. Anaesth. 2016, 117, 371–374. [Google Scholar] [CrossRef]
- Bergmann, I.; Göhner, A.; Crozier, T.A.; Hesjedal, B.; Wiese, C.H.; Popov, A.F.; Bauer, M.; Hinz, J.M. Surgical pleth index-guided Remifentanil administration reduces Remifentanil and Propofol consumption and shortens recovery times in out-patient anesthesia. Br. J. Anaesth. 2013, 110, 622–628. [Google Scholar] [CrossRef]
- Sanders, R.D.; Tononi, G.; Laureys, S.; Sleigh, J.W. Unresponsiveness ≠ unconsciousness. Anesthesiology 2012, 116, 946–959. [Google Scholar] [CrossRef]
- Soehle, M.; Dittmann, A.; Ellerkmann, R.K.; Baumgarten, G.; Putensen, C.; Guenther, U. Intraoperative burst suppression is associated with postoperative delirium following cardiac surgery: A prospective, observational study. BMC Anesthesiol. 2015, 15, 61. [Google Scholar] [CrossRef]
- Hozo, S.P.; Djulbegovic, B.; Hozo, I. Estimating the mean and variance from the median, range, and the size of a sample. BMC Med. Res. Methodol. 2005, 5, 13. [Google Scholar] [CrossRef]
- Kim, H.Y. Statistical notes for clinical researchers: Chi-squared test and Fisher’s exact test. Restor. Dent. Endod. 2017, 42, 152–155. [Google Scholar] [CrossRef]
- Sauer, B.C.; Brookhart, M.A.; Roy, J.; VanderWeele, T. A review of covariate selection for non-experimental comparative effectiveness research. Pharmacoepidemiol. Drug Saf. 2013, 22, 1139–1145. [Google Scholar] [CrossRef]
- Thomson, A.J.; Nimmo, A.F.; Engbers, F.H.; Glen, J.B. A novel technique to determine an ‘apparent ke0’ value for use with the Marsh pharmacokinetic model for propofol. Anaesthesia 2014, 69, 420–428. [Google Scholar] [CrossRef]
- Sepúlveda, P.O.; Cortínez, L.I.; Recart, A.; Muñoz, H.R. Predictive ability of propofol effect-site concentrations during fast and slow infusion rates. Acta Anaesthesiol. Scand. 2010, 54, 447–452. [Google Scholar] [CrossRef]
- Simoni, R.F.; Esteves, L.O.; Miziara, L.E.D.P.G.; Cangiani, L.M.; Alves, G.G.O.; Romano, A.L.P.; Hansen, P.Ú.; Vianna, P.T.G. Clinical evaluation of two Ke0 in the same pharmacokinetic propofol model: Study on loss and recovery of consciousness. Rev. Bras. Anestesiol. 2011, 61, 397–408. [Google Scholar] [CrossRef]
- Seo, J.H.; Goo, E.K.; Song, I.A.; Park, S.H.; Park, H.P.; Jeon, Y.T.; Hwang, J.W. Influence of a modified propofol equilibration rate constant (k(e0)) on the effect-site concentration at loss and recovery of consciousness with the Marsh model. Anaesthesia 2013, 68, 1232–1238. [Google Scholar] [CrossRef]
- Sepúlveda, P.O.; Carrasco, E.; Tapia, L.F.; Ramos, M.; Cruz, F.; Conget, P.; Olivares, Q.F.B.; Cortínez, I. Evidence of hysteresis in propofol pharmacodynamics. Anaesthesia 2018, 73, 40–48. [Google Scholar] [CrossRef]
- Proekt, A.; Kelz, M.B. Explaining anaesthetic hysteresis with effect-site equilibration. Br. J. Anaesth. 2021, 126, 265–278. [Google Scholar] [CrossRef]
- Glen, J.B.; Engbers, F.H. The influence of target concentration, equilibration rate constant (ke0) and pharmacokinetic model on the initial propofol dose delivered in effect-site target-controlled infusion. Anaesthesia 2016, 71, 306–314. [Google Scholar] [CrossRef]
- Carron, M.; Bertoncello, F.; Ieppariello, G. Profile of sugammadex for reversal of neuromuscular blockade in the elderly: Current perspectives. Clin. Interv. Aging 2017, 13, 13–24. [Google Scholar] [CrossRef]
- Linassi, F.; Kreuzer, M.; Maran, E.; Farnia, A.; Zanatta, P.; Navalesi, P.; Carron, M. Age influences on Propofol estimated brain concentration and entropy during maintenance and at return of consciousness during total intravenous anesthesia with target-controlled infusion in unparalyzed patients: An observational prospective trial. PLoS ONE 2020, 15, e0244145. [Google Scholar] [CrossRef]
- Evered, L.A.; Chan, M.T.; Han, R.; Chu, M.H.; Cheng, B.P.; Scott, D.A.; Pryor, K.O.; Sessler, D.I.; Veselis, R.; Frampton, C.; et al. Anaesthetic depth and delirium after major surgery: A randomised clinical trial. Br. J. Anaesth. 2021, 127, 704–712. [Google Scholar] [CrossRef]
- Linassi, F.; Maran, E.; Spano, L.; Zanatta, P.; Carron, M. Anaesthetic depth and delirium after major surgery. Comment on Br J Anaesth 2022; 127: 704–12. Br. J. Anaesth. 2022, 129, e33–e35. [Google Scholar] [CrossRef]
- Linassi, F.; Maran, E.; Kreuzer, M.; Zanatta, P.; Carron, M. Intraoperative electroencephalographic burst suppression may help to identify patients at risk for long-term adverse outcome: Findings from a case of homozygous twins. Anaesth. Crit. Care Pain Med. 2020, 39, 629–630. [Google Scholar] [CrossRef]
- Fritz, B.A.; King, C.R.; Ben Abdallah, A.; Lin, N.; Mickle, A.M.; Budelier, T.P.; Oberhaus, J.; Park, D.; Maybrier, H.R.; Wildes, T.S.; et al. Preoperative Cognitive Abnormality, Intraoperative Electroencephalogram Suppression, and Postoperative Delirium: A Mediation Analysis. Anesthesiology 2020, 132, 1458–1468. [Google Scholar] [CrossRef]
- Ni, K.; Cooter, M.; Gupta, D.K.; Thomas, J.; Hopkins, T.J.; Miller, T.E.; James, M.L.; Kertai, M.D.; Berger, M. Paradox of age: Older patients receive higher age-adjusted minimum alveolar concentration fractions of volatile anaesthetics yet display higher bispectral index values. Br. J. Anaesth. 2019, 123, 288–297. [Google Scholar] [CrossRef]
- Bouillon, T.W.; Bruhn, J.; Radulescu, L.; Andresen, C.; Shafer, T.J.; Cohane, C.; Shafer, S.L. Pharmacodynamic interaction between propofol and remifentanil regarding hypnosis, tolerance of laryngoscopy, bispectral index, and electroencephalographic approximate entropy. Anesthesiology 2004, 100, 1353–1372. [Google Scholar] [CrossRef]
Figure 1.
STROBE flow diagram.
Figure 2.
Comparison of CePs between the Eleveld and the Schnider PK/PD models across four time points during BIS-guided TIVA-TCI anesthesia in the total population of patients.
Figure 2.
Comparison of CePs between the Eleveld and the Schnider PK/PD models across four time points during BIS-guided TIVA-TCI anesthesia in the total population of patients.
Table 1.
Comparison between Schnider PK-PD model group and Eleveld PK-PD model group in total population of patients, adults, and elders.
Table 1.
Comparison between Schnider PK-PD model group and Eleveld PK-PD model group in total population of patients, adults, and elders.
| Variable | Total Population | Adults (18–64 yrs) | Elders (≥65 yrs) | ||||||
|---|---|---|---|---|---|---|---|---|---|
| Schnider 39 Patients | Eleveld 39 Patients | p-Value | Schnider 17 Patients | Eleveld 20 Patients | p-Value | Schnider 22 Patients | Eleveld 19 Patients | p-Value | |
| Age, yrs | 66 [61–71] | 63 [58–71] | 0.631 | 60 [52–62] | 58 [54–60] | 0.625 | 69 [67–73.7] | 71 [69–75.5] | 0.487 |
| 22 (56.4) | 19 (48.7) | 0.650 | 0 (0) | 0 (0) | 1.00 | 22 (100) | 19 (100) | 1.00 |
| Weight, kg | 66 [61–75] | 65 [57–70] | 0.509 | 66 [58–71] | 62 [56.7–67.2] | 0.352 | 65 [62–77] | 69 [59–74] | 0.979 |
| Height, cm | 165 [160–168] | 164 [160–167.5] | 0.609 | 166 [160–170] | 164 [160–170] | 0.609 | 164 [160–167.7] | 164 [160–165.5] | 0.753 |
| BMI, kg/m2 | 24.2 [22.6–27.6] | 23.9 [21.2–27.3] | 0.586 | 22 [22.5–27.4] | 23.7 [20.2–25.1] | 0.657 | 25.5 [23–28.8] | 24.4 [23.1–28] | 0.764 |
| 4 (10.3) | 5 (12.8) | 1.00 | 0 (0.0) | 2 (10) | 0.489 | 4 (18.2) | 3 (15.8) | 1.00 |
| ASA, n (%) | |||||||||
| 9 (23.1) | 7 (17.9) | 9 (52.9) | 7 (35) | 0 (0.0) | 0 (0.0) | |||
| 30 (74.4) | 32 (74.4) | 8 (47.1) | 12 (60) | 21 (95.5) | 17 (89.5) | |||
| 1 (2.6) | 3 (7.7) | 0 (0) | 1 (5) | 1 (4.5) | 2 (10.5) | |||
| Propofol total dose, mg | 522 [399.5–600.7] | 512.6 [406.3–631.3] | 0.893 | 527.2 [422.8–628.1] | 502 [454.5–666.4] | 0.831 | 508.8 [398.2–572.4] | 533.4 [378.9–571.7] | 0.937 |
| Surgery time, min | 44 [35–60] | 45 [33–63.5] | 0.853 | 43 [34–84] | 48 [34.7–71.2] | 0.891 | 46 [37.7–56.2] | 44 [33–51] | 0.488 |
| Anesthesia time, min | 62 [55–87.5] | 66 [53–78] | 0.764 | 60 [55–110] | 80 [57.5–98] | 0.795 | 63.5 [60.2–77.2] | 65 [51–73.5] | 0.425 |
| LoR | |||||||||
| BIS baseline | 97 [97–98] | 97 [97–98] | 0.727 | 97 [97–98] | 98 [97–98] | 0.213 | 97.5 [96–98] | 97 [96.5–98] | 0.620 |
| CeP at LoR, μg/mL | 3.60 [3.00–4.18] | 1.7 [1.36–2.25] | <0.001 | 3.50 [2.65–4.07] | 1.88 [1.38–2.32] | 0.001 | 3.70 [3.06–4.27] | 1.6 [1.29–1.99] | <0.001 |
| CeR at LoR, ng/mL | 0.8 [0.8–0.8] | 0.8 [0.8–0.8] | 1.00 | 0.8 [0.8–0.8] | 0.8 [0.8–0.8] | 1.00 | 0.8 [0.8–0.8] | 0.8 [0.8–0.8] | 1.00 |
| BIS at LoR | 80 [76.2–83] | 77.5 [62.5–81.7] | 0.036 | 80 [77–84] | 73 [62–79.5] | 0.036 | 80 [76–83] | 79.5 [72.2–82.7] | 0.641 |
| Anesthesia maintenance | |||||||||
| CePMA1, μg/mL | 2.40 [1.80–2.65] | 3.10 [2.75–3.50] | <0.001 | 2.20 [2.20–2.70] | 2.95 [2.88–3.28] | <0.001 | 2.40 [1.80–2.50] | 3.30 [2.65–3.50] | <0.001 |
| CeRMA1, ng/mL | 3.00 [3.00–3.00] | 3.00 [3.00–3.00] | 0.519 | 3.00 [3.00–3.00] | 3.00 [3.00–3.00] | 0.326 | 3.00 [3.00–3.00] | 3.00 [3.00–3.00] | 0.879 |
| BIS at CePMA1 | 46 [43–50] | 48 [44–52] | 0.183 | 48 [43–50] | 48 [45.7–50.5] | 0.324 | 46 [43.2–49.5] | 48 [44–52] | 0.598 |
| Time to CePMA1, min | 24 [20–31.5] | 22 [18.5–28.5] | 0.246 | 25 [21–33] | 20.5 [19–29.2] | 0.418 | 23.5 [20–30.5] | 22 [17–27.5] | 0.440 |
| CePMA2, μg/mL | 2.30 [1.80–2.50] | 2.80 [2.55–3.40] | <0.001 | 2.20 [2.20–2.60] | 2.90 [2.68–3.28] | 0.001 | 2.40 [1.80–2.50] | 2.70 [2.40–3.40] | 0.003 |
| CeRMA2, ng/mL | 3.00 [3.00–3.00] | 3.00 [3.00–3.00] | 0.535 | 3.00 [3.00–3.00] | 3.00 [3.00–3.00] | 0.484 | 3.00 [3.00–3.00] | 3.00 [3.00–3.00] | 0.916 |
| BIS at CePMA2 | 46 [43–51] | 48 [44–50] | 0.625 | 48 [43–50] | 48 [45.7–48.5] | 0.665 | 46 [44–51] | 47 [44–50] | 0.906 |
| RoR | |||||||||
| CeP at RoR, μg/mL | 0.64 [0.55–0.81] | 1.48 [1.08–1.80] | <0.001 | 0.75 [0.61–0.84] | 1.48 [1.21–1.76] | <0.001 | 0.60 [0.53–0.73] | 1.44 [1.08–1.95] | <0.001 |
| CeR at RoR, ng/mL | 0.59 [0.50–0.70] | 0.60 [0.50–0.77] | 0.637 | 0.50 [0.50–0.67] | 0.59 [0.49–0.76] | 0.794 | 0.59 [0.50–0.72] | 0.65 [0.50–0.88] | 0.669 |
| BIS at RoR | 71 [63–77] | 75 [70–80.7] | 0.075 | 66 [60–74] | 75 [69.7–82] | 0.049 | 72 [70–77.7] | 75.5 [70.2–78] | 0.531 |
| Time to RoR, min | 9 [7–12] | 10 [8–12] | 0.116 | 8 [7–10] | 11 [9–13.5] | 0.047 | 9 [7–12] | 9 [8–11] | 0.958 |
| Δ CeP, μg/mL | 2.84 [2.28–3.48] | 0.58 [0.26–0.98] | <0.001 | 2.65 [2.02–2.87] | 0.58 [0.21–1.02] | <0.001 | 3.04 [2.56–3.56] | 0.58 [0.33–0.98] | <0.001 |
| Unwanted events | |||||||||
| DAE, n (%) | 12 (30.8) | 27 (69.2) | 0.001 | 6 (35.3) | 15 (75) | 0.022 | 6 (27.3) | 12 (63.2) | 0.030 |
| BSE, n (%) | 2 (5.1) | 11 (28.2) | 0.013 | 1 (5.9) | 5 (25) | 0.189 | 1 (4.5) | 6 (31.6) | 0.036 |
| LAE, n (%) | 1 (2.6) | 2 (5.1) | 1.00 | 0 (0.0) | 2 (10) | 0.489 | 1 (4.5) | 0 (0.0) | 1.00 |
| USRE, n (%) | 1 (2.6) | 2 (5.1) | 1.00 | 0 (0.0) | 2 (10) | 0.489 | 1 (4.5) | 0 (0.0) | 1.00 |
BMI: body mass index; ASA: American Society of Anesthesiologists physical status classification; BIS: bispectral index; CeP: concentrations at the effect site (Ce) of propofol; LoR: loss of responsiveness; CePMA1: initial CeP during maintenance of anesthesia (MA); CePMA2: final CeP during MA; RoR: return of responsiveness; Δ CeP: difference between CeP LoR and CeP ROR; LAE: lightening of anesthesia event; USRE: unwanted spontaneous responsiveness event; DAE: deepening of anesthesia event; BSE: burst suppression event. The bold identifies the different phases of anesthesia or the adverse events section, or the significant variables.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. |
© 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Linassi, F.; Zanatta, P.; Spano, L.; Burelli, P.; Farnia, A.; Carron, M. Schnider and Eleveld Models for Propofol Target-Controlled Infusion Anesthesia: A Clinical Comparison. Life 2023, 13, 2065. https://doi.org/10.3390/life13102065
AMA Style
Linassi F, Zanatta P, Spano L, Burelli P, Farnia A, Carron M. Schnider and Eleveld Models for Propofol Target-Controlled Infusion Anesthesia: A Clinical Comparison. Life. 2023; 13(10):2065. https://doi.org/10.3390/life13102065
Chicago/Turabian StyleLinassi, Federico, Paolo Zanatta, Leonardo Spano, Paolo Burelli, Antonio Farnia, and Michele Carron. 2023. "Schnider and Eleveld Models for Propofol Target-Controlled Infusion Anesthesia: A Clinical Comparison" Life 13, no. 10: 2065. https://doi.org/10.3390/life13102065
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
