Carotid Blood Flow as a Surrogate for Pulse Contour Analysis in Assessment of Fluid Responsiveness: A Prospective, Observational, Single-Centre Study (Contour Study).

Background and objectives The quest for an accurate and reliable non-invasive method of assessing cardiac output in critically ill patients is still ongoing. Carotid artery Doppler is a promising non-invasive, reproducible, and feasible bedside monitor. So we compared the change in cardiac output derived from arterial pressure waveforms (pulse contour analysis) with that from carotid artery Doppler-derived measurements, in post-major elective abdominal surgery patients. Materials and methods We conducted a prospective observational study in 30 adult post-major elective abdominal surgery patients admitted to the Gastroenterology and Liver Transplant intensive care unit postoperatively on mechanical ventilator support, who were found to be fluid responsive clinically on passive leg raise (PLR) test. Demographics and vasopressor support were recorded. Hemodynamic parameters including heart rate, systolic blood pressure (SBP), diastolic blood pressure (DBP), cardiac output (CO) using arterial pulse contour analysis (Vigileo monitor/FloTrac® sensor; Edwards Lifesciences, Irvine, California, United States), and carotid blood flow (CBF) were recorded on the baseline, pre- and post- PLR, and post fluid bolus administration. Balanced salt solution at the rate of 6ml/kg over 20 minutes was given as a fluid bolus. Results Of the 30 patients who were included in the study, 16 patients (53.3%) were on vasopressor support, mean (± SD) age of the patients was 52.93 (± 8.13) years. There was a significant increase in the SBP (mmHg) pre- to post-PLR, that is, 112.2±15.57 and 118.7±14.96, respectively (p-value = 0.001). Also from pre-PLR to post-fluid bolus administration, the increase in SBP was significant, 112.2±15.57 and 121.93±13.96, respectively (p-value = 0.001). The change in cardiac output measured using Vigileo and CBF from pre- to post-PLR (7.66±1.45 to 9.14±1.76, p< 0.001 for Vigileo and 8.10±1.66 to 9.72±1.99, p<0.001 for CBF) and pre-PLR to post fluid administration (7.66±1.45 to 9.39±1.77, p< 0.001 for Vigileo and 8.10±1.66 to 10.31±2.26, p< 0.001 for CBF) were significant. There was a positive correlation between the change in cardiac output as measured from arterial pulse contour analysis technique (Vigileo) and that measured from CBF (r=0.884) pre- and post-PLR. There was a significant correlation between cardiac output measurements derived from two techniques, before PLR, after PLR, and after fluid expansion (p< 0.001 for each variable). The change in cardiac output before PLR and after fluid expansion was also correlated by both the techniques (correlation coefficient being, r=0.781). Conclusion There was a significant positive correlation of the CO (absolute and change) measurements pre- and post-interventions (that is, PLR and fluid bolus administration) as made by pulse contour analysis (Vigileo) and by CBF in post-surgical patients. Pulse wave Doppler of CBF could be used as a surrogate for invasive measures of CO measurement for prediction of fluid responsiveness in this subgroup. Further larger studies can be performed to validate the same.

Intraoperative cardiac function assessment by transesophageal echocardiography versus FloTrac/Vigileo™ system during pectus excavatum surgical repair.

BACKGROUND: Pectus excavatum (PE), a congenital deformity of the chest wall, can lead to cardiac compression and related symptoms. PE surgical repair can improve cardiac function. Intraoperative transesophageal echocardiography (TEE) has been successfully employed to assess intraoperative hemodynamic variations in patients undergoing PE repair. FloTrac/Vigileo™ system (Edwards Life-sciences Irvine, CA) (FT/V) is a minimally invasive cardiac output monitoring system. This retrospective study aimed to assess hemodynamic changes in surgical repair of PE using FT/V and concordance with parameters measured by TEE. RESULTS: N=19 patients submitted to PE repair via Ravitch or Nuss technique were enrolled. Intraoperative cardiac assessments simultaneously obtained via TEE and FT/V system were investigated. The agreement between TEE-derived cardiac output (CO-TEE) and FT/V system parameter (COAP) was evaluated. The relationship between COTEE and COAP was analyzed for all data using linear regression analysis. A significant correlation between COAP and COTEE values (R = 0.65, p < 0.001) was found. Bland-Altman analysis of COAP and COTEE showed a bias of 0.13 L/min and a limit of agreement of - 2.33 to 2.58 L/min, with a percentage error of 48%. Intraoperative measurements by TEE and FT/V both showed a significant increase in CO after surgical correction of PE (p < 0.005). CONCLUSIONS: FT/V system compared to TEE in hemodynamic monitoring during PE surgery yielded clinically unacceptable results due to a high percentage error. After surgical correction of PE, CO, measured by TEE and FT/V, significantly improved.

Comparing the Mutual Interchangeability of ECOM, FloTrac/Vigileo, 3D-TEE, and ITD-PAC Cardiac Output Measuring Systems in Coronary Artery Bypass Grafting.

OBJECTIVE: The aim of this study was to compare the mutual interchangeability of 4 cardiac output measuring devices by comparing their accuracy, precision, and trending ability. DESIGN: A single-center prospective observational study. DESIGN: Nonuniversity teaching hospital, single center. PARTICIPANTS: Forty-four consecutive patients scheduled for elective, nonemergent coronary artery bypass grafting (CABG). INTERVENTIONS: The cardiac output was measured for each participant using 4 methods: intermittent thermodilution via pulmonary artery catheter (ITD-PAC), Endotracheal Cardiac Output Monitor (ECOM), FloTrac/Vigileo System (FLOTRAC), and 3-dimensional transesophageal echocardiography (3D-TEE). MEASUREMENTS AND MAIN RESULTS: Measurements were performed simultaneously at 5 time points: presternotomy, poststernotomy, before cardiopulmonary bypass, after cardiopulmonary bypass, and after sternal closure. A series of statistical and comparison analyses including ANOVA, Pearson correlation, Bland-Altman plots, quadrant plots, and polar plots were performed, and inherent precision for each method and percent errors for mutual interchangeability were calculated. For the 6 two-by-two comparisons of the methods, the Pearson correlation coefficients (r), the percentage errors (% error), and concordance ratios (CR) were as follows: ECOM_versus_ITD-PAC (r = 0.611, % error = 53%, CR = 75%); FLOTRAC_versus_ITD-PAC (r = 0.676, % error = 49%, CR = 77%); 3D-TEE versus ITD-PAC (r = 0.538, % error = 64%, CR = 67%); FLOTRAC_versus_ECOM (r = 0.627, % error = 51%, CR = 75%); 3D-TEE_versus ECOM (r = 0.423, % error = 70%, CR = 60%), and 3D-TEE_versus_FLOTRAC (r = 0.602, % error = 59%, CR = 61%). CONCLUSIONS: Based on the recommended statistical measures of interchangeability, ECOM, FLOTRAC, and 3D-TEE are not interchangeable with each other or to the reference standard invasive ITD-PAC method in patients undergoing nonemergent cardiac bypass surgery. Despite the negative result in this study and the majority of previous studies, these less-invasive methods of CO have continued to be used in the hemodynamic management of patients. Each device has its own distinct technical features and inherent limitations; it is clear that no single device can be used universally for all patients. Therefore, different methods or devices should be chosen based on individual patient conditions, including the degree of invasiveness, measurement performance, and the ability to provide real-time, continuous CO readings.

The association between arterial pulse waveform analysis device and in-hospital mortality in high-risk non-cardiac surgeries.

BACKGROUND: Perioperative goal-directed fluid therapy is used for haemodynamic optimization in high-risk surgeries. Cardiac output monitoring can be performed by a specialized pressure transducer for arterial pulse waveform analysis (S-APWA). No study has assessed whether real-world use of S-APWA is associated with post-operative outcomes; therefore, using a Japanese administrative claims database, we retrospectively investigated whether S-APWA use is associated with in-hospital mortality among patients undergoing high-risk surgery under general anaesthesia. METHODS: Adult patients who underwent high-risk surgery under general anaesthesia and arterial catheterization between 2014 and 2016 were divided into S-APWA and conventional arterial pressure transducer groups, then compared regarding baseline factors and outcomes. Logistic regression analysis was performed to compare in-hospital mortality. Subgroup analyses evaluated S-APWA efficacy and outcomes based on the type of surgery and patients' comorbidity. RESULTS: S-APWA was used in 6859 of 23 655 (29.0%) patients; the crude in-hospital mortality rate was 3.5%. Adjusted analysis showed no significant association between S-APWA use and in-hospital mortality rate (adjusted odds ratio [aOR] = 0.91; 95% confidence interval [CI]: 0.76-1.07; P = .25). S-APWA use was associated with significantly lower in-hospital mortality in patients undergoing vascular surgery (aOR = 0.67; 95% CI: 0.49-0.94), and significantly higher in-hospital mortality in patients undergoing lower limb amputation (aOR = 2.63; 95% CI: 1.32-5.22). S-APWA use and in-hospital mortality were not significantly associated with other subgroups. CONCLUSION: S-APWA use was not associated with in-hospital mortality in the entire study population. However, S-APWA was associated with decreased in-hospital mortality among vascular surgery and increased in-hospital mortality among lower limb amputation.

Utilization of arterial pulse waveform analysis during non-cardiac surgery in Japan: a retrospective observational study using a nationwide claims database.

Arterial pulse waveform analysis (APWA) is used for cardiac output monitoring. However, data on the frequency of and patient characteristics for specialized pressure transducer for APWA (S-APWA) use are lacking. We retrospectively identified 175,201 patients aged 18 years or older, who underwent non-cardiac surgery under general anesthesia with an arterial catheter from January 1, 2014, to December 31, 2016. We extracted data on patient demographics, comorbidities, surgical and anesthesia characteristics, and hospital characteristics. Among the full study cohort, 24,605 (14.0%) patients were monitored using S-APWA. Further, the use of S-APWA was higher in patients undergoing high-risk surgery than in those undergoing low-risk surgery [high vs low: adjusted odds ratio (aOR) 1.95; 95% confidence interval (CI) 1.76-2.15, moderate vs low: aOR 1.11; 95% CI 1.01-1.22] and those with more comorbidities than in those with less comorbidities (high vs low: aOR 1.49; 95% CI 1.42-1.56, moderate vs low: aOR 1.25; 95% CI 1.20-1.31). S-APWA use was significantly associated with both surgery risk and patients' comorbidities. In conclusion, our study may provide a benchmark for future studies related to the appropriate use of S-APWA.

Evaluation of the Fourth-Generation FloTrac/Vigileo System in Comparison With the Intermittent Bolus Thermodilution Method in Patients Undergoing Cardiac Surgery.

OBJECTIVES: The aim of this study was to evaluate the accuracy, precision, and trending ability of the fourth-generation FloTrac/Vigileo system (version 4.00; Edwards Lifesciences, Irvine, CA) by comparing cardiac output derived from FloTrac/Vigileo system (COAP) with that measured by a pulmonary artery catheter (COTD), and to determine the effects of hemodynamic variables on the bias between COTD and COAP. DESIGN: A prospective study. SETTING: University hospital. PARTICIPANTS: Thirty patients undergoing elective cardiac surgery using cardiopulmonary bypass. INTERVENTIONS: Including hemodynamic variables, COTD and COAP were measured simultaneously at the following 10 time points: after the induction of anesthesia, at the start of operation, after sternotomy, before and after the administration of heparin, before and after the administration of protamine, at the start of sternal closure, at the end of operation, and on arrival to intensive care unit. MEASUREMENTS AND MAIN RESULTS: In total, 280 pairs of datasets were obtained. Bland-Altman analysis showed a bias of -0.41 L/min, a precision of 0.72 L/min, and limits of agreement of -1.85 and 1.03 L/min, with a percentage error of 37.1%. The concordance rate determined by 4-quadrant plot analysis and the polar concordance rate were 76% and 79%, respectively. The linear mixed-effect model revealed that the bias was influenced strongly by the difference in pulse pressure between the radial and femoral artery (p < 0.001), and the systemic vascular resistance index (p < 0.001). CONCLUSION: The fourth-generation FloTrac/Vigileo system still lacks accuracy and trending ability in cardiac surgery, and the discrepancy in cardiac output measurement depends on the peripheral vascular tone. Further improvement of this system is needed.

Clinical Applications of Goal-Directed Fluid Therapy for Pancreatoduodenectomy / 中国医科大学学报

Objective To investigate the clinical applications of goal-directed fluid therapy for pancreatoduodenectomy. Methods A total of 40 patients undergoing pancreatoduodenectomy under general anesthesia were randomly divided into two groups, G and C, with 20 cases in each group. Goal-directed fluid therapy was used in Group G, whereas conventional fluid therapy was used in group C. The intraoperative hemodynamics, liquid management, duration of the first postoperative gastrointestinal ventilation, postoperative renal function, serum lactate, and the incidence of postoperative complications were recorded. Results Compared with group C, the CI increased and SVV decreased (P ＜ 0.05) at T3 to T5, and MAP increased at T4 to T5 (P ＜ 0.05). The amount of fluid infusion and total infusion in group G were less than that of group C (P ＜ 0.05), and the number of vasoactive drugs was greater than that of group C (P ＜ 0.05). The duration of the first postoperative gastrointestinal ventilation in group G was shorter than that of group C (P ＜ 0.05). There were no significant differences between the 2 groups for the incidence of serum lactate, BUN, Cr, and the incidence of postoperative complications (P＞ 0.05).Conclusion For major complex operations, such as pancreaticoduodenectomy, goal-directed fluid therapy can guide intraoperative fluid therapy more accurately with individual optimizations, and has more advantages in maintaining intraoperative hemodynamics stability and improving postoperative outcome.

Effect of goal-directed fluid therapy on the volume and coagulation function in patients with placenta pre-via during perioperative period / 实用医学杂志

Objective To investigate the therapeutic effect of goal-directed fluid therapy on perioperative volume therapy in patients with placenta previa during perioperative period. Methods Eighty patients undergoing cesarean section were randomly divided into 2 groups(n=40 in each group):the conventional therapy group(N group)and the target management of resuscitation group(G group). Patients in G group were connected the Flo-Trac/Vigileo monitoring system to obtain the information of△SV and CI which were used to guide goal-directed flu-id therapy. Hemodynamics,blood coagulation indexes and lactic acid content in different periods of operation were recorded. Results Compared with N group,colloid infusion volume,HR,△SV,the amount of phenylephrine, PT,APTT and TT were decreased,but urine volume,CVP,CI and MBP of each time point and FIB were mark-edly increased(P < 0.05,respectively). Conclusion The application of FloTrac/Vigileo monitoring system for goal-directed fluid therapy,real-time monitor and effectively maintain hemodynamics in patients with dangerous placenta previa during perioperative period,which can improve the postoperative coagulation function and is better than the conventional rehydration capacity.

Application of FloTrac/Vigileo system in monitoring hemodynamics of single lung ventilation / 临床麻醉学杂志

Objective To explore the feasibility of FloTrac/Vigileo System in hemodynamic monitoring during the surgery of single-lung ventilation patients.Methods Twenty-five patients with thoracoscopic lobectomy under general anesthesia,aged 35-65 years,ASA physical status Ⅰ or Ⅱ, preoperative showed no application taboo of FloTrac/Vigileo system or transesophageal echocardio-graphy (TEE).The radial artery puncture catheter was inserted after getting into the operating room, then connect the FloTrac/Vigileo system,after that the TEE was inserted following the induction of general anesthesia.Using the FloTrac/Vigileo system to record the stroke volume (SVF),cardiac output (COF),stroke volume variation (SVV),at the moment of after turning over (T0),opening chest and single-lung ventilation(T1),single-lung ventilation for 15 minutes (T2),single-lung venti-lation for 30 minutes (T3),single-lung ventilation for 45 minutes (T4)single-lung ventilation for 60 minutes (T5).Using TEE to monitor the index and record the the stroke volume (SVT)cardiac out-put(COT)and inferior vena cava collapse index(cIVC)of the same patient at same time as Group F. Results There was no statistically significant different between SVFand SVTat T0-T5in both groups,Overall correlation analysis,r=0.84,P<0.01.There is no statistically significant different between COFand COTat T0-T5in both groups,Overall correlation analysis,r=0.92,P<0.01. Correlation analysis of SVV of group F and cIVC of group T,the results were positively correlate,r=0.80,P<0.01.Conclusion FloTrac/Vigileo system can be used as a monitoring method for mo-nitoring hemodynamics in thoracic surgery.

Effective evaluation of arterial pulse waveform analysis by two-dimensional stroke volume variation-stroke volume index plots.

Arterial pulse waveform analysis (APWA) with a semi-invasive cardiac output monitoring device is popular in perioperative hemodynamic and fluid management. However, in APWA, evaluation of hemodynamic data is not well discussed. In this study, we analyzed how we visually interpret hemodynamic data, including stroke volume variation (SVV) and stroke volume (SV) derived from APWA. We performed arithmetic estimation of the SVV-SV relationship and applied measured values to this estimation. We then collected measured values in six anesthesia cases, including three liver transplantations and three other types of surgeries, to apply them to this SVV-SVI (stroke volume variation index) plot. Arithmetic analysis showed that the relationship between SVV and SV can be drawn as hyperbolic curves. Plotting SVV-SV values in the semi-logarithmic scale showed linear correlations, and the slopes of the linear regression lines theoretically represented average mean cardiac contractility. In clinical measurements in APWA, plotting SVV and SVI values in the linear scale and the semi-logarithmic scale showed the correlations represented by hyperbolic curves and linear regression lines. The plots approximately shifted on the rectangular hyperbolic curves, depending on blood loss and blood transfusion. Arithmetic estimation is close to real measurement of the SVV-SV interaction in hyperbolic curves. In APWA, using SVV as an index of preload and the cardiac index or SVI derived from arterial pressure-based cardiac output as an index of cardiac function, is likely to be appropriate for categorizing hemodynamic stages as a substitute for Forrester subsets.

Effect of operation position change on heart index and stroke volume variation in patients monitored by FloTrac/Vigileo system / 重庆医学

Objective To investigate the effect of different operation positions on cardiac index (CI) and stroke volume variation (SVV) in the patients monitored by FloTrac/Vigileo system to provide some references for the hemodynamic management and liquid treatment of the patients.Methods Sixty patients scheduled for elective TV auxiliary thoracoscope radical operation of esophageal cancer.The CI and SVV changes were observed by using the FloTrac/Vigileo system.CI,SVV and CVP were recorded at 5 min after anesthesia induction (T0),5 min after converting to the position of head low feet high (T1),5 min after converting to the position of head high feet low (T2).Results Compared with T0,CI at T1 and T2 was decreased(P＜0.05);compared with T0,SVV at T1 was decreased and CVP was increased;SVV at T2 was increased and CVP was decreased(P＜0.05).Conclusion The operation position change may have a significant impact on the patient's CI,SVV and CVP.Focusing on the corresponding change can provide some references for the intraoperative hemodynamic management and liquid treatment.

The effects of different values of PEEP on heart index, stroke volume variation and oxygen transport index in patients monitored by FloTrac/Vigileo system / 天津医药

Objective To investigate the effects of different values of PEEP on cardiac index (CI), stroke volume variation (SVV) and oxygen transport index (DO2I) in patients monitored by FloTrac/Vigileo system, and to provide some references for the hemodynamic management and improvement of oxygenation for patients. Methods Sixty patients scheduled for elective television (TV) auxiliary thoracoscope radical operation for esophageal cancer were included in this study. Data of CI, SVV and DO2I were observed by the FloTrac/Vigileo system. Changes of CI, SVV and DO2I were recorded after anesthesia induction and turn left side (T0), artificial pneumothorax with 0 PEEP after 5 minutes (T1), artificial pneumothorax with 5 PEEP after 5 minutes (T2), artificial pneumothorax with 10 PEEP after 5 minutes (T3), and artificial pneumothorax with 15 PEEP after 5 minutes (T4). Results Compared with T0, CI decreased and SVV increased significantly at T1, T2, T3 and T4(P<0.05). Compared with T1, CI decreased and SVV increased at T4. DO2I increased at T2 and T3 compared with that of T1(P<0.05). Conclusion PEEP may have a certain influence on CI and SVV in the process of operation. The values of 5-10 PEEP can significantly improve oxygenation and have a less influence on hemodynamics, which can be appropriately used in clinical care.

Disagreement between fourth generation FloTrac and LiDCOrapid measurements of cardiac output and stroke volume variation during laparoscopic colectomy.

STUDY OBJECTIVE: To determine the agreement between cardiac output (CO) and stroke volume variation (SVV) measured simultaneously by the fourth generation FloTrac/Vigileo system and LiDCOrapid system during pneumoperitoneum in patients undergoing laparoscopic colectomy. DESIGN: Retrospective observational study. SETTINGS: Operating room in a general hospital. PATIENTS: Ten patients (American Society of Anesthesiologist 1 or 2) without preoperative anemia. INTERVENTIONS: A 22-gauge catheter was inserted in the radial artery after induction of anesthesia. The arterial line was split to monitor CO and SVV simultaneously with the LiDCOrapid and fourth generation FloTrac/Vigileo systems. All data were downloaded from each system after surgery and simultaneous paired COFloTrac, COLiDCO and SVVFloTrac, SVVLiDCO values estimated every 1 minute during the pneumoperitoneum were analyzed. MEASUREMENTS: To assess the agreement after carbon dioxide insufflation, a scatter 4-quadrant plot was generated using paired ΔCO values (changes in COFloTrac and COLiDCO just before pneumoperitoneum and 3 minutes after the induction of pneumoperitoneum). For data in which SVVFloTrac was >9% but <16% and cardiac index measured by FloTrac/Vigileo was <2.5 L/min per m2 during stable pneumoperitoneum (the period from 5 minutes after Trendelenburg position until discontinuation of pneumoperitoneum), simultaneously measured paired SVVFloTrac and SVVLiDCO were plotted every 1 minute using the Bland-Altman method. MAIN RESULTS: A concordance ratio for changes in CO after the induction of pneumoperitoneum was 83% in 4-quadrant plot. During stable pneumoperitoneum, 702 paired SVVFloTrac and SVVLiDCO matched the criteria. These data sets were plotted by the Bland-Altman method and the bias and 95% limit of agreement of SVV were 2.01 and -2.63% to 6.65%, respectively, with 38% percentage error. The regression equation was SVVLiDCO = 0.98 × SVVFloTrac- 1.73 with Pearson correlation coefficient of 0.55. CONCLUSIONS: Our study showed disagreement between the 2 methods and the hemodynamic parameters measured by one of the two devices should be interpreted with caution before therapeutic interventions.

Evaluation of the non-calibrated pulse contour cardiac output monitor FloTrac/Vigileo against thermodilution in standing horses.

OBJECTIVE: To evaluate the non-calibrated, minimally invasive cardiac output (CO) monitor FloTrac/Vigileo (FloTrac) against thermodilution (TD) CO in standing horses. STUDY DESIGN: Prospective, experimental trial. ANIMALS: Nine adult horses weighing a median (range) of 535 (470-602) kg. METHODS: Catheters were placed in the right atrium, pulmonary artery and carotid artery under local anaesthesia. CO was measured 147 times by TD and FloTrac and indexed to body weight. Changes in CO were achieved with romifidine or xylazine and dobutamine constant rate infusions. Bland-Altman analysis, concordance and polar plot analysis were used to assess agreement and ability to track changes in CO. RESULTS: Mean ± standard deviation COTD of 48 ± 16 mL kg(-1) minute(-1) (range: 19-93 mL kg(-1) minute(-1) ) and mean COF loTrac of 9 ± 3 mL kg(-1) minute(-1) (range: 5-21 mL kg(-1) minute(-1) ) were measured. Low agreement with a large mean bias of 39 mL kg(-1) minute(-1) and wide limits of agreement of 8-70 mL kg(-1) minute(-1) were found. The percentage error of 108% and precision of TD of ± 18% resulted in an estimated precision of FloTrac of ± 106%. Comparison of changes in COF loTrac with changes in COTD gave a concordance rate of 52% in the four-quadrant plot, and a mean polar angle of -11° with radial limits of agreement of ± 61 ° in the polar plot. Mean arterial pressure (MAP) and COF loTrac were positively correlated (r = 0.5, p < 0.0001). No correlation of MAP with COTD was observed. CONCLUSIONS AND CLINICAL RELEVANCE: The FloTrac system, originally designed for use in humans, neither measured absolute CO in standing horses accurately nor tracked relative changes in CO measured by TD correctly. The false dependence of COF loTrac on arterial blood pressure further discourages the use of this technique in horses.

Improved Performance of the Fourth-Generation FloTrac/Vigileo System for Tracking Cardiac Output Changes.

OBJECTIVES: The aims of this study were to compare cardiac output (CO) measured by the new fourth-generation FloTrac™/Vigileo™ system (Version 4.00) (COFVS) with that measured by a pulmonary artery catheter (COREF), and to investigate the ability of COFVS to track CO changes induced by increased peripheral resistance. DESIGN: Prospective study. SETTING: University Hospital. PARTICIPANTS: Twenty-three patients undergoing cardiac surgery. INTERVENTIONS: Phenylephrine (100 µg) was administered. MEASUREMENTS AND MAIN RESULTS: Hemodynamic variables, including CO(REF) and CO(FVS), were measured before and after phenylephrine administration. Bland-Altman analysis was used to assess the discrepancy between CO(REF) and CO(FVS). Four-quadrant plot and polar-plot analyses were utilized to evaluate the trending ability of CO(FVS) against CO(REF) after phenylephrine boluses. One hundred thirty-six hemodynamic interventions were performed. The bias shown by the Bland-Altman analysis was-0.66 L/min, and the percentage error was 55.4%. The bias was significantly correlated with the systemic vascular resistance index (SVRI) before phenylephrine administration (p<0.001, r(2) = 0.420). The concordance rate determined by four-quadrant plot analysis and the angular concordance rate calculated using polar-plot analysis were 87.0% and 83.0%, respectively. Additionally, this trending ability was not affected by SVRI state. CONCLUSIONS: The trending ability of the new fourth-generation FloTrac™/Vigileo™ system after increased vasomotor tone was greatly improved compared with previous versions; however, the discrepancy of the new system in CO measurement was not clinically acceptable, as in previous versions. For clinical application in critically ill patients, this vasomotor tone-dependent disagreement must be decreased.

Agreement between cardiac index measured with FloTrac-Vigileo system and pulmonary artery catheter in patients undergoing off-pump coronary artery bypass grafting / 中华麻醉学杂志

Objective To determine if the cardiac index (Cl) measured with FloTrac-Vigileo system agrees with that measured with pulmonary artery catheter (PAC).Methods Forty-three ASA Ⅱ or Ⅲ patients aged 53-75 yr weighing 46-100 kg undergoing off-pump coronary artery bypass grafting were included in this study.Anesthesia was induced with midazolam,sufentanil,propofol and rocuronium and maintained with propofol,remifentanil and atracurium.One MAC sevoflurane was inhaled at breast bone splitting and closing.Cl was measured with FloTrac-Vigileo system and PAC before,and at 5,15 min of sevoflurane inhalation and recorded.All data were compared by Bland-Altman analysis and with kappa coefficient for agreement and percentage error was calculated.Results Bland-Altman comparison of FloTrac-Vigileo system and PAC:matching data of 258 measurements:Cl (2.8 ± 0.6) L·min-1 ·m-2,bias was 0.23 L·min-1 ·m-2 and limit of agreement was (-0.57,1.02) L·min-1 ·m-2,resulting in κ =0.546 and an overall percentage error of 28.6％.Conclusion Cl values obtained by FloTrac-Vigileo system agrees well with that obtained by thermodilution technique using PAC in patients undergoing off-pump coronary artery bypass grafting.

The effect of the different position on hemodynamic monitored by FloTrac/Vigileo system in patients un-dergoing laparoscopic appendectomy / 临床麻醉学杂志

Objective To investigate the effect of the different position on hemodynamic moni-tored by FloTrac/Vigileo system in patients undergoing laparoscopic appendectomy.Methods Sixty patients undergoing laparoscopic appendectomy,ASA Ⅰ or Ⅱ,were randomly divided into three groups (n=20):group A,B and C underwent the trendelenburg position of 10 degrees,20 degrees and 30 degrees,respectively.HR,MAP,cardiac output (CO),cardiac index (CI)and stroke volume (SV)were recorded before pneumoperitoneum (T0 ),1 min after pneumoperitoneum (T1 ),5 min af-ter trendelenburg position (T2 ),20 min after pneumoperitoneum (T3 ),1 min after the end of pneu-moperitoneum (T4 )and 5 min after the end of trendelenburg position (T5 )after induction of anesthe-sia.The time of pneumoperitoneum and operation was recorded.Results Compared with T0 ,HR and MAP increased significantly at T1-T3 in three groups(P<0.05);Compared with group C,CO and SV decreased significantly at T2-T3 in group A and group B (P<0.05).Compared with T1 ,CO and SV increased at T2-T3 in group C (P<0.05).Compared with group C,the time of pneumoperitoneum and operation was longer in group A and B (P<0.05).Conclusion During the operation of laparo-scopic appendectomy,the change of the hemodynamic is in clinical safe range,and the time of pneu-moperitoneum and operation is shorter in the position of 30°than 10°and 20°in laparoscopic appen-dectomy.

Hemodynamic changes during robotic radical prostatectomy.

BACKGROUND: Effect on hemodynamic changes and experience of robot-assisted laparoscopic radical prostatectomy (RALRP) in steep Trendelenburg position (45°) with high-pressure CO(2) pneumoperitoneum is very limited. Therefore, we planned this prospective clinical trial to study the effect of steep Tredelenburg position with high-pressure CO(2) pneumoperitoneum on hemodynamic parameters in a patient undergoing RALRP using FloTrac/Vigileo™1.10. METHODS: After ethical approval and informed consent, 15 patients scheduled for RALRP were included in the study. In the operation room, after attaching standard monitors, the radial artery was cannulated. Anesthesia was induced with fentanyl (2 µg/kg) and thiopentone (4-7 mg/kg), and tracheal intubation was facilitated by vecuronium bromide (0.1 mg/kg). The patient's right internal jugular vein was cannulated and the Pre Sep™ central venous oximetry catheter was connected to it. Anesthesia was maintained with isoflurane in oxygen and nitrous oxide and intermittent boluses of vecuronium. Intermittent positive-pressure ventilation was provided to maintain normocapnea. After CO(2) pneumoperitoneum, position of the patient was gradually changed to 45° Trendelenburg over 5 min. The robot was then docked and the robot-assisted surgery started. Intraoperative monitoring included central venous pressure (CVP), stroke volume (SV), stroke volume variation (SVV), cardiac output (CO), cardiac index (CI) and central venous oxygen saturation (ScvO(2)). RESULTS: After induction of anesthesia, heart rate (HR), SV, CO and CI were decreased significantly from the baseline value (P>0.05). SV, CO and CI further decreased significantly after creating pneumoperitoneum (P>0.05). At the 45° Trendelenburg position, HR, SV, CO and CI were significantly decreased compared with baseline. Thereafter, CO and CI were persistently low throughout the 45° Trendelenburg position (P=0.001). HR at 20 min and 1 h, SV and mean arterial blood pressure after 2 h decreased significantly from the baseline value (P>0.05) during the 45° Trendelenburg position. CVP increased significantly after creating pneumoperitoneum and at the 45° Trendelenburg position (after 5 and 20 min) compared with the baseline postinduction value (P>0.05). All these parameters returned to baseline after deflation of CO(2) pneumoperitoneum in the supine position. There were no significant changes in SVV and ScvO(2) throughout the study period. CONCLUSIONS: The steep Trendelenburg position and CO(2) pneumoperitoneum, during RALRP, leads to significant decrease in stroke volume and cardiac output.

Agreement between cardiac index measured with FloTrac-Vigileo system and pulmonary artery catheter in patients undergoing off-pump coronary artery bypass grafting / 中华麻醉学杂志

ObjectiveTo determine ff the cardiac index (CI) measured with FloTrac-Vigileo system agrees with that measured with pulmonary artery catheter (PAC).MethodsForty-three ASA Ⅱ or Ⅲ patients aged 53-75 yr weighing 46-100 kg undergoing off-pump coronary artery bypass grafting were included in this study.Anesthesia was induced with midasolam,sufentunil,propofol and rocuronium and maintained with propofol,remifentanil and atracurium.One MAC sevoflurane was inhaled at breast bone splitting and closing.CI was measured with FloTrac-Vigileo system and PAC before,and at 5,15 min of sevoflurane inhalation and recorded.All data were compared by Bland-Altman analysis and with kappa coefficient for agreement and percentage error was calculated.ResultsBland-Altman comparison of FloTrac-Vigileo system and PAC:matching data of 258 measurements:CI (2.8 ± 0.6 ) L· min - 1 · m- 2,bias was 0.23 L* min- 1 · m - 2 and limit of agreement was ( - 0.57,1.02)L · min- 1 · m- 2,resulting in κ ＝ 0.546 and an overall percentage error of 28.6 ％.ConclusionCI values obtained by FloTrac-Vigileo system agrees well with that obtained by thermodilution technique using PAC in patients undergoing off-pump coronary artery bypass grafting.

Clinical evaluation of the flotrac/Vigileo system for continuous cardiac output monitoring in patients undergoing regional anesthesia for elective cesarean section: a pilot study.

BACKGROUND: Spinal anesthesia for cesarean delivery may cause severe maternal hypotension and a decrease in cardiac output. Compared to assessment of cardiac output via a pulmonary artery catheter, the FloTrac/Vigileo system may offer a less invasive technique. The aim of this study was to evaluate cardiac output and other hemodynamic measurements made using the FloTrac/Vigileo system in patients undergoing spinal anesthesia for elective cesarean section. METHODS: A prospective study enrolling 10 healthy pregnant women was performed. Hemodynamic parameters were continuously obtained at 15 main points: admission to surgery (two baseline measurements), after preload, after spinal anesthesia administration and 4 time points thereafter (4, 6, 8 and 10 min after anesthesia), at skin and uterine incision, newborn and placental delivery, oxytocin administration, end of surgery, and recovery from anesthesia. Hemodynamic therapy was guided by mean arterial pressure, and vasopressors were used as appropriate to maintain baseline values. A repeated measures ANOVA was used for data analysis. RESULTS: There was a significant increase in heart rate and a decrease of stroke volume and stroke volume index up to 10 min after spinal anesthesia (P < 0.01). Importantly, stroke volume variation increased immediately after newborn delivery (P < 0.001) and returned to basal values at the end of surgery. Further hemodynamic parameters showed no significant changes over time. DISCUSSION AND CONCLUSIONS: No significant hemodynamic effects, except for heart rate and stroke volume changes, were observed in pregnant women managed with preload and vasopressors when undergoing elective cesarean section and spinal anesthesia.