Evaluation of Cardiac Functions in Deep Trendelenburg Position

Hemodynamic Instability Clinical Trial

Official title:

Evaluation of Cardiac Functions in Robotic-assisted Prostatectomy Surgery Performed Under Deep Trendelenburg Position

Clinical Trial Details — Status: Completed

Administrative data

• NCT number: NCT05685979
• Other study ID #: ATADEK; 2022-20/05
• Status: Completed
• Start date: May 1, 2022
• Est. completion date: October 15, 2022

Study information

• Verified date: July 2023
• Source: Acibadem University
• Contact: n/a
• Is FDA regulated: No
• Study type: Observational

Clinical Trial Summary

Robotic-assisted laparoscopic prostatectomy (RALP) is a surgical method with good short-term results and accepted as the gold standard because of its minimal invasiveness. The pneumoperitoneum and deep Trendelenburg position (at least 25°-45° upside down) required for RALP surgeries can cause significant pathophysiological changes in both the pulmonary and cardiac systems, as well as complicate hemodynamic management. In this study, investigators aimed to determine the changes in the cardiovascular system during deep Trendelenburg position with the hemodynamic parameters monitored by the pressure record analytical method (PRAM) and the Longitudinal Strain measured with simultaneous transesophageal echocardiography.

Description:

RALP is the gold standard surgical technique in prostate surgery. Many Robotic-laparoscopic surgical techniques also require the intraoperative deep Trendelenburg position. However, the possible side effects of the deep Trendelenburg position on the cardiovascular system during surgery are unknown. Although the Trendelenburg position is a life-saving maneuver in hypovolemic patients, it also carries undesirable risks. Although the increase in venous return is expected to protect the cardiac output (CO) in the deep Trendelenburg position, the increase in intrathoracic pressure due to the intraperitoneal pressure may cause deterioration in venous return and a decrease in CO . In addition, the changing heart configuration in the deep Trendelenburg position may also cause an increase in the workload of the heart. Therefore, the need to evaluate hemodynamic management with advanced monitoring techniques, including fluid therapy in the perioperative period, has arisen in patients undergoing RALP. The pressure Recording Analytical Method (PRAM), is one of the most up-to-date monitoring methods designed for continuous CO measurement derived from the arterial pressure wave analysis, with a high signal sampling rate (1000 Hz). Many studies have shown that PRAM is a reliable monitoring method in major surgery. Cardiac Cycle Efficiency (CCE), which the PRAM method adds to our daily practice, is an index that defines hemodynamic performance in terms of energy consumption and efficiency. It can be expressed as the ratio of systolic energy performance to the total energy expenditure of the cardiac cycle and indicates the ability of the cardiovascular system to maintain homeostasis at different energy levels. However, data on how cardiac functions change in the deep Trendelenburg position are still limited. In this study, investigators aimed to demonstrate the reliability of the CCE value through its correlation with the Longitudinal Strain (LS) by observing the effect of the deep Trendelenburg position in RALP surgeries on cardiac functions using PRAM and Transesophageal Echocardiography (TEE).

Recruitment information / eligibility

• Status: Completed
• Enrollment: 30
• Est. completion date: October 15, 2022
• Est. primary completion date: September 30, 2022
• Accepts healthy volunteers: No
• Gender: Male
• Age group: 18 Years to 100 Years

Eligibility

Inclusion Criteria:

• Patients with American Society Of Anesthesiology physical status 1-3
• Underwent Robotic-assisted laparoscopic prostatectomy
• Patients with intra-arterial blood pressure monitoring before anesthesia induction.

.Exclusion Criteria:

• Under 18 years of age
• Arrhythmia (atrial fibrillation, frequent premature beat)
• History of myocardial infarction in the last 3 months
• Heart failure
• Severe pre-existing lung disease
• Severe valvular heart disease
• Chronic renal disease on dialysis,

Related Conditions & MeSH terms

• Cardiovascular Complication
• Hemodynamic Instability

Intervention

Procedure:
• Robotic-assisted laparoscopic prostatectomy in deep Trendelenburg position.
After general anesthesia induction, the patients were placed in the deep Trendelenburg position (at least 25°-45° upside down).

Locations

Country	Name	City	State
Turkey	Acibadem Altunizade Hospital	Istanbul

Sponsors (1)

Lead Sponsor	Collaborator
Acibadem University

Country where clinical trial is conducted

Turkey, 

References & Publications (6)

Falabella A, Moore-Jeffries E, Sullivan MJ, Nelson R, Lew M. Cardiac function during steep Trendelenburg position and CO2 pneumoperitoneum for robotic-assisted prostatectomy: a trans-oesophageal Doppler probe study. Int J Med Robot. 2007 Dec;3(4):312-5. doi: 10.1002/rcs.165. — View Citation

Faragli A, Tanacli R, Kolp C, Abawi D, Lapinskas T, Stehning C, Schnackenburg B, Lo Muzio FP, Fassina L, Pieske B, Nagel E, Post H, Kelle S, Alogna A. Cardiovascular magnetic resonance-derived left ventricular mechanics-strain, cardiac power and end-systolic elastance under various inotropic states in swine. J Cardiovasc Magn Reson. 2020 Nov 30;22(1):79. doi: 10.1186/s12968-020-00679-z. — View Citation

Lestar M, Gunnarsson L, Lagerstrand L, Wiklund P, Odeberg-Wernerman S. Hemodynamic perturbations during robot-assisted laparoscopic radical prostatectomy in 45 degrees Trendelenburg position. Anesth Analg. 2011 Nov;113(5):1069-75. doi: 10.1213/ANE.0b013e3182075d1f. Epub 2011 Jan 13. — View Citation

Pawlik MT, Prasser C, Zeman F, Harth M, Burger M, Denzinger S, Blecha S. Pronounced haemodynamic changes during and after robotic-assisted laparoscopic prostatectomy: a prospective observational study. BMJ Open. 2020 Oct 5;10(10):e038045. doi: 10.1136/bmjopen-2020-038045. — View Citation

Porpiglia F, Morra I, Lucci Chiarissi M, Manfredi M, Mele F, Grande S, Ragni F, Poggio M, Fiori C. Randomised controlled trial comparing laparoscopic and robot-assisted radical prostatectomy. Eur Urol. 2013 Apr;63(4):606-14. doi: 10.1016/j.eururo.2012.07.007. Epub 2012 Jul 20. — View Citation

Ruppert M, Lakatos BK, Braun S, Tokodi M, Karime C, Olah A, Sayour AA, Hizoh I, Barta BA, Merkely B, Kovacs A, Radovits T. Longitudinal Strain Reflects Ventriculoarterial Coupling Rather Than Mere Contractility in Rat Models of Hemodynamic Overload-Induced Heart Failure. J Am Soc Echocardiogr. 2020 Oct;33(10):1264-1275.e4. doi: 10.1016/j.echo.2020.05.017. Epub 2020 Aug 7. — View Citation

Outcome

Type	Measure	Description	Time frame	Safety issue
Primary	Cardiac cycle efficiency (CCE) was measured for evaluating cardiac performance	CCE(unit) indicates the ability of the cardiovascular system to maintain homeostasis at different energy levels. CCE was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy)	The duration of the measurement was defined from one minute before induction to the end of the surgery
Primary	Longitudinal strain (LS) was measured for evaluating cardiac performance	LS (%) is a parameter that shows the percentage of dimensional change that occurs in the heart muscle. It is an indicator of the systolic functions of the left ventricle. LS was calculated by intraoperative transesophageal echocardiography.	LS was measured at supine position and 10 minute after trendelenburg position
Primary	Longitudinal strain rate (LSR) was measured for evaluating cardiac performance	LSR (%) is a parameter that shows the rate of dimensional change that occurs in the heart muscle. It is an indicator of the systolic functions of the left ventricle. LSR was calculated by intraoperative transesophageal echocardiography.	LSR was measured at supine position and 10 minute after trendelenburg position
Secondary	Stroke volume variation (SVV) was measured for evaluation of volume status	Stroke volume variation (SVV,%), was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). SVV is a parameter used to asses cardiac preload and fluid responsiveness.	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Pulse pressure variation (PPV) was measured for evaluation of volume status	Pulse pressure variation (PPV,%) was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). PPV is a parameter used to asses cardiac preload and fluid responsiveness.	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Cardiac power output (CPO) was measured for evaluation of cardiac power reserve	Cardiac power output (CPO, Watt) was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). CPO is a parameter used to asses cardiac reserve	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Cardiac index (CI) was measured for evaluating cardiac flow	Cardiac index (CI, L/min/m2), was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). CI is a parameter used to asses cardiac stroke volume	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Dp/Dt was measured to assess cardiac systolic function	Dp/Dt(mmHg/msn), was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). Dp/Dt is a parameter used to asses cardiac contractility.	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Systolic arterial pressure (SAP) was measured for evaluating perfusion pressure	Systolic arterial pressure (SAP- mm/Hg) was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). SAP is a parameter used to assess the pressure of the arterial system during cardiac systole	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Diastolic arterial pressure (DAP) was measured for evaluating perfusion pressure	Diastolic arterial pressure (DAP, mm/Hg) was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). DAP is a parameter used to assess the pressure of the arterial system during cardiac diastole	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Mean arterial pressure (MAP) was measured for evaluating perfusion pressure	Mean arterial pressure (MAP, mm/Hg) was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). MAP is a parameter used to assess organ perfusion	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Heart rate (HR) was measured for evaluating heart ritm	Heart rate( HR, bpm) was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). HR is a parameter used to assess the cardiac rate.	The duration of the measurement was defined from one minute before induction to the end of the surgery
Secondary	Systemic vascular resistance index (SVRI) was measured for evaluating peripheric vascular resistance	Systemic vascular resistance index (SVRI, dyn*s/cm5*m2) was monitored using the uncalibrated pulse contour device MostCare (Vytech, Vygon, Padova, Italy). SVRI is a parameter used to assess the resistance to blood flow offered by all of the systemic vasculatures, excluding the pulmonary vasculature.	The duration of the measurement was defined from one minute before induction to the end of the surgery