Evaluate Efficacy Levobupivacaine 0.125% Versuss Ropivacaine 0.2% in Hemodynamic Alterations in Labor and Fetal Repercussions

May 17, 2023 updated by: Mauricio Roberto Argañaraz Quinteros, Althaia Xarxa Assistencial Universitària de Manresa

Randomized Clinical Trial to Evaluate the Efficacy of Levobupivacaine 0.125% vs Ropivacaine 0.2%, in Hemodynamic Alterations in Pregnant Women in Labor and Their Fetal Repercussions

INTRODUCTION:

Most studies on analgesia in pregnant women in labor mainly evaluate the effect of anesthetics on pain, mentioning hypotension as a side effect without investigating its impact on fetal well-being. The objective of the present study is to evaluate the efficacy of the use of low doses of local anesthetic (LA) to prevent hemodynamic alterations that manifest as a loss of fetal well-being.

METHODOLOGY/DESIGN:

It is a randomized clinical trial. Patients will be pregnant women in labor (dilation period) who want epidural anesthesia (EA), who will randomly receive 0.125% levobupivacaine (Group L) versus 0.2% ropivacaine (Group R). In both groups, controls of hemodynamic parameters and their relationship with changes in fetal heart rate (FHR) and cardiotocographic recording (RCTG) will be carried out during the first 60 minutes after the administration of the local anesthetic via the epidural route. In case of hypotension and/or subsequent FHR and RCTG alterations, they will also be recorded. The follow-up period will extend from the moment the patient enters the delivery room and requests epidural anesthesia until the moment the patient is discharged from the delivery room. The percentage of patients with hemodynamic alterations will be evaluated as a primary result, as well as the percentage of patients whose hemodynamic alterations are related to changes in FHR and RCTG, when using low doses of LA. In the following will also be evaluated in relation to analgesia, the onset time, level reached and degree of satisfaction; and various intra and postpartum side effects.

DISCUSSION:

Both groups of pregnant women in labor will be studied in order to obtain data on the potential impact of the use of low doses of local anesthetic via the epidural route on hemodynamic parameters and the state of well-being of the fetus.

Study Overview

Status

Not yet recruiting

Conditions

Intervention / Treatment

Detailed Description

Any patient presenting in the delivery room or gynecology-obstetrics office of the hospital with prodromes, midwives or gynecologists will inform the principal investigator (PI). The IP will contact the patient to inform them of what the study consists of and if they wish to participate in it. In case of acceptance, the explanatory documentation and a questionnaire will be delivered to determine if it meets the inclusion criteria. If the pregnant patient at term meets the inclusion criteria, she is recruited to enter the study, it will also be used to resolve any doubts that the patient may have. Once the patient has signed the informed consent, the collaborating researcher (CI) of the recruiting center will be notified to contact the Althaia Innovation and Research Unit to find out the patient's assignment group. The collaborating researcher will be in charge of notifying the patient of the group to which she has been assigned (Intervention Group A or B).

Initially, the basal hemodynamic constants will be recorded: systolic blood pressure (SBP), mean blood pressure (TAM), diastolic blood pressure (TAD), pulse pressure (PP), systemic vascular resistance (SVR), cardiac output (CO), index Pulse Pressure Variation (PPV), Stroke Volume Variation (SVV), Heart Rate (HR), Stroke Volume (SV), Partial Pressure Oxygen Saturation (SpO2) via Clearsight device ®; pain score (VAS); degree of anxiety/depression by filling in a questionnaire to complete yourself; the degree of dilation. The FHR will also be recorded, as well as the different pathological patterns of the RCTG that appear, the Philips Avalon FM 30 monitor will be used for this.

The steps to follow for the administration of local anesthetic through the epidural catheter will be the following:

The mother's data (before and after AE) will be collected, including hemodynamic data: systolic blood pressure (SBP), mean blood pressure (TAM), diastolic blood pressure (TAD), pulse pressure (PP), vascular resistance heart rate (SVR), cardiac output (CO), cardiac index (CI), pulse pressure variation (PPV), stroke volume variation (VSV), heart rate (HR), stroke volume (SV), blood saturation partial pressure of oxygen (SpO2); pain score (VAS), degree of analgesia achieved, satisfaction obtained, time onset of analgesia, level of sensory block using the pin-prick test and the hot-cold test; degree of anxiety/depression by filling in a questionnaire to complete yourself; the degree of dilation. The fetal data (before and after the AE) of the FHR (values above or below the normal limits) will also be included, as well as the different pathological patterns of the RCTG that appear, due to hypotension or alterations. associated hemodynamics.

All pregnant women who will participate in this study will carry an intravenous cannula and will receive a fluid load of 500 cc. The position of the patients will be in a sitting position and the epidural puncture will be performed at the level of the L2-3 or L3-4 intervertebral space using a Tuohy 18 epidural needle. The loss of resistance technique with air or saline will be used according to the standards of our service.

A volume of 2 ml of 2% lidocaine will be administered via the epidural via the epidural catheter, after 3 minutes (it will be evaluated if undesirable effects appear: such as motor block due to accidental dural puncture, hypotension, nausea, vomiting), it will be administered to pregnant women the final volume (10 cc) of the local anesthetic randomly assigned via epidural.

After the administration of the initial bolus (Group A - Group B), the different constants or parameters to be evaluated will be recorded.

The measurement of the different hemodynamic variables will be recorded through a non-invasive device, the Clearsight®. The device will automatically determine the constants, which will be recorded at 5, 10, 15, 30, 45 and 60 minutes.

In the event of recording an episode of hypotension after the first 60 minutes, a record of all the hemodynamic variables evaluated will be made every 5 minutes for the following 60 minutes.

It will be determined which of the local anesthetics at low concentrations administered via the epidural is related to alteration of the hemodynamic parameters. To measure the different parameters, a non-invasive device (Clearsight) will be used, which will determine the existing hemodynamic alterations before, after, and during the first hour after the administration of the initial dose through the lumbar epidural catheter, as well as in the event of an episode. of hypotension or changes in FHR and/or RCTG after the first hour of catheter placement.

Study Type

Interventional

Enrollment (Estimated)

40

Phase

  • Phase 4

Contacts and Locations

This section provides the contact details for those conducting the study, and information on where this study is being conducted.

Study Contact

  • Name: Mauricio Roberto Argañaraz Quinteros, Physician
  • Phone Number: 0034600609107
  • Email: mraq1969@gmail.com

Study Contact Backup

  • Name: Susana Gonzalez Suarez

Study Locations

  • Spain
    • Barcelona
      • Manresa, Barcelona, Spain, 08243
        • Althaia Xarxa Assitensial i Universitaria Manresa
        • Contact:
          • Anna Arnau Bartes, Epidemiologist
          • Phone Number: 3414 0034938759300
          • Email: aarnau@althaia.cat

Participation Criteria

Researchers look for people who fit a certain description, called eligibility criteria. Some examples of these criteria are a person's general health condition or prior treatments.

Eligibility Criteria

Ages Eligible for Study

  • Adult

Accepts Healthy Volunteers

No

Description

Inclusion Criteria:

  • - Woman > 18 years
  • Request epidural anesthesia (EA)
  • Expansion period
  • Low obstetric risk
  • ASA I-II (only one associated comorbidity, example: arterial hypertension, etc.)
  • Cervix dilation ≥ 3
  • single fetus
  • Gestational age > 36 weeks
  • Normal Fetal Heart Rate (110 -160 beats / minute)
  • Normal Cardiotocographic record or absence of fetal heart rate patterns suggestive of risk of loss of fetal well-being or non-reassuring cardiotocographic record.

Exclusion Criteria:

  • VAS ≤ 2
  • Breech presentation
  • Maternal fever > 38 years
  • Pre-eclampsia and severe eclampsia
  • Prenatal bleeding
  • ASA II (more than one comorbidity)
  • Chronic pain
  • Substance abuse
  • Contraindications for epidural analgesia (EA)
  • Allergy to local anesthetics
  • BMI >40 kg/m²
  • Presence of RCTG not reassuring

Study Plan

This section provides details of the study plan, including how the study is designed and what the study is measuring.

How is the study designed?

Design Details

  • Primary Purpose: Treatment
  • Allocation: Randomized
  • Interventional Model: Parallel Assignment
  • Masking: Triple

Arms and Interventions

Participant Group / Arm
Intervention / Treatment
Active Comparator: Levobupivacaina
Levobupivacaine 0.125% , dosage 10 ml frequency 1 one dosis duration 1 hour
Drug: Levobupivacaine
To evaluate the efficacy of low-dose levobupivacaine (0.125%) (0.2) in avoiding hemodynamic changes after performing regional analgesia in pregnant women in labor and preventing changes in fetal heart rate and cardiotocographic recording.
Active Comparator: Ropivacaina
Ropivacaine 2 % , dosage 10 ml frequency 1 one dosis duration 1 hour
Drug: Ropivacaine
To evaluate the efficacy of low-dose ropivacaine (0.2) in avoiding hemodynamic changes after performing regional analgesia in pregnant women in labor and preventing changes in fetal heart rate and cardiotocographic recording.

What is the study measuring?

Primary Outcome Measures

Outcome Measure
Measure Description
Time Frame
Systemic vascular resistance ( units of measure:dyn*s/cm5)
Time Frame: 10 minutes before epidural
Systemic vascular resistance (SVR) is expressed by the equation: SVR = (MAP - CVP)/CO, where MAP is mean arterial pressure and CVP is central venous pressure.
10 minutes before epidural
Systemic vascular resistance ( units of measure:dyn*s/cm5)
Time Frame: 5 minutes after epidural
Systemic vascular resistance (SVR) is expressed by the equation: SVR = (MAP - CVP)/CO, where MAP is mean arterial pressure and CVP is central venous pressure.
5 minutes after epidural
Systemic vascular resistance ( units of measure:dyn*s/cm5)
Time Frame: 10 minutes after epidural
Systemic vascular resistance (SVR) is expressed by the equation: SVR = (MAP - CVP)/CO, where MAP is mean arterial pressure and CVP is central venous pressure.
10 minutes after epidural
Systemic vascular resistance ( units of measure:dyn*s/cm5)
Time Frame: 15 minutes after epidural
Systemic vascular resistance (SVR) is expressed by the equation: SVR = (MAP - CVP)/CO, where MAP is mean arterial pressure and CVP is central venous pressure.
15 minutes after epidural
Systemic vascular resistance ( units of measure:dyn*s/cm5)
Time Frame: 30 minutes after epidural
Systemic vascular resistance (SVR) is expressed by the equation: SVR = (MAP - CVP)/CO, where MAP is mean arterial pressure and CVP is central venous pressure.
30 minutes after epidural
Systemic vascular resistance ( units of measure:dyn*s/cm5)
Time Frame: 45 minutes after epidural
Systemic vascular resistance (SVR) is expressed by the equation: SVR = (MAP - CVP)/CO, where MAP is mean arterial pressure and CVP is central venous pressure.
45 minutes after epidural
Systemic vascular resistance ( units of measure :dyn*s/cm5)
Time Frame: 60 minutes after epidural
Systemic vascular resistance (SVR) is expressed by the equation: SVR = (MAP - CVP)/CO, where MAP is mean arterial pressure and CVP is central venous pressure.
60 minutes after epidural

Secondary Outcome Measures

Outcome Measure
Measure Description
Time Frame
Systolic Blood Pressure (units of measure :mmHg)
Time Frame: 10 minutes before epidural
Systolic pressure refers to the pressure of blood in the artery when the heart contracts. It is the upper (and highest) number in a blood pressure measurement.
10 minutes before epidural
Systolic Blood Pressure (units of measure :mmHg)
Time Frame: 5 minutes after epidural
Systolic pressure refers to the pressure of blood in the artery when the heart contracts. It is the upper (and highest) number in a blood pressure measurement.
5 minutes after epidural
Systolic Blood Pressure (units of measure :mmHg)
Time Frame: 10 minutes after epidural
Systolic pressure refers to the pressure of blood in the artery when the heart contracts. It is the upper (and highest) number in a blood pressure measurement.
10 minutes after epidural
Systolic Blood Pressure (units of measure :mmHg)
Time Frame: 15 minutes after epidural
Systolic pressure refers to the pressure of blood in the artery when the heart contracts. It is the upper (and highest) number in a blood pressure measurement.
15 minutes after epidural
Systolic Blood Pressure (units of measure :mmHg)
Time Frame: 30 minutes after epidural
Systolic pressure refers to the pressure of blood in the artery when the heart contracts. It is the upper (and highest) number in a blood pressure measurement.
30 minutes after epidural
Systolic Blood Pressure (units of measure :mmHg)
Time Frame: 45 minutes after epidural
Systolic pressure refers to the pressure of blood in the artery when the heart contracts. It is the upper (and highest) number in a blood pressure measurement.
45 minutes after epidural
Systolic Blood Pressure (units of measure :mmHg)
Time Frame: 60 minutes after epidural
Systolic pressure refers to the pressure of blood in the artery when the heart contracts. It is the upper (and highest) number in a blood pressure measurement.
60 minutes after epidural
Diastolic Blood Pressure (units of measure :mmHg)
Time Frame: 10 minutes before epidural
Diastolic blood pressure refers to the pressure of blood in the artery when the heart relaxes between beats. It is the lower (and lower) number in a blood pressure measurement.
10 minutes before epidural
Diastolic Blood Pressure (units of measure :mmHg)
Time Frame: 5 minutes after epidural
Diastolic blood pressure refers to the pressure of blood in the artery when the heart relaxes between beats. It is the lower (and lower) number in a blood pressure measurement.
5 minutes after epidural
Diastolic Blood Pressure (units of measure :mmHg)
Time Frame: 10 minutes after epidural
Diastolic blood pressure refers to the pressure of blood in the artery when the heart relaxes between beats. It is the lower (and lower) number in a blood pressure measurement.
10 minutes after epidural
Diastolic Blood Pressure (units of measure :mmHg)
Time Frame: 15 minutes after epidural
Diastolic blood pressure refers to the pressure of blood in the artery when the heart relaxes between beats. It is the lower (and lower) number in a blood pressure measurement.
15 minutes after epidural
Diastolic Blood Pressure (units of measure :mmHg)
Time Frame: 30 minutes after epidural
Diastolic blood pressure refers to the pressure of blood in the artery when the heart relaxes between beats. It is the lower (and lower) number in a blood pressure measurement.
30 minutes after epidural
Diastolic Blood Pressure (units of measure :mmHg)
Time Frame: 45 minutes after epidural
Diastolic blood pressure refers to the pressure of blood in the artery when the heart relaxes between beats. It is the lower (and lower) number in a blood pressure measurement.
45 minutes after epidural
Diastolic Blood Pressure (units of measure :mmHg)
Time Frame: 60 minutes after epidural
Diastolic blood pressure refers to the pressure of blood in the artery when the heart relaxes between beats. It is the lower (and lower) number in a blood pressure measurement.
60 minutes after epidural
Mean Arterial Pressure (units of measure :mmHg)
Time Frame: 10 minutes before epidural

Mean arterial pressure (MAP) is determined by cardiac output (CO), peripheral vascular resistance (PVR), and central venous pressure (CVP). The formula that integrates these concepts is:

PAM = (GC x RVP) + PVC
10 minutes before epidural
Mean Arterial Pressure (units of measure :mmHg)
Time Frame: 5 minutes after epidural

Mean arterial pressure (MAP) is determined by cardiac output (CO), peripheral vascular resistance (PVR), and central venous pressure (CVP). The formula that integrates these concepts is:

PAM = (GC x RVP) + PVC
5 minutes after epidural
Mean Arterial Pressure (units of measure :mmHg)
Time Frame: 10 minutes after epidural

Mean arterial pressure (MAP) is determined by cardiac output (CO), peripheral vascular resistance (PVR), and central venous pressure (CVP). The formula that integrates these concepts is:

PAM = (GC x RVP) + PVC
10 minutes after epidural
Mean Arterial Pressure (units of measure :mmHg)
Time Frame: 15 minutes after epidural

Mean arterial pressure (MAP) is determined by cardiac output (CO), peripheral vascular resistance (PVR), and central venous pressure (CVP). The formula that integrates these concepts is:

PAM = (GC x RVP) + PVC
15 minutes after epidural
Mean Arterial Pressure (units of measure :mmHg)
Time Frame: 30 minutes after epidural

Mean arterial pressure (MAP) is determined by cardiac output (CO), peripheral vascular resistance (PVR), and central venous pressure (CVP). The formula that integrates these concepts is:

PAM = (GC x RVP) + PVC
30 minutes after epidural
Mean Arterial Pressure (units of measure :mmHg)
Time Frame: 45 minutes after epidural

Mean arterial pressure (MAP) is determined by cardiac output (CO), peripheral vascular resistance (PVR), and central venous pressure (CVP). The formula that integrates these concepts is:

PAM = (GC x RVP) + PVC
45 minutes after epidural
Mean Arterial Pressure (units of measure :mmHg)
Time Frame: 60 minutes after epidural

Mean arterial pressure (MAP) is determined by cardiac output (CO), peripheral vascular resistance (PVR), and central venous pressure (CVP). The formula that integrates these concepts is:

PAM = (GC x RVP) + PVC
60 minutes after epidural
Pulse Pressure (units of measure :mmHg)
Time Frame: 10 minutes before epidural
Pulse pressure is the difference between systolic blood pressure (SBP) and diastolic blood pressure (DBP), and is an index of arterial compliance.
10 minutes before epidural
Pulse Pressure (units of measure :mmHg)
Time Frame: 5 minutes after epidural
Pulse pressure is the difference between systolic blood pressure (SBP) and diastolic blood pressure (DBP), and is an index of arterial compliance.
5 minutes after epidural
Pulse Pressure (units of measure :mmHg)
Time Frame: 10 minutes after epidural
Pulse pressure is the difference between systolic blood pressure (SBP) and diastolic blood pressure (DBP), and is an index of arterial compliance.
10 minutes after epidural
Pulse Pressure (units of measure :mmHg)
Time Frame: 15 minutes after epidural
Pulse pressure is the difference between systolic blood pressure (SBP) and diastolic blood pressure (DBP), and is an index of arterial compliance.
15 minutes after epidural
Pulse Pressure (units of measure :mmHg)
Time Frame: 30 minutes after epidural
Pulse pressure is the difference between systolic blood pressure (SBP) and diastolic blood pressure (DBP), and is an index of arterial compliance.
30 minutes after epidural
Pulse Pressure (units of measure :mmHg)
Time Frame: 45 minutes after epidural
Pulse pressure is the difference between systolic blood pressure (SBP) and diastolic blood pressure (DBP), and is an index of arterial compliance.
45 minutes after epidural
Pulse Pressure (units of measure :mmHg)
Time Frame: 60 minutes after epidural
Pulse pressure is the difference between systolic blood pressure (SBP) and diastolic blood pressure (DBP), and is an index of arterial compliance.
60 minutes after epidural
Cardiac Output (units of measure :L/min)
Time Frame: 10 minutes before epidural

The volume of blood pumped from a ventricle each minute is known as cardiac output. It is the product of heart rate and stroke volume:

Cardiac output = heart rate x stroke volume
10 minutes before epidural
Cardiac Output (units of measure :L/min)
Time Frame: 5 minutes after epidural

The volume of blood pumped from a ventricle each minute is known as cardiac output. It is the product of heart rate and stroke volume:

Cardiac output = heart rate x stroke volume
5 minutes after epidural
Cardiac Output (units of measure :L/min)
Time Frame: 10 minutes after epidural

The volume of blood pumped from a ventricle each minute is known as cardiac output. It is the product of heart rate and stroke volume:

Cardiac output = heart rate x stroke volume
10 minutes after epidural
Cardiac Output (units of measure :L/min)
Time Frame: 15 minutes after epidural

The volume of blood pumped from a ventricle each minute is known as cardiac output. It is the product of heart rate and stroke volume:

Cardiac output = heart rate x stroke volume
15 minutes after epidural
Cardiac Output (units of measure :L/min)
Time Frame: 30 minutes after epidural

The volume of blood pumped from a ventricle each minute is known as cardiac output. It is the product of heart rate and stroke volume:

Cardiac output = heart rate x stroke volume
30 minutes after epidural
Cardiac Output (units of measure :L/min)
Time Frame: 45 minutes after epidural

The volume of blood pumped from a ventricle each minute is known as cardiac output. It is the product of heart rate and stroke volume:

Cardiac output = heart rate x stroke volume
45 minutes after epidural
Cardiac Output (units of measure :L/min)
Time Frame: 60 minutes after epidural

The volume of blood pumped from a ventricle each minute is known as cardiac output. It is the product of heart rate and stroke volume:

Cardiac output = heart rate x stroke volume
60 minutes after epidural
Cardiac Index ( units of measure :L/min/m2)
Time Frame: 10 minutes before epidural

A cardio dynamic measure based on the cardiac output, which is the amount of blood the left ventricle ejects into the systemic circulation in one minute, measured in liters per minute (l/min). Cardiac output is indexed to a patient's body size by dividing by the body surface area to yield the cardiac index.

Cardiac Index = Cardiac Output / Body Surface Area = (Heart Rate * Stroke Volume) / Body Surface Area
10 minutes before epidural
Cardiac Index ( units of measure :L/min/m2)
Time Frame: 5 minutes after epidural

A cardio dynamic measure based on the cardiac output, which is the amount of blood the left ventricle ejects into the systemic circulation in one minute, measured in liters per minute (l/min). Cardiac output is indexed to a patient's body size by dividing by the body surface area to yield the cardiac index.

Cardiac Index = Cardiac Output / Body Surface Area = (Heart Rate * Stroke Volume) / Body Surface Area
5 minutes after epidural
Cardiac Index ( units of measure :L/min/m2)
Time Frame: 10 minutes after epidural

A cardio dynamic measure based on the cardiac output, which is the amount of blood the left ventricle ejects into the systemic circulation in one minute, measured in liters per minute (l/min). Cardiac output is indexed to a patient's body size by dividing by the body surface area to yield the cardiac index.

Cardiac Index = Cardiac Output / Body Surface Area = (Heart Rate * Stroke Volume) / Body Surface Area
10 minutes after epidural
Cardiac Index ( units of measure :L/min/m2)
Time Frame: 15 minutes after epidural

A cardio dynamic measure based on the cardiac output, which is the amount of blood the left ventricle ejects into the systemic circulation in one minute, measured in liters per minute (l/min). Cardiac output is indexed to a patient's body size by dividing by the body surface area to yield the cardiac index.

Cardiac Index = Cardiac Output / Body Surface Area = (Heart Rate * Stroke Volume) / Body Surface Arealimits) will also be included
15 minutes after epidural
Cardiac Index ( units of measure :L/min/m2)
Time Frame: 30 minutes after epidural

A cardio dynamic measure based on the cardiac output, which is the amount of blood the left ventricle ejects into the systemic circulation in one minute, measured in liters per minute (l/min). Cardiac output is indexed to a patient's body size by dividing by the body surface area to yield the cardiac index.

Cardiac Index = Cardiac Output / Body Surface Area = (Heart Rate * Stroke Volume) / Body Surface Area
30 minutes after epidural
Cardiac Index ( units of measure :L/min/m2)
Time Frame: 45 minutes after epidural

A cardio dynamic measure based on the cardiac output, which is the amount of blood the left ventricle ejects into the systemic circulation in one minute, measured in liters per minute (l/min). Cardiac output is indexed to a patient's body size by dividing by the body surface area to yield the cardiac index.

Cardiac Index = Cardiac Output / Body Surface Area = (Heart Rate * Stroke Volume) / Body Surface Area
45 minutes after epidural
Cardiac Index ( units of measure :L/min/m2)
Time Frame: 60 minutes after epidural

A cardio dynamic measure based on the cardiac output, which is the amount of blood the left ventricle ejects into the systemic circulation in one minute, measured in liters per minute (l/min). Cardiac output is indexed to a patient's body size by dividing by the body surface area to yield the cardiac index.

Cardiac Index = Cardiac Output / Body Surface Area = (Heart Rate * Stroke Volume) / Body Surface Area
60 minutes after epidural
Pulse Pressure Variation ( units of measure :% Percent)
Time Frame: 10 minutes before epidural

Pulse pressure variation (PPV) is an effective and widely used dynamic parameter to predict the increase in cardiac output after fluid administration. Ideally, PPV measurement should be performed with a closed chest and mechanical ventilation with a tidal volume of 8 mL/kg.PPV was calculated as the percentage changes in arterial pulse pressure during a ventilatory cycle as [(PPmax - PPmin)/(PPmax

+ PPmin)/2] × 100, where PPmax and PPmin represent the maximal and minimal arterial pulse pressure, respectively
10 minutes before epidural
Pulse Pressure Variation ( units of measure :% Percent)
Time Frame: 5 minutes after epidural

Pulse pressure variation (PPV) is an effective and widely used dynamic parameter to predict the increase in cardiac output after fluid administration. Ideally, PPV measurement should be performed with a closed chest and mechanical ventilation with a tidal volume of 8 mL/kg.PPV was calculated as the percentage changes in arterial pulse pressure during a ventilatory cycle as [(PPmax - PPmin)/(PPmax

+ PPmin)/2] × 100, where PPmax and PPmin represent the maximal and minimal arterial pulse pressure, respectively
5 minutes after epidural
Pulse Pressure Variation ( units of measure :% Percent)
Time Frame: 10 minutes after epidural

Pulse pressure variation (PPV) is an effective and widely used dynamic parameter to predict the increase in cardiac output after fluid administration. Ideally, PPV measurement should be performed with a closed chest and mechanical ventilation with a tidal volume of 8 mL/kg.PPV was calculated as the percentage changes in arterial pulse pressure during a ventilatory cycle as [(PPmax - PPmin)/(PPmax

+ PPmin)/2] × 100, where PPmax and PPmin represent the maximal and minimal arterial pulse pressure, respectively
10 minutes after epidural
Pulse Pressure Variation ( units of measure :% Percent)
Time Frame: 15 minutes after epidural

Pulse pressure variation (PPV) is an effective and widely used dynamic parameter to predict the increase in cardiac output after fluid administration. Ideally, PPV measurement should be performed with a closed chest and mechanical ventilation with a tidal volume of 8 mL/kg.PPV was calculated as the percentage changes in arterial pulse pressure during a ventilatory cycle as [(PPmax - PPmin)/(PPmax

+ PPmin)/2] × 100, where PPmax and PPmin represent the maximal and minimal arterial pulse pressure, respectively
15 minutes after epidural
Pulse Pressure Variation ( units of measure :% Percent)
Time Frame: 30 minutes after epidural

Pulse pressure variation (PPV) is an effective and widely used dynamic parameter to predict the increase in cardiac output after fluid administration. Ideally, PPV measurement should be performed with a closed chest and mechanical ventilation with a tidal volume of 8 mL/kg.PPV was calculated as the percentage changes in arterial pulse pressure during a ventilatory cycle as [(PPmax - PPmin)/(PPmax

+ PPmin)/2] × 100, where PPmax and PPmin represent the maximal and minimal arterial pulse pressure, respectively
30 minutes after epidural
Pulse Pressure Variation ( units of measure :% Percent)
Time Frame: 45 minutes after epidural

Pulse pressure variation (PPV) is an effective and widely used dynamic parameter to predict the increase in cardiac output after fluid administration. Ideally, PPV measurement should be performed with a closed chest and mechanical ventilation with a tidal volume of 8 mL/kg.PPV was calculated as the percentage changes in arterial pulse pressure during a ventilatory cycle as [(PPmax - PPmin)/(PPmax

+ PPmin)/2] × 100, where PPmax and PPmin represent the maximal and minimal arterial pulse pressure, respectively
45 minutes after epidural
Pulse Pressure Variation ( units of measure :% Percent)
Time Frame: 60 minutes after epidural

Pulse pressure variation (PPV) is an effective and widely used dynamic parameter to predict the increase in cardiac output after fluid administration. Ideally, PPV measurement should be performed with a closed chest and mechanical ventilation with a tidal volume of 8 mL/kg.PPV was calculated as the percentage changes in arterial pulse pressure during a ventilatory cycle as [(PPmax - PPmin)/(PPmax

+ PPmin)/2] × 100, where PPmax and PPmin represent the maximal and minimal arterial pulse pressure, respectively
60 minutes after epidural
(Maternal) Heart Rate (units of measure: beats per minute)
Time Frame: 10 minutes before epidural

The number of times the heart beats during a certain period, usually one minute.

The resting heart rate normally ranges from 60 to 100 beats per minute in a healthy adult at rest.
10 minutes before epidural
(Maternal) Heart Rate (units of measure: beats per minute)
Time Frame: 5 minutes after epidural

The number of times the heart beats during a certain period, usually one minute.

The resting heart rate normally ranges from 60 to 100 beats per minute in a healthy adult at rest.
5 minutes after epidural
(Maternal) Heart Rate (units of measure: beats per minute)
Time Frame: 10 minutes after epidural

The number of times the heart beats during a certain period, usually one minute.

The resting heart rate normally ranges from 60 to 100 beats per minute in a healthy adult at rest.
10 minutes after epidural
(Maternal) Heart Rate (units of measure: beats per minute)
Time Frame: 15 minutes after epidural

The number of times the heart beats during a certain period, usually one minute.

The resting heart rate normally ranges from 60 to 100 beats per minute in a healthy adult at rest.
15 minutes after epidural
(Maternal) Heart Rate (units of measure: beats per minute)
Time Frame: 30 minutes after epidural

The number of times the heart beats during a certain period, usually one minute.

The resting heart rate normally ranges from 60 to 100 beats per minute in a healthy adult at rest.
30 minutes after epidural
(Maternal) Heart Rate (units of measure: beats per minute)
Time Frame: 45 minutes after epidural

The number of times the heart beats during a certain period, usually one minute.

The resting heart rate normally ranges from 60 to 100 beats per minute in a healthy adult at rest.
45 minutes after epidural
(Maternal) Heart Rate (units of measure: beats per minute)
Time Frame: 60 minutes after epidural

The number of times the heart beats during a certain period, usually one minute.

The resting heart rate normally ranges from 60 to 100 beats per minute in a healthy adult at rest.
60 minutes after epidural
Stroke Volume (units of measure :ml)
Time Frame: 10 minutes before epidural
Stroke volume is the volume of blood pumped out of the left ventricle of the heart during each systolic cardiac contraction. The SV volume may be calculated as the difference between the left ventricular end-diastolic volume and the left ventricular end-systolic volume (ESV).
10 minutes before epidural
Stroke Volume (units of measure :ml)
Time Frame: 5 minutes after epidural
Stroke volume is the volume of blood pumped out of the left ventricle of the heart during each systolic cardiac contraction. The SV volume may be calculated as the difference between the left ventricular end-diastolic volume and the left ventricular end-systolic volume (ESV).
5 minutes after epidural
Stroke Volume (units of measure :ml)
Time Frame: 10 minutes after epidural
Stroke volume is the volume of blood pumped out of the left ventricle of the heart during each systolic cardiac contraction. The SV volume may be calculated as the difference between the left ventricular end-diastolic volume and the left ventricular end-systolic volume (ESV).
10 minutes after epidural
Stroke Volume (units of measure :ml)
Time Frame: 15 minutes after epidural
Stroke volume is the volume of blood pumped out of the left ventricle of the heart during each systolic cardiac contraction. The SV volume may be calculated as the difference between the left ventricular end-diastolic volume and the left ventricular end-systolic volume (ESV).
15 minutes after epidural
Stroke Volume (units of measure :ml)
Time Frame: 30 minutes after epidural
Stroke volume is the volume of blood pumped out of the left ventricle of the heart during each systolic cardiac contraction. The SV volume may be calculated as the difference between the left ventricular end-diastolic volume and the left ventricular end-systolic volume (ESV).
30 minutes after epidural
Stroke Volume (units of measure :ml)
Time Frame: 45 minutes after epidural
Stroke volume is the volume of blood pumped out of the left ventricle of the heart during each systolic cardiac contraction. The SV volume may be calculated as the difference between the left ventricular end-diastolic volume and the left ventricular end-systolic volume (ESV).
45 minutes after epidural
Stroke Volume (units of measure :ml)
Time Frame: 60 minutes after epidural
Stroke volume is the volume of blood pumped out of the left ventricle of the heart during each systolic cardiac contraction. The SV volume may be calculated as the difference between the left ventricular end-diastolic volume and the left ventricular end-systolic volume (ESV).
60 minutes after epidural
Systolic Variation Volume ( units of measure :% Percent)
Time Frame: 10 minutes before epidural
Stroke volume variation (SVV) has been shown to be a reliable predictor of fluid responsiveness.SVV is assessed using the following equation: SVV (%) = (SVmax - SVmin)/SVmean
10 minutes before epidural
Systolic Variation Volume ( units of measure :% Percent)
Time Frame: 5 minutes after epidural
Stroke volume variation (SVV) has been shown to be a reliable predictor of fluid responsiveness.SVV is assessed using the following equation: SVV (%) = (SVmax - SVmin)/SVmean
5 minutes after epidural
Systolic Variation Volume ( units of measure :% Percent)
Time Frame: 10 minutes after epidural
Stroke volume variation (SVV) has been shown to be a reliable predictor of fluid responsiveness.SVV is assessed using the following equation: SVV (%) = (SVmax - SVmin)/SVmean
10 minutes after epidural
Systolic Variation Volume ( units of measure :% Percent)
Time Frame: 15 minutes after epidural
Stroke volume variation (SVV) has been shown to be a reliable predictor of fluid responsiveness.SVV is assessed using the following equation: SVV (%) = (SVmax - SVmin)/SVmean
15 minutes after epidural
Systolic Variation Volume ( units of measure :% Percent)
Time Frame: 30 minutes after epidural
Stroke volume variation (SVV) has been shown to be a reliable predictor of fluid responsiveness.SVV is assessed using the following equation: SVV (%) = (SVmax - SVmin)/SVmean
30 minutes after epidural
Systolic Variation Volume ( units of measure :% Percent)
Time Frame: 45 minutes after epidural
Stroke volume variation (SVV) has been shown to be a reliable predictor of fluid responsiveness.SVV is assessed using the following equation: SVV (%) = (SVmax - SVmin)/SVmean
45 minutes after epidural
Systolic Variation Volume ( units of measure :% Percent)
Time Frame: 60 minutes after epidural
Stroke volume variation (SVV) has been shown to be a reliable predictor of fluid responsiveness.SVV is assessed using the following equation: SVV (%) = (SVmax - SVmin)/SVmean
60 minutes after epidural
Arterial Oxigen Saturation ( units of measure :% Percent)
Time Frame: 10 minutes before epidural
Arterial oxygen saturation (SaO2) is a measure of hemoglobin oxygenation in the arterial compartment of the circulatory system. It is not a measure of the total oxygen content in the arterial blood because a small fraction of oxygen (about 2%) is dissolved in the plasma. To determine overall oxygen-carrying capacity of the blood, multiply 1.34 ml/g by the patient's hemoglobin level in g/dL and by Spo2.
10 minutes before epidural
Arterial Oxigen Saturation ( units of measure :% Percent)
Time Frame: 5 minutes after epidural
Arterial oxygen saturation (SaO2) is a measure of hemoglobin oxygenation in the arterial compartment of the circulatory system. It is not a measure of the total oxygen content in the arterial blood because a small fraction of oxygen (about 2%) is dissolved in the plasma. To determine overall oxygen-carrying capacity of the blood, multiply 1.34 ml/g by the patient's hemoglobin level in g/dL and by Spo2.
5 minutes after epidural
Arterial Oxigen Saturation ( units of measure :% Percent)
Time Frame: 10 minutes after epidural
Arterial oxygen saturation (SaO2) is a measure of hemoglobin oxygenation in the arterial compartment of the circulatory system. It is not a measure of the total oxygen content in the arterial blood because a small fraction of oxygen (about 2%) is dissolved in the plasma. To determine overall oxygen-carrying capacity of the blood, multiply 1.34 ml/g by the patient's hemoglobin level in g/dL and by Spo2.
10 minutes after epidural
Arterial Oxigen Saturation ( units of measure :% Percent)
Time Frame: 15 minutes after epidural
Arterial oxygen saturation (SaO2) is a measure of hemoglobin oxygenation in the arterial compartment of the circulatory system. It is not a measure of the total oxygen content in the arterial blood because a small fraction of oxygen (about 2%) is dissolved in the plasma. To determine overall oxygen-carrying capacity of the blood, multiply 1.34 ml/g by the patient's hemoglobin level in g/dL and by Spo2.
15 minutes after epidural
Arterial Oxigen Saturation ( units of measure :% Percent)
Time Frame: 30 minutes after epidural
Arterial oxygen saturation (SaO2) is a measure of hemoglobin oxygenation in the arterial compartment of the circulatory system. It is not a measure of the total oxygen content in the arterial blood because a small fraction of oxygen (about 2%) is dissolved in the plasma. To determine overall oxygen-carrying capacity of the blood, multiply 1.34 ml/g by the patient's hemoglobin level in g/dL and by Spo2.
30 minutes after epidural
Arterial Oxigen Saturation ( units of measure :% Percent)
Time Frame: 45 minutes after epidural
Arterial oxygen saturation (SaO2) is a measure of hemoglobin oxygenation in the arterial compartment of the circulatory system. It is not a measure of the total oxygen content in the arterial blood because a small fraction of oxygen (about 2%) is dissolved in the plasma. To determine overall oxygen-carrying capacity of the blood, multiply 1.34 ml/g by the patient's hemoglobin level in g/dL and by Spo2.
45 minutes after epidural
Arterial Oxigen Saturation ( units of measure :% Percent)
Time Frame: 60 minutes after epidural
Arterial oxygen saturation (SaO2) is a measure of hemoglobin oxygenation in the arterial compartment of the circulatory system. It is not a measure of the total oxygen content in the arterial blood because a small fraction of oxygen (about 2%) is dissolved in the plasma. To determine overall oxygen-carrying capacity of the blood, multiply 1.34 ml/g by the patient's hemoglobin level in g/dL and by Spo2.
60 minutes after epidural
Fetal heart rate (units of measure: beats per minute)
Time Frame: 10 minutes before epidural
The average fetal heart rate is between 110 and 160 beats per minute. It can vary by 5 to 25 beats per minute. The fetal heart rate may change by differents conditions in the uterus. An abnormal fetal heart rate may mean that is not getting enough oxygen or that there are other problems.
10 minutes before epidural
Fetal heart rate (units of measure: beats per minute)
Time Frame: 5 minutes after epidural
The average fetal heart rate is between 110 and 160 beats per minute. It can vary by 5 to 25 beats per minute. The fetal heart rate may change by differents conditions in the uterus. An abnormal fetal heart rate may mean that is not getting enough oxygen or that there are other problems.
5 minutes after epidural
Fetal heart rate (units of measure: beats per minute)
Time Frame: 10 minutes after epidural
The average fetal heart rate is between 110 and 160 beats per minute. It can vary by 5 to 25 beats per minute. The fetal heart rate may change by differents conditions in the uterus. An abnormal fetal heart rate may mean that is not getting enough oxygen or that there are other problems.
10 minutes after epidural
Fetal heart rate (units of measure: beats per minute)
Time Frame: 15 minutes after epidural
The average fetal heart rate is between 110 and 160 beats per minute. It can vary by 5 to 25 beats per minute. The fetal heart rate may change by differents conditions in the uterus. An abnormal fetal heart rate may mean that is not getting enough oxygen or that there are other problems.
15 minutes after epidural
Fetal heart rate (units of measure: beats per minute)
Time Frame: 30 minutes after epidural
The average fetal heart rate is between 110 and 160 beats per minute. It can vary by 5 to 25 beats per minute. The fetal heart rate may change by differents conditions in the uterus. An abnormal fetal heart rate may mean that is not getting enough oxygen or that there are other problems.
30 minutes after epidural
Fetal heart rate (units of measure: beats per minute)
Time Frame: 45 minutes after epidural
The average fetal heart rate is between 110 and 160 beats per minute. It can vary by 5 to 25 beats per minute. The fetal heart rate may change by differents conditions in the uterus. An abnormal fetal heart rate may mean that is not getting enough oxygen or that there are other problems.
45 minutes after epidural
Fetal heart rate (units of measure: beats per minute)
Time Frame: 60 minutes after epidural
The average fetal heart rate is between 110 and 160 beats per minute. It can vary by 5 to 25 beats per minute. The fetal heart rate may change by differents conditions in the uterus. An abnormal fetal heart rate may mean that is not getting enough oxygen or that there are other problems.
60 minutes after epidural
Variability (units of measure: beats per minute)
Time Frame: 10 minutes before epidural
This the minor fluctuation in baseline FHR. It is assessed by estimating the difference in bpm between the highest peak and lowest trough of fluctuation in one minute segments of the trace
10 minutes before epidural
Variability (units of measure: beats per minute)
Time Frame: 5 minutes after epidural
This the minor fluctuation in baseline FHR. It is assessed by estimating the difference in bpm between the highest peak and lowest trough of fluctuation in one minute segments of the trace
5 minutes after epidural
Variability (units of measure: beats per minute)
Time Frame: 10 minutes after epidural
This the minor fluctuation in baseline FHR. It is assessed by estimating the difference in bpm between the highest peak and lowest trough of fluctuation in one minute segments of the trace
10 minutes after epidural
Variability (units of measure: beats per minute)
Time Frame: 15 minutes after epidural
This the minor fluctuation in baseline FHR. It is assessed by estimating the difference in bpm between the highest peak and lowest trough of fluctuation in one minute segments of the trace
15 minutes after epidural
Variability (units of measure: beats per minute)
Time Frame: 30 minutes after epidural
This the minor fluctuation in baseline FHR. It is assessed by estimating the difference in bpm between the highest peak and lowest trough of fluctuation in one minute segments of the trace
30 minutes after epidural
Variability (units of measure: beats per minute)
Time Frame: 45 minutes after epidural
This the minor fluctuation in baseline FHR. It is assessed by estimating the difference in bpm between the highest peak and lowest trough of fluctuation in one minute segments of the trace
45 minutes after epidural
Variability (units of measure: beats per minute)
Time Frame: 60 minutes after epidural
This the minor fluctuation in baseline FHR. It is assessed by estimating the difference in bpm between the highest peak and lowest trough of fluctuation in one minute segments of the trace
60 minutes after epidural
Accelerations (units of measure: beats per minute)
Time Frame: 10 minutes before epidural
These are transient increases in FHR of 15bpm or more above the baseline and lasting 15 seconds.
10 minutes before epidural
Accelerations (units of measure: beats per minute)
Time Frame: 5 minutes after epidural
These are transient increases in FHR of 15bpm or more above the baseline and lasting 15 seconds.
5 minutes after epidural
Accelerations (units of measure: beats per minute)
Time Frame: 10 minutes after epidural
These are transient increases in FHR of 15bpm or more above the baseline and lasting 15 seconds.
10 minutes after epidural
Accelerations (units of measure: beats per minute)
Time Frame: 15 minutes after epidural
These are transient increases in FHR of 15bpm or more above the baseline and lasting 15 seconds.
15 minutes after epidural
Accelerations (units of measure: beats per minute)
Time Frame: 30 minutes after epidural
These are transient increases in FHR of 15bpm or more above the baseline and lasting 15 seconds.
30 minutes after epidural
Accelerations (units of measure: beats per minute)
Time Frame: 45 minutes after epidural
These are transient increases in FHR of 15bpm or more above the baseline and lasting 15 seconds.
45 minutes after epidural
Accelerations (units of measure: beats per minute)
Time Frame: 60 minutes after epidural
These are transient increases in FHR of 15bpm or more above the baseline and lasting 15 seconds.
60 minutes after epidural
Decelerations (units of measure: beats per minute)
Time Frame: 10 minutes before epidural
These are transient episodes of decrease of FHR below the baseline of more than 15 bpm lasting at least 15 seconds.
10 minutes before epidural
Decelerations (units of measure: beats per minute)
Time Frame: 5 minutes after epidural
These are transient episodes of decrease of FHR below the baseline of more than 15 bpm lasting at least 15 seconds.
5 minutes after epidural
Decelerations (units of measure: beats per minute)
Time Frame: 10 minutes after epidural
These are transient episodes of decrease of FHR below the baseline of more than 15 bpm lasting at least 15 seconds.
10 minutes after epidural
Decelerations (units of measure: beats per minute)
Time Frame: 15 minutes after epidural
These are transient episodes of decrease of FHR below the baseline of more than 15 bpm lasting at least 15 seconds.
15 minutes after epidural
Decelerations (units of measure: beats per minute)
Time Frame: 30 minutes after epidural
These are transient episodes of decrease of FHR below the baseline of more than 15 bpm lasting at least 15 seconds.
30 minutes after epidural
Decelerations (units of measure: beats per minute)
Time Frame: 45 minutes after epidural
These are transient episodes of decrease of FHR below the baseline of more than 15 bpm lasting at least 15 seconds.
45 minutes after epidural
Decelerations (units of measure: beats per minute)
Time Frame: 60 minutes after epidural
These are transient episodes of decrease of FHR below the baseline of more than 15 bpm lasting at least 15 seconds.
60 minutes after epidural

Collaborators and Investigators

This is where you will find people and organizations involved with this study.

Sponsor

Althaia Xarxa Assistencial Universitària de Manresa

Publications and helpful links

The person responsible for entering information about the study voluntarily provides these publications. These may be about anything related to the study.

General Publications

Study record dates

These dates track the progress of study record and summary results submissions to ClinicalTrials.gov. Study records and reported results are reviewed by the National Library of Medicine (NLM) to make sure they meet specific quality control standards before being posted on the public website.

Study Major Dates

Study Start (Estimated)

June 1, 2023

Primary Completion (Estimated)

December 1, 2023

Study Completion (Estimated)

December 1, 2023

Study Registration Dates

First Submitted

March 20, 2023

First Submitted That Met QC Criteria

May 17, 2023

First Posted (Actual)

May 26, 2023

Study Record Updates

Last Update Posted (Actual)

May 26, 2023

Last Update Submitted That Met QC Criteria

May 17, 2023

Last Verified

May 1, 2023

More Information

Terms related to this study

Keywords

Additional Relevant MeSH Terms

Other Study ID Numbers

  • CEI-pendiente

Plan for Individual participant data (IPD)

Plan to Share Individual Participant Data (IPD)?

NO

Drug and device information, study documents

Studies a U.S. FDA-regulated drug product

No

Studies a U.S. FDA-regulated device product

No

This information was retrieved directly from the website clinicaltrials.gov without any changes. If you have any requests to change, remove or update your study details, please contact register@clinicaltrials.gov. As soon as a change is implemented on clinicaltrials.gov, this will be updated automatically on our website as well.

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