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To evaluate which of the two de-airing methods (CO2 insufflation vs. Lund de-airing technique) can shorten the left heart de-airing time and prevent or minimize cerebral air emboli during open surgery involving exposure of the left heart to the ambient air.
To evaluate the cost effectiveness and possible side effects of CO2 de-airing technique compared to Lund de-airing technique.
Study design:
Prospective, randomized and controlled study involving 20 patients, 10 in each group. The de-airing time and the efficiency of the techniques will be assessed by trans-esophageal echocardiography (TEE) and trans-cranial echo-doppler monitoring (TCD). The cardiologists analyzing the TEE recordings will be blinded to the de-airing technique used (the recorded videos will be analyzed at the end of the study). The TCD monitoring will be done by on-line automatic recording of the micro embolic signals (MES) from the right and or left middle cerebral arteries and performed by single surgeon. The CO2 insufflation of the operating field will be performed according to manufacturer's guide lines. During entire study course one type of extracorporeal perfusion system will be used.The study will be registered in the international database. A prior approval will be sought from the hospital ethical committee for the study.
Patient selection:
Patients planned for aortic valve/root replacement or repair will be selected for the study
Exclusion criteria:
Patients with known: a) chronic obstructive pulmonary disease, b) emphysema, c) previous thoracic or cardiac surgery, d) history of CVA or stroke and e) evidence of intraoperative pleural adhesions will be excluded from the study. Patients requiring internal mammary artery coronary bypass will also be excluded.
Patient consent:
A written consent previously approved by the hospital ethical committee will be obtained from all patients before they are enrolled in the study (enclosure 3).
De-airing procedure:
Enrolled patients will be assigned randomly to one of the two following groups:
Control group ( newly developed de-airing technique in Lund ) :
In these patients (n=10) the pleura will be opened on both sides and the ventilator will be disconnected before aorta is cross-clamped and cardioplegia administered. At the end of the cardioplegic arrest, the aortic root and the LV will be actively vented and aortic cross clamp released. The time will be noted down (T1). The heart will be defibrillated to sinus or pacemaker induced rhythm. The heart will be kept empty by the LV vent and ejection avoided as monitored by continual intraoperative TEE and systemic arterial pressure tracing. At 35 Celsius body temperature, as measured from the thermistor in the urinary bladder, and with apparently good cardiac contraction the de-airing will begin. Inotropic drugs or systemic arterial vasodilators will be used as and when necessary to achieve good cardiac contraction. The time will be noted down (T2) (T2 - T1 = Pre ejection de-airing time). The LV preload will first now be successively increased by reducing the venous return from the heart-lung machine to raise CVP between 5-10 cm water. LV vent will be continuously regulated depending upon the amount of residual air showing in the left heart. When no air is seen on TEE monitoring in the left heart (LA, LV & Aorta), half the calculated minute ventilation with 100% oxygen and a PEEP of 5 cm H2O will be started. De-airing will be continued and when the TEE shows no or minimal air in left heart, full ventilation with unchanged PEEP will be restored. The patient will be weaned successively from the CPB thereby ensuring that entire cardiac output is diverted through the native fully ventilated lungs. When TEE will show no air in the left heart, the de-airing will be considered complete and the time noted again (T3) (T3 - T2 = Post ejection de-airing time).
All cardiac cannulae including the LV vent will be left in situ but clamped, patient weaned completely from the cardiopulmonary bypass and monitored for residual air by TEE & TCD for 10 minutes continually. The LV vent will be re-opened whenever the residual air in the left heart exceeds grade II. The frequency of theses measures will be noted in the protocol. If the patient has by now achieved 36 Celsius core temperature, the heart will be decannulated and CPB removed. Otherwise CPB will be restarted and patient warmed to 36 Celsius before final weaning and decannulation.
Study group ( CO2 insufflation ):
In these patients (n=10) the pleurae will not be opened. During aortic cross-clamp period the ventilator will be adjusted to provide dead space ventilation only i.e. 5cm PEEP, ventilator frequency 5/min and the minute ventilation = 1,5 liter. Fio2 = 50%. The operating field will be insufflated with CO2 at a flow rate of 10 L / minute starting 2 minutes before cardiac cannulation and continued until 10 minutes after termination of the CPB.
At the end of the cardioplegic arrest, the aortic root and the LV will be actively vented and the time noted down (T1). The LV preload will be successively increased by reducing the venous return from the heart-lung machine to raise CVP between 5-10 cm water. LV venting will be continued and when no air bubbles are seen in the left heart (LA, LV & Aorta) under TEE monitoring, the calculated minute ventilation with 100% oxygen and PEEP of 5 cm H2O will be restored. De-airing will be continued and when no or minimal air is seen in the left heart the time will be noted down (T2) (T2 - T1 = Pre ejection de-airing time). Aortic cross-clamp will be released now and heart defibrillated to sinus or pacemaker induced rhythm and de-airing continued. At 35 Celsius body temperature, as measured from the thermistor in the urinary bladder, and with apparently good cardiac contraction the patient will be weaned successively from the CPB ensuring thereby that the entire cardiac output is diverted through the native fully ventilated lungs. Inotropic drugs or systemic arterial vasodilators will be used as and when necessary to achieve good cardiac contraction. When TEE will show no air in the left heart, the de-airing will be considered complete and the time noted again (T3) (T3 - T2 = Post ejection de-airing time). The patient will be weaned completely from the cardiopulmonary bypass and all cardiac cannulae including the LV vent will be left in situ but clamped. The patient will be monitored now for residual air by TEE & TCD for 10 minutes continually. The LV vent will be re-opened whenever the residual air showing on TEE in the left heart exceeds grade II. The frequency of theses measures will be noted in the protocol. The C02 insufflations will continue until the 10- minute post CPB monitoring interval is completed. If patient by now has achieved 36 Celsius core temperature, the heart will be decannulated and CPB removed. Otherwise CPB will be restarted and patient warmed to 36 Celsius before final weaning and decannulation.
Trans-esophageal echocardiographic study (TEE):
After completion of the cardioplegic arrest and for 10 minutes after termination of the CPB, all the patients will be monitored by TEE for air in the left heart. The residual air showing on TEE after the termination of CPB will be quantified in 4 grades depending upon presence of air in LA, LV and aortic root during one cardiac cycle (grade 0 = no or occasional air in LA, grade 1 = air showing in LA only, grade 2 = air showing simultaneously in LA and LV, grade 3 = air showing simultaneously in LA, LV and the aortic root). The 10-minute post CPB TEE recording will be saved on a video-tape.
Trans-cranial echo-doppler study (TCD):
After release of the aortic cross clamp and for 10 minutes after the patient has been weaned off from the CPB, the patient will be continuously monitored for micro embolic signals by on-line automatic TCD placed on middle cerebral arteries.
Blood gases will be monitored in all patients as following:
Blood gas analysis from arterial & venous blood of the patient every 15 minutes in the operating room in both groups until 15 minutes post CPB) - following attached tables (Anesthesia, Perfusion and TCD & Invous monitoring)
Measurement of end-tidal PCO2 and volume of expired CO2 every 15 minutes after the patient is intubated and till the time patient leaves the operating room in both groups. (No measurements possible in the control group during cardioplegic arrest)
Blood gas analysis from arterial & venous blood lines of the oxygenator and from the LV vent line every 15 minutes while the patient is on CPB in both groups.
Continuous on-line monitoring of CO2 content and PCO2 in the blood at the inflow and outflow ports of the oxygenator in both groups using CDI & new machine. Variations in gas flow and the FiO2 needed to adjust PaCO2 to within a fixed desirable range will be recorded and extra blood gas sample will be taken whenever any such adjustment is made.
Alfa stat will be employed for blood gas analysis. A core temperature at 30 C will be used for all patients unless positively indicted.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Lund de-airing | Experimental | Lund de-airing technique |
|
| Carbon-dioxide insufflation | Active Comparator | carbon-dioxide insufflation will be provided to the open mediastinal wound in a standardized manner |
|
| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Lund de-airing technique | Procedure | In these patients the pleura will be opened on both sides and the ventilator will be disconnected before aorta is cross-clamped and cardioplegia administered. At the conclusion of the surgical procedure, the LV preload will first now be successively increased. When no air is seen on TEE monitoring in the left heart (LA, LV & Aorta), half the calculated minute ventilation with 100% oxygen and a PEEP of 5 cm H2O will be started. Deairing will be continued and when the TEE shows no or minimal air in left heart, full ventilation with unchanged PEEP will be restored. The patient will be weaned successively from the CPB. When TEE will show no air in the left heart, the de-airing will be considered complete. |
| Measure | Description | Time Frame |
|---|---|---|
| Number of Air Microemboli Registered Over the Middle Cerebral Arteries by On-line Trans-cranial Echo-Doppler (TCD). | The number of air microemboli (also referred to as gaseous microembolic signals) was concomitantly counted in the right and left medial cerebral artery. The number of signals from the right and the left medial cerebral artery were summed, and presented as the total sum of the gaseous micromebolic signals from the right and left side. Counting of gaseous microembolic signals was done during three time intervals: Before cardiac ejection, after cardiac ejection and during 10 minutes after cardiopulmonary bypass. | Before cardiac ejection |
| Number of Air Microemboli Registered Over the Middle Cerebral Arteries by On-line Trans-cranial Echo-Doppler (TCD). | The number of air microemboli (also referred to as gaseous microembolic signals) was concomitantly counted in the right and left medial cerebral artery. The number of signals from the right and the left medial cerebral artery were summed, and presented as the total sum of the gaseous micromebolic signals from the right and left side. Counting of gaseous microembolic signals was done during three time intervals: Before cardiac ejection, after cardiac ejection and during 10 minutes after cardiopulmonary bypass. | After cardiac ejection |
| Number of Air Microemboli Registered Over the Middle Cerebral Arteries by On-line Trans-cranial Echo-Doppler (TCD). | The number of air microemboli (also referred to as gaseous microembolic signals) was concomitantly counted in the right and left medial cerebral artery. The number of signals from the right and the left medial cerebral artery were summed, and presented as the total sum of the gaseous micromebolic signals from the right and left side. Counting of gaseous microembolic signals was done during three time intervals: Before cardiac ejection, after cardiac ejection and during 10 minutes after cardiopulmonary bypass. | During 10 minutes after cardiopulmonary bypass |
| Number of Participants With <=Grade I Gas Emboli as Assessed by Trans-esophageal Echocardiography TEE). |
| Measure | Description | Time Frame |
|---|---|---|
| Total Time Required for De-airing | The total de-airing time as measured in minutes. | After removal of aortic cross-clamp to complete de-airing, an average of 11 minutes |
| De-airing Time Before Cardiac Ejection |
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Inclusion Criteria:
Exclusion Criteria:
Patients with known
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| Name | Affiliation | Role |
|---|---|---|
| Bansi L Koul, MD, PhD | Cardiothoracic Surgery, Heart & Lung Division, University Hospital Lund, Sweden | Principal Investigator |
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| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 23246060 | Derived | Landenhed M, Al-Rashidi F, Blomquist S, Hoglund P, Pierre L, Koul B. Systemic effects of carbon dioxide insufflation technique for de-airing in left-sided cardiac surgery. J Thorac Cardiovasc Surg. 2014 Jan;147(1):295-300. doi: 10.1016/j.jtcvs.2012.11.010. Epub 2012 Dec 13. | |
| 20817209 | Derived | Al-Rashidi F, Landenhed M, Blomquist S, Hoglund P, Karlsson PA, Pierre L, Koul B. Comparison of the effectiveness and safety of a new de-airing technique with a standardized carbon dioxide insufflation technique in open left heart surgery: a randomized clinical trial. J Thorac Cardiovasc Surg. 2011 May;141(5):1128-33. doi: 10.1016/j.jtcvs.2010.07.013. Epub 2010 Sep 3. |
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All 20 consecutive patients recruited in the study fullfilled the inclusion criteria. No patient was excluded.
Patients requiring elective aortic valve or aortic root surgery on the waiting list of the clinic were recruited in the study during year 2009.
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| ID | Title | Description |
|---|---|---|
| FG000 | Lund De-airing Technique | Before cardiopulmonary bypass (CPB) was established, both pleural cavities were exposed to atmospheric air through small openings in the mediastinal pleurae. After CPB was established the patient was disconnected from the ventilator, allowing both lungs to collapse. After completion of the surgical procedure the aortic crossclamp was released and the heart was then defibrillated. After a good cardiac contraction and normal central hemodynamics, the LV preload was gradually and successively. When no air emboli were observed in the left side of the heart by Trans-esophageal Echocardiography (TEE), the patient was reconnected to the ventilator and the lungs were ventilated with half of the estimated minute volume using 100% oxygen and 5 cm H2O positive end-expiratory pressure. The de-airing was continued, and when no air emboli were observed in the left side of the heart, the lungs were ventilated to full capacity and the heart was allowed to eject by reducing the LV vent. |
| FG001 | Carbon-dioxide Insufflation Technique | The pleural cavities were left intact in the carbon-dioxide(CO2) group. During cardiopulmonary bypass (CPB), the patient was administered dead space ventilation. Before the cannulation for CPB, the CO2 was insufflated in the mediastinum at a flow rate of 10 L/min and continued until 10 minutes post-CPB. After completed surgery, the heart and lungs were passively filled with blood from the CPB circuit and the left side was de-aired continuously through the LV apical vent. Full ventilation was then resumed. The heart was defibrillated and the LV preload was gradually and successively increased by reducing the venous return to the CPB circuit. The de-airing continued through the vent in the LV apex under TEE monitoring. When no gas emboli were observed in the left side of the heart, the LV vent was reduced and the heart was allowed to ject. De-airing was continued, and when no further gas emboli were observed in the left side of the heart, the patient was weaned from CPB. |
| Title | Milestones | Reasons Not Completed | ||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Overall Study |
|
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| ID | Title | Description |
|---|---|---|
| BG000 | Lund De-airing Technique | Before cardiopulmonary bypass (CPB) was established, both pleural cavities were exposed to atmospheric air through small openings in the mediastinal pleurae. Hereafter the patient was disconnected from the ventilator, allowing both lungs to collapse. After completion of the surgical procedure the aortic crossclamp was released and the heart defibrillated. After a good cardiac contraction and normal central hemodynamics were established, the LV preload was gradually and successively increased. When no air emboli were observed in the left side of the heart by transesophageal echocardiography (TEE), the patient was reconnected to the ventilator and the lungs were ventilated with half of the estimated minute volume using 100% oxygen and 5 cm H2O positive end-expiratory pressure. The deairing was continued, and when no air emboli were observed in the left side of the heart, the lungs were ventilated to full capacity and the heart was allowed to eject by reducing the LV vent. |
| Units | Counts |
|---|---|
| Participants |
|
| Title | Description | Population Description | Parameter Type | Dispersion Type | Unit of Measure | Calculate Percentage | Denominator Units Selected | Denominators | Classes |
|---|---|---|---|---|---|---|---|---|---|
| Age, Categorical | Count of Participants |
| Type | Title | Description | Population Description | Reporting Status | Anticipated Posting Date | Parameter Type | Dispersion Type | Unit of Measure | Calculate Percentage | Time Frame | Units Analyzed | Denominator Units Selected | Arm/Group Information | Denominators | Classes | Analyses | |||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Primary | Number of Air Microemboli Registered Over the Middle Cerebral Arteries by On-line Trans-cranial Echo-Doppler (TCD). | The number of air microemboli (also referred to as gaseous microembolic signals) was concomitantly counted in the right and left medial cerebral artery. The number of signals from the right and the left medial cerebral artery were summed, and presented as the total sum of the gaseous micromebolic signals from the right and left side. Counting of gaseous microembolic signals was done during three time intervals: Before cardiac ejection, after cardiac ejection and during 10 minutes after cardiopulmonary bypass. | Posted | Mean | Standard Deviation | Air Microemboli | Before cardiac ejection |
|
Data was collected during the postoperative course when patient was still in ward (median time 7 Days).
Method of detecting adverse events was screening of patients charts for reports of neurological dysfunction.
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| ID | Title | Description | Deaths (Affected) | Deaths (At Risk) | Serious Events (Affected) | Serious Events (At Risk) | Other Events (Affected) | Other Events (At Risk) |
|---|---|---|---|---|---|---|---|---|
| EG000 | Lund De-airing | Before CPB was started, both pleural cavities were exposed to atmospheric air through small openings in the mediastinal pleurae. After CPB was established the patient was disconnected from the ventilator, allowing both lungs to collapse. After completion of the surgical procedure the aortic crossclamp was released and the heart was then defibrillated. After a good cardiac contraction and normal central hemodynamics, the LV preload was gradually and successively. When no air emboli were observed in the left side of the heart, the patient was reconnected to the ventilator and the lungs were ventilated with half of the estimated minute volume using 100% oxygen and 5 cm H2O positive end-expiratory pressure. The deairing was continued, and when no air emboli were observed in the left side of the heart, the lungs were ventilated to full capacity and the heart was allowed to eject by reducing the LV vent. |
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| Term | Organ System | Source Vocabulary | Assessment Type | Notes | Statistical Information |
|---|---|---|---|---|---|
| Postoperative neurological dysfunction | Nervous system disorders | SNOMED CT | Non-systematic Assessment | Any sign of postoperative confusion, agitation or disorientation OR focal neurological deficit with or without cerebral computer tomography performed. |
This study included a total of 20 patients randomized to one of two groups with ten patients in each arms. The small number of study objects might be a potential limitation.
| Title | Organization | Phone | Extension | |
|---|---|---|---|---|
| Dr. Bansi Koul MD, PhD, Principal Investigator | Cardiothoracic Surgery, Skåne University Hospital Lund | +46 46 171649 | bansi.koul@skane.se |
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| ID | Term |
|---|---|
| D000082862 | Aortic Valve Disease |
| ID | Term |
|---|---|
| D006349 | Heart Valve Diseases |
| D006331 | Heart Diseases |
| D002318 | Cardiovascular Diseases |
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|
|
| carbon-dioxide insufflation | Drug | In these patients (n=10) the pleurae will not be opened. During aortic cross-clamp period the ventilator will be adjusted to provide dead space ventilation only i.e. 5cm PEEP, ventilator frequency 5/min and the minute ventilation = 1,5 liter. Fio2 = 50%. The operating field will be insufflated with Co2 at a flow rate of 10 L / minute starting 2 minutes before cardiac cannulation and continued until 10 minutes after termination of the CPB.At the end of the cardioplegic arrest, the de-airing procedure is similar to that in the Lund de-airing group. |
|
|
Grade 0, no residual gas emboli; grade I, gas emboli observed in 1 of the 3 anatomic areas - left atrium, left ventricle or aortic root during 1 cardiac cycle; grade II, gas emboli observed simultaneously in 2 of the 3 anatomic areas during 1 cardiac cycle; grade III, gas emboli observed simultaneously in all 3 anatomic areas during 1 cardiac cycle. |
| 0-3 minutes after end of cardiopulmonary bypass |
| Number of Participants With <=Grade I Gas Emboli as Assessed by Trans-esophageal Echocardiography TEE). | Grade 0, no residual gas emboli; grade I, gas emboli observed in 1 of the 3 anatomic areas - left atrium, left ventricle or aortic root during 1 cardiac cycle; grade II, gas emboli observed simultaneously in 2 of the 3 anatomic areas during 1 cardiac cycle; grade III, gas emboli observed simultaneously in all 3 anatomic areas during 1 cardiac cycle. | 3-6 minutes after end of cardiopulmonary bypass |
| Number of Participants With <=Grade I Gas Emboli as Assessed by Trans-esophageal Echocardiography TEE). | Grade 0, no residual gas emboli; grade I, gas emboli observed in 1 of the 3 anatomic areas - left atrium, left ventricle or aortic root during 1 cardiac cycle; grade II, gas emboli observed simultaneously in 2 of the 3 anatomic areas during 1 cardiac cycle; grade III, gas emboli observed simultaneously in all 3 anatomic areas during 1 cardiac cycle. | 6-10 minutes after end of cardiopulmonary bypass |
Time in minutes starting at t1 (removal of aortic cross clamp) and ending at t2 (beginning of cardiac ejection).
| Measured during intraoperative course |
| De-airing Time After Cardiac Ejection | The duration in minutes of the period after cardiac ejection to finished de-airing procedure. | During de-airing procedure |
| Oxygenator Gas Flow at 45 Minutes of CPB | The amount of carbon dioxide gas flow through the oxygenator was measured and compared between groups. | Intraoperative |
| pH at 45 Min of CPB | pH measured by arterial bloodgas at 45 minutes of CPB, comparison between groups | Intraoperative |
| BG001 | Carbon-dioxide Insufflation Technique | The pleural cavities were left intact in the CO2 (carbon-dioxide) group. During cardiopulmonary bypass (CPB), the patient was administered dead space ventilation. Before cannulation, CO2 was insufflated in the mediastinum at a flow rate of 10 litres/minute and continued until 10 minutes post-CPB. After completed surgery, the heart and lungs were passively re-filled with blood and the left side was de-aired continuously through the LV apical vent. Full ventilation was then resumed. The heart was defibrillated and the LV preload was gradually and successively increased by reducing the venous return to the CPB circuit. The de-airing continued through the vent in the LV apex under transesophageal echocardiographic (TEE) monitoring. When no gas emboli were observed in the left side of the heart, the LV vent was reduced and the heart was allowed to eject. De-airing was continued, and when no further gas emboli were observed in the left side of the heart, the patient was weaned from CPB. |
| BG002 | Total | Total of all reporting groups |
| Participants |
|
| Age Continuous | Mean | Standard Deviation | years |
|
| Sex: Female, Male | Count of Participants | Participants |
|
| Region of Enrollment | Number | participants |
|
| OG001 | Carbon-dioxide Insufflation Technique | The pleural cavities were left intact in the CO2 (carbon-dioxide) group. During cardiopulmonary bypass (CPB), the patient was administered dead space ventilation. Before CPB, the CO2 was insufflated in the mediastinum at a flow rate of 10 L/min and continued until 10 minutes post-CPB. After completion of the surgical procedure, the heart and lungs were passively filled with blood from the CPB circuit and the left side was de-aired continuously through the LV apical vent. Full ventilation was then resumed. The heart was defibrillated and the LV preload was gradually and successively increased by reducing the venous return to the CPB circuit. The de-airing continued through the vent in the LV apex under TEE monitoring. When no gas emboli were observed in the left side of the heart, the LV vent was reduced and the heart was allowed to ject. De-airing was continued, and when no further gas emboli were observed in the left side of the heart, the patient was weaned from C |
|
|
|
| Secondary | Total Time Required for De-airing | The total de-airing time as measured in minutes. | Posted | Median | Inter-Quartile Range | Minutes | After removal of aortic cross-clamp to complete de-airing, an average of 11 minutes |
|
|
|
| Secondary | De-airing Time Before Cardiac Ejection | Time in minutes starting at t1 (removal of aortic cross clamp) and ending at t2 (beginning of cardiac ejection). | Posted | Median | Inter-Quartile Range | minutes | Measured during intraoperative course |
|
|
|
| Primary | Number of Air Microemboli Registered Over the Middle Cerebral Arteries by On-line Trans-cranial Echo-Doppler (TCD). | The number of air microemboli (also referred to as gaseous microembolic signals) was concomitantly counted in the right and left medial cerebral artery. The number of signals from the right and the left medial cerebral artery were summed, and presented as the total sum of the gaseous micromebolic signals from the right and left side. Counting of gaseous microembolic signals was done during three time intervals: Before cardiac ejection, after cardiac ejection and during 10 minutes after cardiopulmonary bypass. | Posted | Mean | Standard Deviation | Air Microemboli | After cardiac ejection |
|
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|
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| Secondary | De-airing Time After Cardiac Ejection | The duration in minutes of the period after cardiac ejection to finished de-airing procedure. | Posted | Median | Inter-Quartile Range | minutes | During de-airing procedure |
|
|
|
| Secondary | Oxygenator Gas Flow at 45 Minutes of CPB | The amount of carbon dioxide gas flow through the oxygenator was measured and compared between groups. | Posted | Median | Inter-Quartile Range | L/minute | Intraoperative |
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| Post-Hoc | Fraction of Morphologically Damaged Red Blood Cells as Assessed by Scanning Electron Microscopy Studies. | Pieces of tubing from the cardiopulmonary circuit were prepared and photographed in a Scanning Electron Microscope. Visual inspection of each photograph by an investigator blinded to which group the photograph belonged to was performed. The proportion of damaged red blood cells over the total number of red blood cells were calculated. | Samples were collected from 5 participants in each Group (total of 10 participants). For each participant 4 pieces of tubing were collected (20 pieces in each Group, total 40 pieces). Samples were photographed. One photograph from each individual was randomly selected and studied by an investigator blinded to Group (total of 10 photographs). | Posted | Mean | 95% Confidence Interval | Fraction of Damaged Red Blood Cells | Pieces of tubing collected after weaning from cardiopulmonary bypass |
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| Secondary | pH at 45 Min of CPB | pH measured by arterial bloodgas at 45 minutes of CPB, comparison between groups | Posted | Median | Inter-Quartile Range | units on a scale | Intraoperative |
|
|
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| Primary | Number of Air Microemboli Registered Over the Middle Cerebral Arteries by On-line Trans-cranial Echo-Doppler (TCD). | The number of air microemboli (also referred to as gaseous microembolic signals) was concomitantly counted in the right and left medial cerebral artery. The number of signals from the right and the left medial cerebral artery were summed, and presented as the total sum of the gaseous micromebolic signals from the right and left side. Counting of gaseous microembolic signals was done during three time intervals: Before cardiac ejection, after cardiac ejection and during 10 minutes after cardiopulmonary bypass. | Posted | Mean | Standard Deviation | Air Microemboli | During 10 minutes after cardiopulmonary bypass |
|
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| Primary | Number of Participants With <=Grade I Gas Emboli as Assessed by Trans-esophageal Echocardiography TEE). | Grade 0, no residual gas emboli; grade I, gas emboli observed in 1 of the 3 anatomic areas - left atrium, left ventricle or aortic root during 1 cardiac cycle; grade II, gas emboli observed simultaneously in 2 of the 3 anatomic areas during 1 cardiac cycle; grade III, gas emboli observed simultaneously in all 3 anatomic areas during 1 cardiac cycle. | The number was determined before hand as per protocoll. | Posted | Number | participants | 0-3 minutes after end of cardiopulmonary bypass |
|
|
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| Primary | Number of Participants With <=Grade I Gas Emboli as Assessed by Trans-esophageal Echocardiography TEE). | Grade 0, no residual gas emboli; grade I, gas emboli observed in 1 of the 3 anatomic areas - left atrium, left ventricle or aortic root during 1 cardiac cycle; grade II, gas emboli observed simultaneously in 2 of the 3 anatomic areas during 1 cardiac cycle; grade III, gas emboli observed simultaneously in all 3 anatomic areas during 1 cardiac cycle. | The number was determined before hand as per protocoll. | Posted | Number | participants | 3-6 minutes after end of cardiopulmonary bypass |
|
|
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| Primary | Number of Participants With <=Grade I Gas Emboli as Assessed by Trans-esophageal Echocardiography TEE). | Grade 0, no residual gas emboli; grade I, gas emboli observed in 1 of the 3 anatomic areas - left atrium, left ventricle or aortic root during 1 cardiac cycle; grade II, gas emboli observed simultaneously in 2 of the 3 anatomic areas during 1 cardiac cycle; grade III, gas emboli observed simultaneously in all 3 anatomic areas during 1 cardiac cycle. | The number was determined before hand as per protocoll. | Posted | Number | participants | 6-10 minutes after end of cardiopulmonary bypass |
|
|
|
| 0 |
| 10 |
| 1 |
| 10 |
| EG001 | Carbon-dioxide Insufflation | The pleural cavities were left intact in the CO2 group. During CPB, the patient was administerd dead space ventilation. Before the cannulation for CPB, the CO2 was insufflated in the mediastinum at a flow rate of 10 L/min and continued until 10 minutes post-CPB. After completion of the surgical procedure, the heart and lungs were passively filled with blood from the CPB circuit and the left side was de-aired continuously through the LV apical vent. Full ventilation was then resumed. The heart was defibrillated and the LV preload was gradually and successively increased by reducing the venous return to the CPB circuit. The de-airing continued through the vent in the LV apex under TEE monitoring. When no gas emboli were observed in the left side of the heart, the LV vent was reduced and the heart was allowed to ject. De-airing was continued, and when no further gas emboli were observed in the left side of the heart, the patient was weaned from CPB. | 0 | 10 | 1 | 10 |
|
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