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Plasma CO2 Removal Due to CRRT and Its Influence on Indirect Calorimetry (MECCIAS)

Primary Purpose

Continuous Renal Replacement Therapy, CO2 Removal, Nutrition Poor

Status

Completed

Phase

Not Applicable

Locations

Belgium

Study Type

Interventional

Intervention

blood gas analysis under citrate predilution

filter replacement

NaCl predilution

blood gas analysis under NaCl predilution

double ultrafiltration

blood gas analysis under citrate predilution and double ultrafiltration rate

pause and restart nutritional therapy

evolution of vitamin and trace elements

About this trial

This is an interventional diagnostic trial for Continuous Renal Replacement Therapy focused on measuring Calorimetry, Indirect, respiratory dialysis

Eligibility Criteria

18 Years - undefined (Adult, Older Adult)All SexesDoes not accept healthy volunteers

Inclusion Criteria:

AKI requiring CRRT
Patient on CRRT who's filter you want to change
Expected stable patient during the test ( +- 2h) evaluated at discretion of physician :
- No alteration in medication
- Stable respiratory settings where no change in conditions is expected. If possible, controlled mode ventilation is preferred.
- Expected stable pH and lactate
- no intervention will be made on patient (transport/washing/physiotherapy/…)
- no alterations on settings of CRRT is expected to be made.
Maximal respiratory settings: max FiO2: 60% / max inspiratory plateau pressure 30 mmHg/max tidal volumes 8ml/kg
pH between 7,30-7,50, lactate levels <2,0
starting settings CRRT with citrate:
- Blood pump flow: 150 ml/min
- Predilution ( citrate): 1500-2300ml/h
- Dialysate dose: 25-40 ml/kg/h
- ultrafiltration: 0-300 ml /h
- Substitution: NaCl 300-800 ml/h or B22: 400-2000 ml/h

Exclusion Criteria:

Pregnancy / lactation
Contra-indications for the use of indirect calorimetry as stated by the AARC (FiO2>60%, chest tubes)
Severe hemodynamic or ventilator instability.
CRRT modalities unusual to daily clinical ICU practice

Sites / Locations

universitair ziekenhuis Brussel

Arms of the Study

Arm 1

Arm Type

Other

Arm Label

all patients

Arm Description

Classic CRRT with citrate predilution

Outcomes

Primary Outcome Measures

change in CO2 flow and O2 flow on different sample points of CRRT

CO2 flow and O2 flow ( ml/min) will be compared between the different sample points on CRRT with and without citrate. CO2 flow and O2 flow is calculated by multiplying fluid flow ( ml/min) on different sample points of CRRT with CO2 content or O2 content of fluid on respective sample points during CRRT with and without Citrate.

REE change due to CRRT

REE ( Kcal) will be measured during the whole procedure using IC. REE will be measured during CRRT. citrate wil be replaced by NaCl 0,9% fluid and REE will be measured. After this, CRRT will be stopped and REE will be measured. The difference in REE during CRRT with and without citrate and without CRRT will be calculated and compared. REE is calculated using the weir equation and VO2, VCO2. VO2 and VCO2 is calculated using FiO2, FeO2, FiCO2, FeCO2 and VE.

does change in CO2 flow and O2 flow on different sample points of CRRT correlate with VCO2 and VO2 change due to CRRT with or without citrate

VCO2 and VO2 change due to CRRT and due to citrate will be correlated with change in CO2 and O2 flow of fluids passing through CRRT with or without citrate.

Are vitamins and trace elements sufficiently supplemented with standard nutritional therapy during CRRT

blood analysis for concentrations of Vitamin A, B1, B6, B9, B12, C, D, E ; trace elements selenium, zinc, copper, chrome; and cholesterol and triglyceride

Secondary Outcome Measures

VCO2 and VO2 change due to CRRT with or without citrate

VCO2 and VO2 ( ml/min) will be measured during the whole procedure using IC. VCO2 and VO2 will be measured during CRRT with citrate. citrate wil be replaced by NaCl 0,9% fluid and VCO2 and VO2 will be measured. After this, CRRT will be stopped and VCO2 and VO2 will be measured. The difference in VCO2 and VO2 during CRRT with or without citrate and without CRRT will be calculated and compared. VO2 and VCO2 is calculated using FiO2, FeO2, FiCO2, FeCO2 and VE.

FiO2, FeO2, FiCO2 and FeCO2 change due to CRRT with or without citrate

FiO2, FeO2, FiCO2 and FeCO2 ( %) will be measured during the whole procedure using IC. FiO2, FeO2, FiCO2 and FeCO2 will be measured during CRRT with citrate. citrate wil be replace by NaCl0,9% fluid and FiO2, FeO2, FiCO2 and FeCO2 will be measured. After this CRRT will be stopped and FiO2, FeO2, FiCO2 and FeCO2 will be measured. The difference in FiO2, FeO2, FiCO2 and FeCO2 during CRRT with or without citrate and without CRRT will be calculated.

VE change due to CRRT with or without citrate

VE( ml/min) will be measured during the whole procedure using IC. VE will be measured during CRRT with citrate. citrate wil be replace by NaCl0,9% fluid and VE will be measured. After this CRRT will be stopped and VE will be measured. The difference in VE during CRRT with or without citrate and without CRRT will be calculated.

change in CO2 and O2 content of fluid passing through CRRT

using blood gas analyser, CO2 content and O2content ( mmol/L)of fluid on different sample points in extracorporeal circuit of CRRT with or without citrate will be analysed and compared.

change in bicarbonate content of fluid passing through CRRT

using blood gas analyser, bicarbonate ( mmol/L) of fluid on different sample points in extracorporeal circuit of CRRT with or without citrate will be analysed and compared.

change in pH change of fluid passing through CRRT

using blood gas analyser, pH of fluid on different sample points in extracorporeal circuit of CRRT with or without citrate will be analysed and compared

change in pCO2 and pO2 change of fluid passing through CRRT

using blood gas analyser, pCO2 and pO2 (mmHg) of fluid on different sample points in extracorporeal circuit of CRRT with or without citrate will be analysed and compared.

Full Information

NCT ID

NCT03314363

First Posted

July 3, 2017

Last Updated

May 17, 2022

Sponsor

Universitair Ziekenhuis Brussel

1. Study Identification

Unique Protocol Identification Number

NCT03314363

Brief Title

Plasma CO2 Removal Due to CRRT and Its Influence on Indirect Calorimetry

Acronym

MECCIAS

Official Title

MEtabolic Consequences of Continuous Renal Replacement Therapy and Impact on Indirect cAlorimetry Study

Study Type

Interventional

2. Study Status

Record Verification Date

May 2022

Overall Recruitment Status

Completed

Study Start Date

April 26, 2017 (Actual)

Primary Completion Date

March 15, 2019 (Actual)

Study Completion Date

March 15, 2019 (Actual)

3. Sponsor/Collaborators

Responsible Party, by Official Title

Principal Investigator

Name of the Sponsor

Universitair Ziekenhuis Brussel

4. Oversight

Studies a U.S. FDA-regulated Drug Product

Studies a U.S. FDA-regulated Device Product

Product Manufactured in and Exported from the U.S.

Yes

Data Monitoring Committee

5. Study Description

Brief Summary

The aim of the present study is to assess the metabolic impact of Continuous Renal Replacement Therapy and overview the obstacles and important factors compromising the use of Indirect Calorimetry in CRRT and suggest a model to overcome these issues.

Detailed Description

Acute kidney injury (AKI) complicates a critical illness from 13% up to 78%, needing renal replacement therapy (RRT) up to10 % of all patients in the intensive care unit (ICU). Both intermittent (IRRT) and continuous renal replacement therapy (CRRT) are used. The advantage of the latter is that it has lesser influence on hemodynamics and is better tolerated in critical ill patients. Another complication during their stay is the inability to feed themselves. Nutrition is a cornerstone in the care for the critical ill and should be started within 3 days of admission to the intensive care unit. To optimize a nutritional prescription, protein and energy targets need to be defined. Predicting formulae based on anthropometric measures and other parameters can be used to calculate the caloric need but indirect calorimetry (IC) remains the gold standard. Caloric need can be derived from Energy expenditure which is calculated with the Weir's equation using carbon dioxide (CO2) production (VCO2) and oxygen (O2) consumption (VO2). Therefore, it is underestimated if CO2 is lost through other means than the normal respiratory route. Hence one of the contra-indications of IC is CRRT. The totalCO2 (tCO2) travels through the vascular structures within the red blood cells or inside plasma. There, most of the content has 3 different forms: as physically dissolved CO2, bicarbonate, and carbamino compounds. These compounds are in equilibrium with each other. During RRT, a potential loss of CO2 and its different forms may occur due to ultrafiltration in the dialysate. No large trials were conducted trying to quantify this loss nor identifying the determining factors which can be used to predict this loss. Indeed, one author even found a gain in tCO2 of the blood during dialysis with acetate. Trisodiumcitrate is used as an anticoagulant during CRRT. It is a weak base and due to pH change may alter the equilibrium of the Henderson-Hasselbalch equation and thus influence the balance between CO2 and HCO3- and its extraction through CRRT. Although indirect calorimetry in the intensive care unit has been evaluated during CRRT, the loss of tCO2was not considered. The investigators explored the possibility to predict and easily calculate this CO2 exchange so IC can be used during CRRT.

6. Conditions and Keywords

Primary Disease or Condition Being Studied in the Trial, or the Focus of the Study

Continuous Renal Replacement Therapy, CO2 Removal, Nutrition Poor, Acute Renal Failure

Keywords

Calorimetry, Indirect, respiratory dialysis

7. Study Design

Primary Purpose

Diagnostic

Study Phase

Not Applicable

Interventional Study Model

Single Group Assignment

Masking

None (Open Label)

Allocation

N/A

Enrollment

10 (Actual)

8. Arms, Groups, and Interventions

Arm Title

all patients

Arm Type

Other

Arm Description

Classic CRRT with citrate predilution

Intervention Type

Diagnostic Test

Intervention Name(s)

blood gas analysis under citrate predilution

Intervention Description

blood gas analysis of blood on different sample points and dialysis fluid

Intervention Type

Device

Intervention Name(s)

filter replacement

Intervention Description

Using local protocol: stop and disconnect CRRT, replace filter and reconnect and restart CRRT.

Intervention Type

Device

Intervention Name(s)

Intervention Description

monitor patients during the whole study period with indirect calorimetry

Intervention Type

Drug

Intervention Name(s)

NaCl predilution

Intervention Description

Replace citrate predilution with NaCl

Intervention Type

Diagnostic Test

Intervention Name(s)

blood gas analysis under NaCl predilution

Intervention Description

repeat blood gas analysis of blood on different sample points and dialysis fluid

Intervention Type

Drug

Intervention Name(s)

double ultrafiltration

Intervention Description

double the ultrafiltration fluid by augmenting post dilution fluid and keeping ultrafiltration at the same rate.

Intervention Type

Diagnostic Test

Intervention Name(s)

blood gas analysis under citrate predilution and double ultrafiltration rate

Intervention Description

repeat blood gas analysis of blood on different sample points and dialysis fluid

Intervention Type

Dietary Supplement

Intervention Name(s)

pause and restart nutritional therapy

Intervention Description

pause parenteral and enteral nutrition before indirect calorimetry is performed. and restart after first blood analysis for vitamine status

Intervention Type

Diagnostic Test

Intervention Name(s)

evolution of vitamin and trace elements

Intervention Description

blood analysis for vitamin and trace elements. Perform this blood analysis after restart of CRRT but before restart of nutritional therapy, 30 minutes after restart of nutritional therapy and 24h after restart of nutritional therapy.

Primary Outcome Measure Information:

Title

change in CO2 flow and O2 flow on different sample points of CRRT

Description

Time Frame

2hours

Title

REE change due to CRRT

Description

Time Frame

2hours

Title

does change in CO2 flow and O2 flow on different sample points of CRRT correlate with VCO2 and VO2 change due to CRRT with or without citrate

Description

VCO2 and VO2 change due to CRRT and due to citrate will be correlated with change in CO2 and O2 flow of fluids passing through CRRT with or without citrate.

Time Frame

2 hours

Title

Are vitamins and trace elements sufficiently supplemented with standard nutritional therapy during CRRT

Description

blood analysis for concentrations of Vitamin A, B1, B6, B9, B12, C, D, E ; trace elements selenium, zinc, copper, chrome; and cholesterol and triglyceride

Time Frame

24hours

Secondary Outcome Measure Information:

Title

VCO2 and VO2 change due to CRRT with or without citrate

Description

Time Frame

2 hours

Title

FiO2, FeO2, FiCO2 and FeCO2 change due to CRRT with or without citrate

Description

Time Frame

2hours

Title

VE change due to CRRT with or without citrate

Description

Time Frame

2hours

Title

change in CO2 and O2 content of fluid passing through CRRT

Description

using blood gas analyser, CO2 content and O2content ( mmol/L)of fluid on different sample points in extracorporeal circuit of CRRT with or without citrate will be analysed and compared.

Time Frame

2hours

Title

change in bicarbonate content of fluid passing through CRRT

Description

using blood gas analyser, bicarbonate ( mmol/L) of fluid on different sample points in extracorporeal circuit of CRRT with or without citrate will be analysed and compared.

Time Frame

2hours

Title

change in pH change of fluid passing through CRRT

Description

using blood gas analyser, pH of fluid on different sample points in extracorporeal circuit of CRRT with or without citrate will be analysed and compared

Time Frame

2hours

Title

change in pCO2 and pO2 change of fluid passing through CRRT

Description

using blood gas analyser, pCO2 and pO2 (mmHg) of fluid on different sample points in extracorporeal circuit of CRRT with or without citrate will be analysed and compared.

Time Frame

2hours

10. Eligibility

Sex

All

Minimum Age & Unit of Time

18 Years

Accepts Healthy Volunteers

Eligibility Criteria

Inclusion Criteria: AKI requiring CRRT Patient on CRRT who's filter you want to change Expected stable patient during the test ( +- 2h) evaluated at discretion of physician : No alteration in medication Stable respiratory settings where no change in conditions is expected. If possible, controlled mode ventilation is preferred. Expected stable pH and lactate no intervention will be made on patient (transport/washing/physiotherapy/…) no alterations on settings of CRRT is expected to be made. Maximal respiratory settings: max FiO2: 60% / max inspiratory plateau pressure 30 mmHg/max tidal volumes 8ml/kg pH between 7,30-7,50, lactate levels <2,0 starting settings CRRT with citrate: Blood pump flow: 150 ml/min Predilution ( citrate): 1500-2300ml/h Dialysate dose: 25-40 ml/kg/h ultrafiltration: 0-300 ml /h Substitution: NaCl 300-800 ml/h or B22: 400-2000 ml/h Exclusion Criteria: Pregnancy / lactation Contra-indications for the use of indirect calorimetry as stated by the AARC (FiO2>60%, chest tubes) Severe hemodynamic or ventilator instability. CRRT modalities unusual to daily clinical ICU practice

Overall Study Officials:

First Name & Middle Initial & Last Name & Degree

Elisabeth De Waele, Phd

Organizational Affiliation

Universitair Ziekenhuis Brussel

Official's Role

Principal Investigator

Facility Information:

Facility Name

universitair ziekenhuis Brussel

City

Brussels

ZIP/Postal Code

1090

Country

Belgium

12. IPD Sharing Statement

Plan to Share IPD

Citations:

PubMed Identifier

23573420

Citation

Case J, Khan S, Khalid R, Khan A. Epidemiology of acute kidney injury in the intensive care unit. Crit Care Res Pract. 2013;2013:479730. doi: 10.1155/2013/479730. Epub 2013 Mar 21.

Results Reference

result

PubMed Identifier

12352040

Citation

Metnitz PG, Krenn CG, Steltzer H, Lang T, Ploder J, Lenz K, Le Gall JR, Druml W. Effect of acute renal failure requiring renal replacement therapy on outcome in critically ill patients. Crit Care Med. 2002 Sep;30(9):2051-8. doi: 10.1097/00003246-200209000-00016.

Results Reference

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17636735

Citation

Rabindranath K, Adams J, Macleod AM, Muirhead N. Intermittent versus continuous renal replacement therapy for acute renal failure in adults. Cochrane Database Syst Rev. 2007 Jul 18;(3):CD003773. doi: 10.1002/14651858.CD003773.pub3.

Results Reference

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19505748

Citation

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Results Reference

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Citation

Wichansawakun S, Meddings L, Alberda C, Robbins S, Gramlich L. Energy requirements and the use of predictive equations versus indirect calorimetry in critically ill patients. Appl Physiol Nutr Metab. 2015 Feb;40(2):207-10. doi: 10.1139/apnm-2014-0276. Epub 2014 Oct 27.

Results Reference

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PubMed Identifier

27373497

Citation

Oshima T, Berger MM, De Waele E, Guttormsen AB, Heidegger CP, Hiesmayr M, Singer P, Wernerman J, Pichard C. Indirect calorimetry in nutritional therapy. A position paper by the ICALIC study group. Clin Nutr. 2017 Jun;36(3):651-662. doi: 10.1016/j.clnu.2016.06.010. Epub 2016 Jun 22.

Results Reference

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PubMed Identifier

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Citation

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Citation

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Results Reference

derived

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Plasma CO2 Removal Due to CRRT and Its Influence on Indirect Calorimetry

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