Difference between revisions of "CRRT (Continuous Renal Replacement Therapy)"
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Provides renal support to patients. Usually veno-venous, but arterio-venous exists too (not covered here). | Provides renal support to patients. Usually veno-venous, but arterio-venous exists too (not covered here). | ||
== | == Properties == | ||
'''Solute removal mechanisms:''' | '''Solute removal mechanisms:''' | ||
* Diffusion | * Diffusion | ||
** Accomplished by passive movement of solute across a membrane | ** Accomplished by passive movement of solute across a membrane (due to a solute concentration gradient, movement from high to low) | ||
** Efficient clearance of low-molecular-weight solutes (< 500-1,500 Daltons) | ** Efficient clearance of low-molecular-weight solutes (< 500-1,500 Daltons) | ||
** Clearance decreases with increasing molecular weight of solute | ** Clearance decreases with increasing molecular weight of solute | ||
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** Clearance of different size of solute similar until the size of the solute reaches with size of the pores | ** Clearance of different size of solute similar until the size of the solute reaches with size of the pores | ||
** Overall CVVH with higher clearance rate than CVVHD for solutes 1,000 to 20,000 Daltons | ** Overall CVVH with higher clearance rate than CVVHD for solutes 1,000 to 20,000 Daltons | ||
'''Membrane characteristics:''' | |||
''' | |||
* | * Geometric: length, mean inner radius, wall thickness, number of pores, number of fibers (determines membrane surface area) | ||
** | * Membrane ultrafiltration coefficient: water permeability of filter | ||
* | * Filter ultrafiltration coefficient: membrane ultrafiltration coefficient multiplied by membrane surface area | ||
* | * Mass transfer area coefficient: overall capacity of membrane to provide diffusive removal of solute | ||
* | * Membrane sieving coefficient: ratio of specific solute concentration in ultrafiltrate (only removed by convection) divided by mean plasma concentration in filter | ||
* Cutoff: molecular weight of the smallest solute retained by the membrane | |||
'''Fluids:''' | |||
== | * Can alter pre/post filter replacement fluid compositions to adjust final electrolyte concentrations in blood | ||
== Types of CRRT (see figure 1 for diagrams) == | |||
[[File:Img 1.png|thumb|Figure 1: Types of CRRT (Recreated based on Tandukar 2019 & Asahi Kasei Medical Co.)]] | |||
'''SCUF (Slow continuous ultrafiltration)''' | |||
* Convection | |||
* Mainly fluid removal | |||
'''CVVH (Continuous venovenous hemofiltration)''' | |||
* Convection | |||
'''CVVHD (Continuous venovenous hemodialysis)''' | |||
* Diffusion | |||
'''CVVHDF (Continuous venovenous hemodiafiltration)''' | |||
* Combination of convection and diffusion | |||
== | == Anesthetic implications<!-- Briefly summarize the anesthetic implications of this comorbidity. --> == | ||
=== | === Indications === | ||
Renal replacement for patients with cardiovascular/hemodynamic instability, acute brain injury, cerebral edema, or raised intracranial pressure (for slow electrolyte correction). | |||
Can be used during liver transplant surgery for help with electrolyte management, acid-base status, and fluid balance. | |||
== | === Intraoperative management<!-- Describe how this comorbidity may influence intraoperative management. --> === | ||
'''Suggested vascular access (in descending order):''' | |||
# Right internal jugular vein | |||
## catheter tip location: SVC/RA | |||
## recommended catheter length: 15 cm | |||
# Femoral vein | |||
## catheter tip location: IVC | |||
## recommended catheter length: 25 cm | |||
# Left internal jugular vein | |||
## catheter tip location: SVC/RA | |||
## recommended catheter length: 20 cm | |||
# Subclavian (dominant arm) | |||
## catheter tip location: SVC/RA | |||
## 14-17 cm from right subclavian, 17 cm from left subclavian | |||
# Subclavian (non-dominant arm) | |||
## catheter tip location: SVC/RA | |||
## 14-17 cm from right subclavian, 17 cm from left subclavian | |||
'''Anticoagulation:''' | |||
* Techniques to reduce clotting risk: intermittent saline flushes, pre-filter dilution, high blood pump speeds, and low filtration fractions | |||
* Common to use regional citrate (infused into blood prior to entering the extra-corporeal circuit); functions by binding calcium; need to monitor ionized calcium | |||
'''Effect on anesthetic drugs:''' | |||
=== | * Mainly affects drugs that are non-protein bound, have a low molecular weight (< 500 Daltons), and possess a low volume of distribution (< 1L/kg) | ||
* Also need to consider solute/drug charge, membrane binding, and hydrophilicity/hydrophobicity | |||
* Common anesthetic drug properties | |||
** Rocuronium: 609 Daltons, Volume of distribution = 0.25 L/kg, protein binding 30% | |||
** Vecuronium: 637 Daltons, Volume of distribution = 0.3-0.4 L/kg, protein binding 60-80% | |||
** Cisatracurium: 1243 Daltons, Volume of distribution = 0.145 L/kg | |||
** Sugammadex: 2178 Daltons, Volume of distribution = 0.15-0.2 L/kg, protein binding 0% | |||
** Propofol: 178 Daltons, Volume of distribution = 0.60 L/kg, protein binding 95% | |||
** Etomidate: 244 Daltons, Volume of distribution = 2.5-4.5 L/kg, protein binding 75% | |||
** Ketamine: 237 Daltons, Volume of distribution = 3.6 L/kg, protein binding 10-30% | |||
** Midazolam: 362 Daltons, Volume of distribution = 1-3.1 L/kg, protein binding 97% | |||
** Dexmedetomidine: 200 Daltons, Volume of distribution = 1.68 L/kg, protein binding 94% | |||
** Fentanyl: 528 Daltons, Volume of distribution = 11 L/kg, protein binding 80-85% | |||
** Remifentanil: 412 Daltons, Volume of distribution = 0.35 L/kg, protein binding 70% | |||
== | == Pathophysiology<!-- Describe the pathophysiology of this comorbidity. Add subsections as needed. -->== | ||
== References == | == References == | ||
Tandukar S, Palevsky PM. Continuous Renal Replacement Therapy: Who, When, Why, and How. Chest. 2019 Mar;155(3):626-638. doi: 10.1016/j.chest.2018.09.004. Epub 2018 Sep 25. PMID: 30266628; PMCID: PMC6435902. | Tandukar S, Palevsky PM. Continuous Renal Replacement Therapy: Who, When, Why, and How. Chest. 2019 Mar;155(3):626-638. doi: 10.1016/j.chest.2018.09.004. Epub 2018 Sep 25. PMID: 30266628; PMCID: PMC6435902. | ||
Neri M, Villa G, Garzotto F, Bagshaw S, Bellomo R, Cerda J, Ferrari F, Guggia S, Joannidis M, Kellum J, Kim JC, Mehta RL, Ricci Z, Trevisani A, Marafon S, Clark WR, Vincent JL, Ronco C; Nomenclature Standardization Initiative (NSI) alliance. Nomenclature for renal replacement therapy in acute kidney injury: basic principles. Crit Care. 2016 Oct 10;20(1):318. doi: 10.1186/s13054-016-1489-9. PMID: 27719682; PMCID: PMC5056503. | |||
Continuous Renal Replacement Therapy (CRRT) | Asahi Kasei Medical Co., Ltd. (n.d.). <nowiki>https://www.asahi-kasei.co.jp/medical/en/apheresis/product/crrt/about/cure.html</nowiki> | Continuous Renal Replacement Therapy (CRRT) | Asahi Kasei Medical Co., Ltd. (n.d.). <nowiki>https://www.asahi-kasei.co.jp/medical/en/apheresis/product/crrt/about/cure.html</nowiki> | ||
Cronin B, O'Brien EO. Intraoperative Renal Replacement Therapy: Practical Information for Anesthesiologists. J Cardiothorac Vasc Anesth. 2022 Aug;36(8 Pt A):2656-2668. doi: 10.1053/j.jvca.2021.10.002. Epub 2021 Oct 8. PMID: 34750060. | Cronin B, O'Brien EO. Intraoperative Renal Replacement Therapy: Practical Information for Anesthesiologists. J Cardiothorac Vasc Anesth. 2022 Aug;36(8 Pt A):2656-2668. doi: 10.1053/j.jvca.2021.10.002. Epub 2021 Oct 8. PMID: 34750060. | ||
Bohorquez H, Koyner JL, Jones CR. Intraoperative Renal Replacement Therapy in Orthotopic Liver Transplantation. Adv Kidney Dis Health. 2023 Jul;30(4):378-386. doi: 10.1053/j.akdh.2023.03.003. PMID: 37657884. | |||
[[Category:Comorbidities]] | [[Category:Comorbidities]] |
Latest revision as of 13:48, 4 May 2024
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Provides renal support to patients. Usually veno-venous, but arterio-venous exists too (not covered here).
Properties
Solute removal mechanisms:
- Diffusion
- Accomplished by passive movement of solute across a membrane (due to a solute concentration gradient, movement from high to low)
- Efficient clearance of low-molecular-weight solutes (< 500-1,500 Daltons)
- Clearance decreases with increasing molecular weight of solute
- Convection
- Accomplished by active movement of solute (due to a pressure gradient) across a membrane
- Limited primarily by size of pores in membrane
- Clearance of different size of solute similar until the size of the solute reaches with size of the pores
- Overall CVVH with higher clearance rate than CVVHD for solutes 1,000 to 20,000 Daltons
Membrane characteristics:
- Geometric: length, mean inner radius, wall thickness, number of pores, number of fibers (determines membrane surface area)
- Membrane ultrafiltration coefficient: water permeability of filter
- Filter ultrafiltration coefficient: membrane ultrafiltration coefficient multiplied by membrane surface area
- Mass transfer area coefficient: overall capacity of membrane to provide diffusive removal of solute
- Membrane sieving coefficient: ratio of specific solute concentration in ultrafiltrate (only removed by convection) divided by mean plasma concentration in filter
- Cutoff: molecular weight of the smallest solute retained by the membrane
Fluids:
- Can alter pre/post filter replacement fluid compositions to adjust final electrolyte concentrations in blood
Types of CRRT (see figure 1 for diagrams)
SCUF (Slow continuous ultrafiltration)
- Convection
- Mainly fluid removal
CVVH (Continuous venovenous hemofiltration)
- Convection
CVVHD (Continuous venovenous hemodialysis)
- Diffusion
CVVHDF (Continuous venovenous hemodiafiltration)
- Combination of convection and diffusion
Anesthetic implications
Indications
Renal replacement for patients with cardiovascular/hemodynamic instability, acute brain injury, cerebral edema, or raised intracranial pressure (for slow electrolyte correction).
Can be used during liver transplant surgery for help with electrolyte management, acid-base status, and fluid balance.
Intraoperative management
Suggested vascular access (in descending order):
- Right internal jugular vein
- catheter tip location: SVC/RA
- recommended catheter length: 15 cm
- Femoral vein
- catheter tip location: IVC
- recommended catheter length: 25 cm
- Left internal jugular vein
- catheter tip location: SVC/RA
- recommended catheter length: 20 cm
- Subclavian (dominant arm)
- catheter tip location: SVC/RA
- 14-17 cm from right subclavian, 17 cm from left subclavian
- Subclavian (non-dominant arm)
- catheter tip location: SVC/RA
- 14-17 cm from right subclavian, 17 cm from left subclavian
Anticoagulation:
- Techniques to reduce clotting risk: intermittent saline flushes, pre-filter dilution, high blood pump speeds, and low filtration fractions
- Common to use regional citrate (infused into blood prior to entering the extra-corporeal circuit); functions by binding calcium; need to monitor ionized calcium
Effect on anesthetic drugs:
- Mainly affects drugs that are non-protein bound, have a low molecular weight (< 500 Daltons), and possess a low volume of distribution (< 1L/kg)
- Also need to consider solute/drug charge, membrane binding, and hydrophilicity/hydrophobicity
- Common anesthetic drug properties
- Rocuronium: 609 Daltons, Volume of distribution = 0.25 L/kg, protein binding 30%
- Vecuronium: 637 Daltons, Volume of distribution = 0.3-0.4 L/kg, protein binding 60-80%
- Cisatracurium: 1243 Daltons, Volume of distribution = 0.145 L/kg
- Sugammadex: 2178 Daltons, Volume of distribution = 0.15-0.2 L/kg, protein binding 0%
- Propofol: 178 Daltons, Volume of distribution = 0.60 L/kg, protein binding 95%
- Etomidate: 244 Daltons, Volume of distribution = 2.5-4.5 L/kg, protein binding 75%
- Ketamine: 237 Daltons, Volume of distribution = 3.6 L/kg, protein binding 10-30%
- Midazolam: 362 Daltons, Volume of distribution = 1-3.1 L/kg, protein binding 97%
- Dexmedetomidine: 200 Daltons, Volume of distribution = 1.68 L/kg, protein binding 94%
- Fentanyl: 528 Daltons, Volume of distribution = 11 L/kg, protein binding 80-85%
- Remifentanil: 412 Daltons, Volume of distribution = 0.35 L/kg, protein binding 70%
Pathophysiology
References
Tandukar S, Palevsky PM. Continuous Renal Replacement Therapy: Who, When, Why, and How. Chest. 2019 Mar;155(3):626-638. doi: 10.1016/j.chest.2018.09.004. Epub 2018 Sep 25. PMID: 30266628; PMCID: PMC6435902.
Neri M, Villa G, Garzotto F, Bagshaw S, Bellomo R, Cerda J, Ferrari F, Guggia S, Joannidis M, Kellum J, Kim JC, Mehta RL, Ricci Z, Trevisani A, Marafon S, Clark WR, Vincent JL, Ronco C; Nomenclature Standardization Initiative (NSI) alliance. Nomenclature for renal replacement therapy in acute kidney injury: basic principles. Crit Care. 2016 Oct 10;20(1):318. doi: 10.1186/s13054-016-1489-9. PMID: 27719682; PMCID: PMC5056503.
Continuous Renal Replacement Therapy (CRRT) | Asahi Kasei Medical Co., Ltd. (n.d.). https://www.asahi-kasei.co.jp/medical/en/apheresis/product/crrt/about/cure.html
Cronin B, O'Brien EO. Intraoperative Renal Replacement Therapy: Practical Information for Anesthesiologists. J Cardiothorac Vasc Anesth. 2022 Aug;36(8 Pt A):2656-2668. doi: 10.1053/j.jvca.2021.10.002. Epub 2021 Oct 8. PMID: 34750060.
Bohorquez H, Koyner JL, Jones CR. Intraoperative Renal Replacement Therapy in Orthotopic Liver Transplantation. Adv Kidney Dis Health. 2023 Jul;30(4):378-386. doi: 10.1053/j.akdh.2023.03.003. PMID: 37657884.