Reperfusion injury medical therapy: Difference between revisions

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==Overview==
==Overview==


The most common myth about the ischemia-reperfusion injury is itself related to [[blood]] flow. One can easily think like if everything is happening due to [[ischemia]] and with the restoration of [[blood flow]], the injury should heal. Here is the trick, [[reperfusion]] in turn further exacerbates the injury mainly due to the formation of [[free radicals]]. There are few approaches that are studied widely and do play a major role in controlling the [[injury]] related to [[ischemia-reperfusion]] injury
The most common myth about the [[Ischemia-reperfusion injury|ischemia-reperfusion]] injury is itself related to [[blood]] flow. One can easily think like if everything is happening due to [[ischemia]] and with the restoration of [[blood flow]], the injury should [[Healing|heal]]. Here is the trick, [[reperfusion]] in turn further exacerbates the injury mainly due to the formation of [[free radicals]]. There are few approaches that are studied widely and do play a major role in controlling the [[injury]] related to [[ischemia-reperfusion injury]]  


* Prevent generation of [[free radicals]]( Oxidative stress) or Increase the [[tissue's]] capacity to trap the [[free radicals]]  
* Prevent generation of [[free radicals]]( Oxidative stress) or Increase the [[Tissue (biology)|tissue's]] capacity to trap the [[free radicals]]
* Controlling the [[neutrophil]] activation and infiltration of [[ischemic tissue]]
* Controlling the [[neutrophil]] activation and [[Infiltration (medical)|infiltration]] of [[Ischemic|ischemic tissue]]
* [[Hypoxic]] [[preconditioning]]
* [[Hypoxic]] [[pre-conditioning]]
[[Hyperbaric oxygen]] therapy is also studied widely and best suited when used within 6 hrs of [[hypoxia]] as it helps in the reduction of local and [[systemic hypoxia]] and in turn increases the [[survival]] of affected [[tissue]].  
 
[[Hyperbaric oxygen]] therapy is also studied widely and best suited when used within 6 hrs of [[hypoxia]] as it helps in the reduction of local and [[Hypoxemia|systemic hypoxia]] and in turn increases the [[Survival rate|survival]] of affected [[tissue]].  


== Medical Therapy ==
== Medical Therapy ==
[[File:Reperfusion Injury Treatment .gif|thumb|429x429px|Reperfusion injury treatment ]]
Various proposed medical managements studied are:
Various proposed medical managements studied are:


*'''Therapeutic hypothermia'''
*'''Therapeutic hypothermia'''
** It has been shown in rats that [[Neuron|neurons]] sometimes die completely 24 hours after the [[blood flow]] returns. Some claim that this delayed reaction is the result of the multiple [[Inflammation|inflammatory]] [[immune responses]] that occur during [[reperfusion]].  
** It has been shown in rats that [[Neuron|neurons]] sometimes die completely 24 hours after the [[blood flow]] returns.
**This delayed reaction is the result of the multiple [[Inflammation|inflammatory]] [[immune responses]] that occur during [[reperfusion]].
**Such inflammatory reactions cause increase in[[Intracranial pressure|ntracranial pressure]], a pressure that leads to [[Cell disruption|cell damage]] and [[cell death]] in some cases.
**Such inflammatory reactions cause increase in[[Intracranial pressure|ntracranial pressure]], a pressure that leads to [[Cell disruption|cell damage]] and [[cell death]] in some cases.
**[[Hypothermia]] has been shown to help reduce [[intracranial pressure]] and thus decrease the adverse effects of inflammatory immune responses during [[reperfusion]]. Besides that, reperfusion also increases [[Free-radical theory|free radical]] development.  
**[[Hypothermia]] has been shown to help reduce [[intracranial pressure]] and thus decrease the adverse effects of inflammatory immune responses during [[reperfusion]].  
**[[Hypothermia]] has also been shown to decrease the patient's development of deadly [[free radicals]] during [[reperfusion]].  
**Besides that, reperfusion also increases [[Free-radical theory|free radical]] development. [[Hypothermia]] has also been shown to decrease the patient's development of deadly [[free radicals]] during [[reperfusion]].  


*'''Hydrogen sulfide treatment'''
*'''Hydrogen sulfide treatment'''
** There are several preliminary studies in mice that seem to show that treatment with [[hydrogen sulfide]] ( H2S) could have a protective effect against [[reperfusion injury]][[File: Myocardial Treatment In IRI.jpg|thumb|Treatment OF IRI]]
** There are several preliminary studies in mice that seem to show that treatment with [[hydrogen sulfide]] ( H2S) could have a protective effect against [[reperfusion injury]]


*'''Cyclosporine'''
*'''Cyclosporine'''
** In addition to its well-known [[Immunosuppression|immunosuppressive]] capabilities, the one-time administration of [[cyclosporine]] at the time of [[percutaneous coronary intervention]] (PCI) has been found to deliver a 40 percent reduction in [[infarct]] size in a small group proof of concept study of human patients with [[reperfusion injury]] published in The New England Journal of Medicine in 2008.
** In addition to its well-known [[Immunosuppression|immunosuppressive]] capabilities, the one-time administration of [[cyclosporine]] at the time of [[percutaneous coronary intervention]] (PCI) has been found to deliver a 40 percent reduction in [[infarct]] size in a small group proof of concept study of [[human]] patients with [[reperfusion injury]] published in The [[New England Journal of Medicine]] in 2008.
**[[Cyclosporine]] works by inhibiting the action of [[Cyclophilin D]] which usually helps in opening [[Mitochondrial membrane transport protein]] ( MPT Pore). So once [[cyclophilin D]] action is inhibited, there is no more MPT pore opening and in turn, saves the [[mitochondria]] from getting damaged.
**[[Cyclosporine]] works by inhibiting the action of [[Cyclophilin|Cyclophilin D]] which usually helps in opening [[Mitochondrial membrane transport protein]] ( MPT Pore). So once [[Cyclophilin|cyclophilin D]] action is inhibited, there is no more MPT pore opening and in turn, saves the [[mitochondria]] from getting damaged.
**The opening of MTP Pore results in major [[cell]] destruction by causing the influx of water into [[mitochondria]] and in turn impairing its function and ultimately leading to the collapse. The strategy to protect [[mitochondria]] is the most important thing associated with the treatment part.
**The opening of [[Mitochondrial membrane transport protein|MTP Pore]] results in major [[cell]] destruction by causing the influx of water into [[mitochondria]], impairing its function and ultimately leading to the [[collapse]]. The strategy to protect [[mitochondria]] is the most important thing associated with the [[Treatment|treatment part]].


*'''TRO40303'''
*'''TRO40303'''
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*'''Metformin'''
*'''Metformin'''
**Some studies proved the role of [[metformin]] in preventing [[Ischemia-Reperfusion]] injury by inhibiting the opening of [[MPT Pore]] and [[Mitochondrial]] complex inhibition. Although the studies are done in [[rats]] only still the correlation can be derived [[clinically]] for humans as well.
**Some studies proved the role of [[metformin]] in preventing [[Ischemia-reperfusion injury|Ischemia-Reperfusion injury]] by inhibiting the opening of [[MPT Pore]] and [[Mitochondrial]] complex inhibition. Although the studies are done in [[rats]] only still the correlation can be derived [[clinically]] for humans as well.


*'''Cannabinoids'''
*'''Cannabinoids'''
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==Therapies Associated with Improved Clinical Outcomes==
==Therapies Associated with Improved Clinical Outcomes==
[[File: Medical treatment in IRI.jpg|thumb|Medical treatment in IRI]]
[[File:Reperfusion injury management - Via pre-conditioning & Post-conditioning.jpg|thumb|400x400px|Pre-conditioning and Post-conditioning]]
Therapies that have been associated with improved clinical outcomes include:
Therapies that have been associated with improved clinical outcomes include:


#Post conditioning (short repeated periods of [[Blood vessel|vessel]] opening by repeatedly blowing the balloon up for short periods of time).
# "Pre conditioning" - Preconditioning is basically an adaptive response in which ischemia is exposed for a brief period of time before the actual ischemia phase to the tissue. This phenomenon markedly increase the ability of heart to withstand subsequent ischemic insults. In addition to that, application of brief episodes of ischemia at the onset of reperfusion is termed as "post conditioning" which reduces the extent of injury that is supposed to happen.
# "Post conditioning" (short repeated periods of [[Blood vessel|vessel]] opening by repeatedly blowing the balloon up for short periods of time).
#*Mechanisms of protection include formation and release of several [[autacoids]] and [[cytokines]], maintained [[acidosis]] during early repercussion, activation of [[Kinases|protein kinases]], and attenuation of the opening of the [[mitochondrial permeability transition pore]] (MPTP)
#*Mechanisms of protection include formation and release of several [[autacoids]] and [[cytokines]], maintained [[acidosis]] during early repercussion, activation of [[Kinases|protein kinases]], and attenuation of the opening of the [[mitochondrial permeability transition pore]] (MPTP)
#*One study in humans demonstrated an area under the curve (AUC) of [[creatine kinase]] (C) release over the first 3 days of [[reperfusion]] (as a [[Surrogacy|surrogate]] for infarct size) was significantly reduced by 36% in the post conditioned versus a control group
#*One study in humans demonstrated an area under the curve (AUC) of [[creatine kinase]] (C) release over the first 3 days of [[reperfusion]] (as a [[Surrogacy|surrogate]] for infarct size) was significantly reduced by 36% in the post conditioned versus a control group
#*[[Infarct]] size reduction by PCI postconditioning persisted 6 months after [[Acute myocardial infarction|AMI]] and resulted in a significant improvement in [[left ventricular]] (LV) function at 1 year
#*[[Infarct]] size reduction by PCI post conditioning persisted 6 months after [[Acute myocardial infarction|AMI]] and resulted in a significant improvement in [[left ventricular]] (LV) function at 1 year
#Inhibition of mitochondrial pore opening by [[cyclosporine]].  
#Inhibition of mitochondrial pore opening by [[cyclosporine]].  
#*Specifically, the study by Piot et al demonstrated that administration of [[cyclosporine]] at the time of reperfusion was associated with a reduction in infarct size
#*Specifically, the study by Piot et al demonstrated that administration of [[cyclosporine]] at the time of reperfusion was associated with a reduction in infarct size
#*[[Infarct]] size was measured by the release of [[creatine kinase]] and delayed hyperenhancement on MRI
#*[[Infarct]] size was measured by the release of [[creatine kinase]] and delayed hyper enhancement on MRI
#*Patients with [[cardiac arrest]], [[ventricular fibrillation]], [[cardiogenic shock]], [[stent thrombosis]], previous acute [[myocardial infarction]], or [[angina]] within 48 hours before infarction were not included in the study #*Occlusion of the culprit artery ([[TIMI|TIMI flow 0]]) was part of the inclusion criteria.
#*Patients with [[cardiac arrest]], [[ventricular fibrillation]], [[cardiogenic shock]], [[stent thrombosis]], previous acute [[myocardial infarction]], or [[angina]] within 48 hours before infarction were not included in the study #*Occlusion of the culprit artery ([[TIMI|TIMI flow 0]]) was part of the inclusion criteria.


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# GIK (glucose-insulin-potassium infusion) (Studied in the Glucose-Insulin-Potassium Infusion in Patients With Acute Myocardial Infarction Without Signs of Heart Failure: The Glucose-Insulin-Potassium Study (GIPS)-II  and other older studies
# GIK (glucose-insulin-potassium infusion) (Studied in the Glucose-Insulin-Potassium Infusion in Patients With Acute Myocardial Infarction Without Signs of Heart Failure: The Glucose-Insulin-Potassium Study (GIPS)-II  and other older studies
# Sodium-hydrogen exchange inhibitors such as cariporide (Studied in the GUARDIAN  and EXPEDITION  trials)
# Sodium-hydrogen exchange inhibitors such as cariporide (Studied in the GUARDIAN  and EXPEDITION  trials)
# [[Adenosine]] (Studied in the AMISTAD I  and AMISTAD II  trials as well as the ATTACC trial ). It should be noted that at high doses in anterior [[ST elevation myocardial infarction|ST elevation MI]]<nowiki/>s, adenosine was effective in the AMISTAD trial.  Likewise, intracoronary administration of adenosine prior to [[primary PCI]] has been associated with improved echocardiographic and clinical outcomes in one small study.
#<nowiki/>[[Adenosine]] (Studied in the AMISTAD I  and AMISTAD II  trials as well as the ATTACC trial ). It should be noted that at high doses in anterior [[ST elevation myocardial infarction|ST elevation MI]]<nowiki/>s, adenosine was effective in the AMISTAD trial.  Likewise, intracoronary administration of adenosine prior to [[primary PCI]] has been associated with improved echocardiographic and clinical outcomes in one small study.
# [[Calcium-channel blockers]]
#[[Calcium-channel blockers]]
# Potassium–adenosine triphosphate channel openers
# Potassium–adenosine triphosphate channel openers
#[[Antibodies]] directed against [[leukocyte]] adhesion molecules such as CD 18 (Studied in the LIMIT AMI trial )
#[[Antibodies]] directed against [[leukocyte]] adhesion molecules such as CD 18 (Stud<nowiki/>ied in the LIMIT AMI trial )
# Oxygen free radical scavengers/[[anti-oxidants]], including [[Erythropoietin]], [[estrogen]], heme-oxygenase 1, and [[hypoxia]] [[Hypoxia Induced factor-1|induced factor-1]] (HIF-1).
# Oxygen free radical scavengers/[[anti-oxidants]], including [[Erythropoietin]], [[estrogen]], heme-oxygenase 1, and [[hypoxia]] [[Hypoxia Induced factor-1|induced factor-1]] (HIF-1).
#[[Pexelizumab]], a humanized [[monoclonal antibody]] that binds the C5 component of complement (Studied in the [[Pexelizumab]] for [[ST elevation myocardial infarction|Acute ST-Elevation Myocardial Infarction]] in Patients Undergoing Primary [[Percutaneous Coronary Intervention]] (APEX AMI) trial  )
#[[Pexelizumab]], a humanized [[monoclonal antibody]] that binds the C5 component of complement (Studied in the [[Pexelizumab]] for [[ST elevation myocardial infarction|Acute ST-Elevation Myocardial Infarction]] in Patients Undergoing Primary [[Percutaneous Coronary Intervention]] (APEX AMI) trial  )

Revision as of 17:18, 22 August 2020

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1] Associate Editor(s)-in-Chief: Anjan K. Chakrabarti, M.D. [2] Shivam Singla, M.D.[3]

Overview

The most common myth about the ischemia-reperfusion injury is itself related to blood flow. One can easily think like if everything is happening due to ischemia and with the restoration of blood flow, the injury should heal. Here is the trick, reperfusion in turn further exacerbates the injury mainly due to the formation of free radicals. There are few approaches that are studied widely and do play a major role in controlling the injury related to ischemia-reperfusion injury

Hyperbaric oxygen therapy is also studied widely and best suited when used within 6 hrs of hypoxia as it helps in the reduction of local and systemic hypoxia and in turn increases the survival of affected tissue.

Medical Therapy

Reperfusion injury treatment

Various proposed medical managements studied are:

  • Hydrogen sulfide treatment

Therapies Associated with Improved Clinical Outcomes

Pre-conditioning and Post-conditioning

Therapies that have been associated with improved clinical outcomes include:

  1. "Pre conditioning" - Preconditioning is basically an adaptive response in which ischemia is exposed for a brief period of time before the actual ischemia phase to the tissue. This phenomenon markedly increase the ability of heart to withstand subsequent ischemic insults. In addition to that, application of brief episodes of ischemia at the onset of reperfusion is termed as "post conditioning" which reduces the extent of injury that is supposed to happen.
  2. "Post conditioning" (short repeated periods of vessel opening by repeatedly blowing the balloon up for short periods of time).
  3. Inhibition of mitochondrial pore opening by cyclosporine.

Limitations to applying strategies that have demonstrated benefit in animal models are the fact that reperfusion therapy was administered prior to or at the time of reperfusion. In the management of STEMI patients, it is impossible to administer the agent before vessel occlusion (except during coronary artery bypass grafting). Given the time constraints and the goal of opening an occluded artery within 90 minutes, it is also difficult to administer experimental agents before reperfusion in STEMI.

Therapies Associated with Limited Success

Pharmacotherapies that have either failed or that have met with limited success in improving clinical outcomes include:

  1. Beta-blockade
  2. GIK (glucose-insulin-potassium infusion) (Studied in the Glucose-Insulin-Potassium Infusion in Patients With Acute Myocardial Infarction Without Signs of Heart Failure: The Glucose-Insulin-Potassium Study (GIPS)-II and other older studies
  3. Sodium-hydrogen exchange inhibitors such as cariporide (Studied in the GUARDIAN and EXPEDITION trials)
  4. Adenosine (Studied in the AMISTAD I and AMISTAD II trials as well as the ATTACC trial ). It should be noted that at high doses in anterior ST elevation MIs, adenosine was effective in the AMISTAD trial. Likewise, intracoronary administration of adenosine prior to primary PCI has been associated with improved echocardiographic and clinical outcomes in one small study.
  5. Calcium-channel blockers
  6. Potassium–adenosine triphosphate channel openers
  7. Antibodies directed against leukocyte adhesion molecules such as CD 18 (Studied in the LIMIT AMI trial )
  8. Oxygen free radical scavengers/anti-oxidants, including Erythropoietin, estrogen, heme-oxygenase 1, and hypoxia induced factor-1 (HIF-1).
  9. Pexelizumab, a humanized monoclonal antibody that binds the C5 component of complement (Studied in the Pexelizumab for Acute ST-Elevation Myocardial Infarction in Patients Undergoing Primary Percutaneous Coronary Intervention (APEX AMI) trial )
  10. KAI-9803, a delta-protein kinase C inhibitor (Studied in the Intracoronary KAI-9803 as an adjunct to primary percutaneous coronary intervention for acute ST-segment elevation myocardial infarction trial or DELTA AMI trial).
  11. Human atrial natriuretic peptide (Studied in the Human atrial natriuretic peptide and nicorandil as adjuncts to reperfusion treatment for acute myocardial infarction (J-WIND): two randomized trials.)
  12. FX06, an anti-inflammatory fibrin derivative that competes with fibrin fragments for binding with the vascular endothelial molecule VE-cadherin which deters migration of leukocytes across the endothelial cell monolayer (studied in the F.I.R.E. trial (Efficacy of FX06 in the Prevention of Myocardial Reperfusion Injury)
  13. Magnesium, which was evaluated by the Fourth International Study of Infarct Survival (ISIS-4) and the MAGIC trial.
  14. Hyperoxemia, the delivery of supersaturated oxygen after PCI (Studied in the AMIHOT II trial).
  15. Bendavia studied in the EMBRACE STEMI trial

There are several explanations for why trials of experimental agents have failed in this area:

  1. The therapy was administered after reperfusion and after reperfusion injury had set in
  2. The greatest benefit is observed in anterior ST-elevation myocardial infarctions (as demonstrated in the AMISTAD study), and inclusion of non-anterior locations minimizes the potential benefit
  3. There are uninhibited redundant pathways mediating reperfusion injury
  4. Inadequate dosing of the agent

References