ROLE OF MAGNESIUM IN CRITICAL CARE Dr.May Mostafa Darwish Assistant lecturer of Anesthesia and ICU...
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Transcript of ROLE OF MAGNESIUM IN CRITICAL CARE Dr.May Mostafa Darwish Assistant lecturer of Anesthesia and ICU...
ROLE OF MAGNESIUM IN CRITICAL CARE
Dr.May Mostafa DarwishAssistant lecturer of Anesthesia and ICU
Ain Shams University
INTRODUCTION
Magnesium is essential for human life:
It plays a fundamental role in many cellular functions, such as storage, metabolism, and energy utilization.
Mg ions are involved as a cofactor in :
many enzymatic reactions
hormone receptor binding
protein synthesis
neuromuscular function
and nucleic acid stability
4th most common mineral
salt (P/Ca/K/Mg.)
2nd intracellular cation
after potassium
4th plasma cation
(Na/K/Ca/Mg…)
53% in bone, 27% in muscle,
19% in soft tissues, 0.5% in
erythrocytes, 0.3% in serum
In serum:
Ionized (active form): 60%
Protein-bound: 33%
In anion complexes (phosphates and
citrates): 7%
ionized
protein bound
anion complexes
Normal plasma Mg 2+ concentration : 1.7 to 2.4 mEq/L (0.70 to 1.0 mmol/L)
Daily recommended requirement:
250-350 mg (10.4–14.6 mmol) in adults
Cocoa powder, chocolate, nuts, leafy green vegetables, cereals, seafood are rich sources for Mg2+
The maintenance of plasma Magnesium concentration through:
• dietary intake .
• effective renal and intestinal conservation.
Renal excretion is the primary route of elimination
• 25% is reabsorbed in the PCT.
• 50-60% is reabsorbed in the thick ascending limb of the loop of Henle.
Mg absorption and cellular uptake:
PTH : intestinal absorption↑
Vitamin D: intestinal absorption↑
Insulin: cellular uptake↑
Glucagon: renal reabsorption ↑
Actions of Magnesium
1. Endogenous calcium antagonist by affecting its uptake and distribution.
2. Modulator of Na+ and K+ currents, thus influencing membrane potential.
3. Depressant effects in CNS :
antagonist of the (NMDA) receptor
inhibitor of catecholamine release.
What is the role
of magnesi
um in ICU??
Magnesium and Cardioprotectio
n
I. Acute myocardial infarction.
Coronary and systemic VD :
improve metabolism of cardiomyocytes
attenuate ischemia–reperfusion injury of myocardial tissue.
Decreases myocardial membrane excitability:
Na+/K+ ATPase and Ca2+ ATPase are important regulators of myocardial membrane stability.
Attenuates the incidence of infarction-related arrythmias:
prolongs the ARP and shortens the RRP
II. Cardiac Arrythmias :
slows electrical activity of the SAN.
prolongs AV conductance.
increases the refractory period of the AVN.
Types :
1. AF and ventricular arrhythmias after cardiac and thoracic surgery
2. digoxin induced supraventricular and ventricular arrhythmias
3. multifocal atrial tachycardia
4. polymorphic ventricular tachycardia (Torsade de points)
5. VF from drug overdoses.
III. Pulmonary Hypertension: PH is defined as a mean PA
pressure greater than 25 mmHg at rest and > 30 mmHg during exercise.
Magnesium is a potent vasodilator and hence has the potential to reduce the high pulmonary arterial pressures associated with persistent pulmonary hypertension (PPHN)
Magnesium and Preeclampsia
Eclampsia and Preeclampsia
Systemic, cerebral, and uterine vasodilation by:
1)Increase concentrations of the two endogenous potent vasodilators
endothelium-derived relaxing factor and
calcitonin gene-related peptide
2) It attenuates the circulating concentrations of endothelin-1 (an endogenous vasoconstrictor)
Dose : loading 4–6 g /20–30 min & maintenance of 1–2 g/h.
The infusion should be continued for at least 24 h after delivery.
To avoid serious adverse effects, respiration, the presence of tendon reflexes, and urine output should be closely monitored.
antenatal administration may be considered because of its neuroprotective effects in preterm neonates.
Magnesium and Asthma
MgSO4 has been administered to patients to treat acute severe asthma when conventional therapy with oxygen, corticosteroids and continuous aerosol beta agonists fail to provide adequate relief
Magnesium-induced bronchodilation may be mediated by several pathways:
1. attenuation of calcium-induced muscle contractions
2. inhibition of cholinergic neuromuscular transmission
3. antiinflammatory activity
4. potentiation of β-agonists on adenylyl cyclase
5. reversal of magnesium depletion after β-adrenergic treatment
IV MgSO4 provides additional benefit in moderate to severe acute asthma in patients treated with bronchodilators and steroids.
Nebulised inhaled MgSO4 in addition to beta2- agonist used in ttt of acute asthma exacerbation improves pulmonary function.
Mg also possesses mild sedative effects valuable to achieving anxiolysis and relaxation in acute bronchospasm.
Magnesium and Neuroprotectio
n
Mg was shown to protect neurons and glia cells by:
1) inhibiting ischemia-induced glutamate release
2) inhibiting calcium-dependent enzymes
Therefore Mg exertes antiexcitotoxic properties and preventes cellular apoptosis.
I. Stroke: The most promising time frame to facilitate
maximal Neuroprotection is assumed to cover the first 3 h after onset of ischemia.
II. Subarachnoid Hemorrhage: Delayed cerebral ischemia is one of the main
causes of death and disability after SAH and usually occurs 4–10 days after the initial bleeding event.
IV MgSO4 as an adjuvant to nimodipine may reduce delayed cerebral ischemia by 34%
III. Carotid Surgery: Patients undergoing
carotid endarterectomy are at particular risk for postoperative cognitive deficits caused by cortical ischemia after intraoperative hypotension or embolic events.
Mg is known to improve neurocognitive function on 1st postoperative day
IV. Spinal Cord Injury: Once 1ry injury to the
spinal cord has occurred, reduction of 2ry injury and ongoing ischemia by stabilizing hemodynamics and spinal perfusion pressure is most important.
Mg has proven its neuroprotective potential in spinal cord injury.
Magnesium and Pheochromocytoma
Pheochromocytoma is a CA producing and secreting neoplasm arising 1ry from the adrenal medulla.
Surgical removal of Pheochromocytoma possesses significant challenge dt the hemodynamic disturbances occurring when a tumor is manipulated and finally resected.
Standard preoperative treatment includes pharmacologic stabilization by and β adrenergic antagonists.
Magnesium may stabilize hemodynamics :
1. inhibition of CA release from the adrenal medulla and peripheral adrenergic nerve endings.
2. direct blockade of CA receptors.
3. antiarrhythmic properties related to calcium channel antagonism.
An initial bolus dose of 40-60mg/kg IV followed by 2g/hr has been a suggested regimen
Pheochromocytoma Crisis
Mg was shown to improve severe hypertension and hypertensive encephalopathy in patients with pheochromocytoma crisis.
Based on arteriolar -dilating properties, its use might be advantageous to that of sodium nitroprusside, which dilates both arterioles and venules and may thus worsen hemodynamics, especially in hypovolemic patients.
Because Mg was shown to inhibit CA receptors, it may be superior to other competitive adrenergic antagonists, such as phentolamine because excessive CA concentrations may be present.
Magnesium and Tetanus
Mg reduces spasms and autonomic instability in tetanus.
A proposed regimen for management oftetanus is 5g MgSO4 IV over 20mins followed by 2g/hour IV infusion.
This can be increased by 0.5g/hour until there is relief of spasms or loss of patellar reflexes.
Magnesium and Analgesia
Several studies report antinociceptive effects of Mg when administered IV or intrathecally.
Suggested mechanisms include the inhibition of calcium influx (CCB augment morphine-induced analgesia and decrease total opioid consumption ) and antagonism of NMDA receptors
In addition, Mg seems to attenuate or even prevent central sensitization after peripheral tissue injury or inflammation because of inhibition of dorsal horn NMDA receptors.
Magnesium and
Shivering
Hypothermia may be an effective ttt for stroke or acute MI ; however, it provokes vigorous shivering, which causes potentially dangerous hemodynamic responses and prevents further hypothermia.
Mg is an attractive anti-shivering agent because it reduces the threshold (triggering core temperature) and gain of shivering without substantial sedation or muscle weakness.
Magnesium and Laryngoscopic
Intubation
Response
The role of Mg in blunting the intubation response is evolving:
It has direct VD properties on coronary arteries and inhibiting CA release, thus attenuating the hemodynamic effects during endotracheal intubation.
Beside its role in blunting the pressor response to intubation , it also produces less ST changes in coronary artery disease pts.
It was also concluded that pretreatment with different doses of Mg is more effective than pretreatment with Lidocaine.
Magnesium and Insulin Resistance
Clinical situations in which glycemia remains elevated despite increased insulin doses are frequent in ICU.
Mg regulates cellular glucose metabolism directly because it serves as an important cofactor for various enzymes and acts as a 2nd messenger for insulin.
Furthermore, hypomagnesaemia may induce :
1. altered cellular glucose transport
2. reduced pancreatic insulin secretion
3. defective post-receptor insulin signalling
4. altered insulin– insulin receptor interactions and thus aggravate insulin resistance
In a Nutshell
Mg is a cost effective, widely used drug with multidisciplinary applications.
Majority of its physiological effects are attributed to its calcium channel blocking properties.
It is used as :
1. Vasdilator (antihypertensive)
2. Bronchodilator
3. Antiarrythmic
4. Antiseizures
5. Analgesic