Difference between revisions of "Myasthenia gravis"
Chris Rishel (talk | contribs) m |
m (The bullet points said patients are sensitive to succinylcholine. I changed it to say that they are resistant. I added that the ED95 of succinylcholine is 2.6 times normal (from Barash), not sure if thats really needed to be on there.) |
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🠕 sensitivity to nondepolarizing NMBs | 🠕 sensitivity to nondepolarizing NMBs | ||
🠗 | 🠗 resistant to succinylcholine | ||
Monitor for cholinergic symptoms | Monitor for cholinergic symptoms | ||
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}}'''Myasthenia gravis''' is an autoimmune disease that produces antibodies against nicotinic acetylcholine receptors in the postsynaptic membrane of the neuromuscular junction, leading to varying degrees of muscle weakness and fatigue and can affect ocular, bulbar (muscles involved in speech, chewing and swallowing), respiratory, and proximal skeletal muscles. Symptoms are worst at the end of the day or after exertion. Classification of myasthenia depends on whether the patient has only ocular or ocular and extraocular weakness. | }}'''Myasthenia gravis''' is an autoimmune disease that produces antibodies against nicotinic acetylcholine receptors in the postsynaptic membrane of the neuromuscular junction, leading to varying degrees of muscle weakness and fatigue and can affect ocular, bulbar (muscles involved in speech, chewing and swallowing), respiratory, and proximal skeletal muscles. Symptoms are worst at the end of the day or after exertion. Classification of myasthenia depends on whether the patient has only ocular or ocular and extraocular weakness. | ||
==Anesthetic implications<!-- Briefly summarize the anesthetic implications of this comorbidity. --> == | ==Anesthetic implications<!-- Briefly summarize the anesthetic implications of this comorbidity. -->== | ||
===Preoperative optimization<!-- Describe how this comorbidity may influence preoperative evaluation and optimization of patients. -->=== | ===Preoperative optimization<!-- Describe how this comorbidity may influence preoperative evaluation and optimization of patients. -->=== | ||
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**Possibility of disrupting bowel anastomoses secondary to hyperperistalsis | **Possibility of disrupting bowel anastomoses secondary to hyperperistalsis | ||
**Cholinergic side effects including salivation, miosis, bradycardia | **Cholinergic side effects including salivation, miosis, bradycardia | ||
* IV pyridostigmine is 1/30 of the PO dose | *IV pyridostigmine is 1/30 of the PO dose | ||
====Labs and studies==== | ====Labs and studies==== | ||
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**If thymoma present, may be useful to characterize obstruction | **If thymoma present, may be useful to characterize obstruction | ||
====Premedication ==== | ====Premedication==== | ||
*Consider pretreatment with metoclopramide or H2 blocker for aspiration prophylaxis | *Consider pretreatment with metoclopramide or H2 blocker for aspiration prophylaxis | ||
**Patients with involvement of respiratory or bulbar muscles are at higher risk for aspiration | **Patients with involvement of respiratory or bulbar muscles are at higher risk for aspiration | ||
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*IVIG or plasma exchange can be used to improve symptoms of active flare for emergent cases | *IVIG or plasma exchange can be used to improve symptoms of active flare for emergent cases | ||
==== Associated comorbidities==== | ====Associated comorbidities==== | ||
*Thymoma | *Thymoma | ||
* Diabetes mellitus | *Diabetes mellitus | ||
*Thyroid disorders | *Thyroid disorders | ||
*Systemic lupus erythematosus | *Systemic lupus erythematosus | ||
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====Neuromuscular blockade==== | ====Neuromuscular blockade==== | ||
Patients with myasthenia gravis are: | Patients with myasthenia gravis are: | ||
* More sensitive to nondepolarizing neuromuscular blockers | *More sensitive to nondepolarizing neuromuscular blockers | ||
*Resistant to succinylcholine | *Resistant to succinylcholine | ||
** At increased risk for developing phase II neuromuscular block, particularly with repeat doses of succinylcholine | **At increased risk for developing phase II neuromuscular block, particularly with repeat doses of succinylcholine | ||
**ED95 is 2.6 times normal in these patients.<ref>{{Cite book|last=Barash|first=Paul|title=Clinical Anesthesia|publisher=Wolters Kluwer|year=2017|isbn=978-1-4963-3700-9|location=Philadelphia, PA|pages=1067}}</ref> | |||
*In patients taking an acetylcholinesterase inhibitor for myasthenia management, cholinergic crisis is possible if acetylcholinesterase inhibitor is used for neuromuscular blockade reversal | *In patients taking an acetylcholinesterase inhibitor for myasthenia management, cholinergic crisis is possible if acetylcholinesterase inhibitor is used for neuromuscular blockade reversal | ||
==== Airway management ==== | ====Airway management==== | ||
* Consider increased aspiration risk if bulbar symptoms are present | *Consider increased aspiration risk if bulbar symptoms are present | ||
* If thymoma present, may cause anterior mediastinal mass effect | *If thymoma present, may cause anterior mediastinal mass effect | ||
====Other medications==== | ====Other medications==== |
Latest revision as of 03:57, 17 July 2022
Other names | Myasthenia |
---|---|
Anesthetic relevance |
Critical |
Anesthetic management |
Evaluate for acute exacerbation Continue outpatient MG meds 🠕 sensitivity to nondepolarizing NMBs 🠗 resistant to succinylcholine Monitor for cholinergic symptoms May require prolonged ventilatory support |
Specialty |
Neurology, immunology |
Signs and symptoms |
Muscle weakness |
Diagnosis |
Serum antibody level, EMG, nerve conduction studies |
Treatment |
Acetylcholinesterase inhibitor, steroids |
Article quality | |
Editor rating | |
User likes | 0 |
Myasthenia gravis is an autoimmune disease that produces antibodies against nicotinic acetylcholine receptors in the postsynaptic membrane of the neuromuscular junction, leading to varying degrees of muscle weakness and fatigue and can affect ocular, bulbar (muscles involved in speech, chewing and swallowing), respiratory, and proximal skeletal muscles. Symptoms are worst at the end of the day or after exertion. Classification of myasthenia depends on whether the patient has only ocular or ocular and extraocular weakness.
Anesthetic implications
Preoperative optimization
Elective surgery should be delayed for patients who are exhibiting acutely worsened symptoms (i.e. myasthenic crisis)
Outpatient medications
Patients should take their morning dose of acetylcholinesterase inhibitor and/or steroids.
- Steroid use may indicate more severe disease and/or active symptoms
- Acetylcholinesterase inhibitor use may result in:
- Altered patient drug requirements following surgery
- Increased vagal reflexes
- Possibility of disrupting bowel anastomoses secondary to hyperperistalsis
- Cholinergic side effects including salivation, miosis, bradycardia
- IV pyridostigmine is 1/30 of the PO dose
Labs and studies
- PFTs may be helpful to establish baseline respiratory function
- If thymoma present, may be useful to characterize obstruction
Premedication
- Consider pretreatment with metoclopramide or H2 blocker for aspiration prophylaxis
- Patients with involvement of respiratory or bulbar muscles are at higher risk for aspiration
- Use sedating premedication with caution as patients may be more sensitive to respiratory depressants
- IVIG or plasma exchange can be used to improve symptoms of active flare for emergent cases
Associated comorbidities
- Thymoma
- Diabetes mellitus
- Thyroid disorders
- Systemic lupus erythematosus
- Rheumatoid arthritis
Intraoperative management
Neuromuscular blockade
Patients with myasthenia gravis are:
- More sensitive to nondepolarizing neuromuscular blockers
- Resistant to succinylcholine
- At increased risk for developing phase II neuromuscular block, particularly with repeat doses of succinylcholine
- ED95 is 2.6 times normal in these patients.[1]
- In patients taking an acetylcholinesterase inhibitor for myasthenia management, cholinergic crisis is possible if acetylcholinesterase inhibitor is used for neuromuscular blockade reversal
Airway management
- Consider increased aspiration risk if bulbar symptoms are present
- If thymoma present, may cause anterior mediastinal mass effect
Other medications
- Consider stress dose steroids if taking chronically
- Medications which may contribute to muscle weakness:
- Calcium channel blockers
- Magnesium
- Aminoglycoside antibiotics
Postoperative management
- Extubate awake with pulmonary mechanics similar to baseline status
- Risk factors for requiring postoperative ventilation support:
- Leventhal Criteria
- Disease duration >6yrs
- Concomitant pulmonary disease
- Peak inspiratory pressure <-25 cmH2O
- Vital capacity <40 mL/kg (or <2.9L)
- Pyridostigmine dose >750 mg/day
- Other indicators include preoperative use of steroids, and previous episode of respiratory failure
- Leventhal Criteria
- Resume outpatient anticholinesterase medication
- Patients should be monitored in either a ICU or step-down unit
Related surgical procedures
Pathophysiology
Myasthenia gravis is an autoimmune disease leading to the production of antibodies against nicotinic acetylcholine receptors in the postsynaptic membrane of the neuromuscular junction.
Signs and symptoms
Weakness in one or more of the following muscle groups:
- Ocular
- Bulbar (swallowing, chewing, speech)
- Respiratory
- Proximal skeletal
Diagnosis
Myasthenia gravis can be difficult to diagnose, and is based on a combination of:
- Serum antibody level
- Electromyography
- Nerve conduction studies
- Edrophonium test
- CT/MRI to evaluate for enlarged thymus gland
Not to be confused with Congenital myasthenic syndrome (CMS) or Lambert-Eaton syndrome.
Treatment
Myasthenia gravis is typically medically managed using:
- Acetylcholinesterase inhibitor (e.g. pyridostigmine) to increase the presence of acetylcholine in the neuromuscular junction
- Steroids
Prognosis
Patients with managed myasthenia gravis have a normal life expectancy.
Epidemiology
References
- ↑ Barash, Paul (2017). Clinical Anesthesia. Philadelphia, PA: Wolters Kluwer. p. 1067. ISBN 978-1-4963-3700-9.
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