Myasthenia Gravis

views updated May 09 2018

Myasthenia gravis

Definition

Myasthenia gravis (MG) is a chronic autoimmune disease characterized by fatigue and muscular weakness, especially in the face and neck, that results from a breakdown in the normal communication between nerves and muscles caused by the deficiency of acetylcholine at the neuromuscular (nerve-muscle) junctions. MG is the most common primary disorder of neuromuscular transmission.

Description

MG is a chronic autoimmune neuromuscular disease characterized by varying degrees of weakness of the skeletal (voluntary) muscles of the body. The hallmark of this disease is muscle weakness that increases during periods of activity and improves after periods of rest. Muscles that control eye and eyelid movements, facial expression, chewing, talking, and swallowing are often, but not always, involved. The muscles that control breathing and neck and limb movements may also be affected.

Myasthenia gravis can be classified according to which skeletal muscles are affected. Within a year of onset, approximately 8590% of affected persons develop generalized MG, which is characterized by weakness in the trunk, arms, and legs. About 1015% of patients have weakness only in muscles that control eye movement. This type is called ocular myasthenia gravis.

Other types of MG include congenital MG, an inherited condition caused by a genetic defect, and transient neonatal, which occurs in infants born from mothers who have MG. Congenital MG develops at or shortly after birth and causes generalized symptoms.

Demographics

Myasthenia gravis occurs in all ethnic groups and both genders. The prevalence of MG in the United States is estimated to be 14 per 100,000 population, which equals approximately 36,000 cases in the United States. However, this disease is probably under diagnosed and the prevalence may be higher. Previous studies showed that women are more often affected than men. The most common age at onset is the second and third decades in women

and the seventh and eighth decades in men. As the population ages, the average age of onset has increased correspondingly, and now males are considered to be more often affected than females, and the onset of symptoms is usually after age 50.

Causes and symptoms

Myasthenia gravis is an autoimmune disease caused by abnormal antibodies carried in the blood stream. Nerves release a chemical called acetylcholine (ACh) that activates receptors on muscles to trigger contraction. The normal neuromuscular junction releases ACh from the motor nerve terminal in discrete packages (quanta). The ACh quanta diffuse across the synaptic cleft and bind to receptors on the folded muscle end-plate membrane. Stimulation of the motor nerve releases many ACh quanta that depolarize the muscle end-plate region and then the muscle membrane, causing muscle contraction.

The myasthenia antibodies interfere with this process by binding to specific sites on the surface of the muscles, the post-synaptic muscle membrane is distorted and simplified, having lost its normal folded shape. The most common antibodies are directed against the muscle acetylcholine receptor (AChR). ACh is released normally, but its effect on the post-synaptic membrane is reduced. The post-junctional membrane is less sensitive to applied ACh, and the probability that any nerve impulse will cause a muscle action potential is reduced.

Ten percent of patients with MG have a tumor in the thymus, (a thymoma) that is usually benign, and 70% have changes (germinal centers) that indicate an active immune response. These are areas within lymphoid tissue where B-cells interact with helper T-cells to produce antibodies. Because the thymus is the central organ for immunological self-tolerance, it is reasonable to suspect that thymic abnormalities cause the breakdown in tolerance that leads to an immune-mediated attack on AChR in this disease. The thymus contains all the necessary elements for the beginnings of MG: myoid cells that express the AChR antigen, antigen presenting cells, and immunocompetent T-cells. However, it is still uncertain whether the role of the thymus in the pathogenesis of disease is primary or secondary.

There are very rare genetic abnormalities that cause problems similar to myasthenia gravis. These diseases are called congenital or inherited myasthenias and usually are present in infants. MG is not directly inherited, nor is it contagious. Occasionally, the disease may occur in more than one member of the same family. Rarely, children may show signs of congenital (present at birth) myasthenia or congenital myasthenic syndrome. These are not autoimmune disorders, but are caused by defective genes that control proteins in the acetylcholine receptor or in acetyl-cholinesterase. In neonatal myasthenia that develops in 1020% of infants born to mothers who have MG, the fetus may acquire immune proteins (antibodies) from a mother affected with MG. Generally, cases of neonatal myasthenia are transient and the child's symptoms usually disappear within few weeks after birth.

Although MG may affect any voluntary muscle, muscles that control eye and eyelid movement, facial expression, and swallowing are most frequently affected. The onset of the disorder may be sudden. Symptoms often are not immediately recognized as myasthenia gravis. In most cases, the first noticeable symptom is weakness of the eye muscles. In others, difficulty in swallowing and slurred speech may be the first signs. The degree of muscle weakness involved in this disease varies greatly among patients, ranging from a localized form, limited to eye muscles (ocular myasthenia), to a severe or generalized form in which many muscles, sometimes including those that control breathing, are affected. Symptoms, which vary in type and severity, may include a drooping of one or both eyelids (ptosis), blurred or double vision (diplopia) due to weakness of the muscles that control eye movements, unstable or waddling gait, weakness in arms, hands, fingers, legs, and neck, a change in facial expression, difficulty in swallowing and shortness of breath, and impaired speech (dysarthria ).

Diagnosis

A delay in diagnosis of one or two years is not unusual in cases of MG. Because weakness is a common symptom of many other disorders, the diagnosis is often missed in people who experience mild weakness or in those individuals whose weakness is restricted to only a few muscles. The first steps of diagnosing MG include a review of the individual's medical history, and physical and neurological examinations. The signs a physician must look for are impairment of eye movements or muscle weakness without any changes in the individual's ability to feel things. If the physician suspects MG, several tests are available to confirm the diagnosis.

The Edrophonium Chloride (Tensilon) Test

This approach requires the intravenous administration of edrophonium chloride or Tensilon(r), a drug that temporarily increases the levels of acetylcholine at the neuromuscular junction. In people with myasthenia gravis involving the eye muscles, the drug will chloride will briefly relieve weakness.

Antibodies Against Acetylcholine Receptor (AChR)

In general, an elevated concentration of AChR binding antibodies in a patient with compatible clinical features confirms the diagnosis of MG, but normal antibody concentrations do not exclude the diagnosis.

Repetitive Nerve Stimulation (RNS)

This test records weakening muscle responses when the nerves are repetitively stimulated, and helps to differentiate nerve disorders from muscle disorders. Repetitive stimulation of a nerve during a nerve conduction study may demonstrate faults of the muscle action potential (CMAP) due to impaired nerve-to-muscle transmission. A significant decrement to RNS in either a hand or shoulder muscle is found in about 60% of patients with MG.

Single fiber electromyogram (SFEMG)

SFEMG is the most sensitive clinical test of neuromuscular transmission and shows increased jitter in some muscles in almost all patients with myasthenia gravis. Jitter is greatest in weak muscles, but may be abnormal even in muscles with normal strength. Patients with mild or purely ocular (eye) muscle weakness may have increased jitter only in facial muscles. Increased jitter is a nonspecific sign of abnormal neuromuscular transmission and can also be seen in other motor diseases.

Computed tomography (CT) or magnetic resonance imaging (MRI)

Computed tomography (CT ) or magnetic resonance imaging (MRI) may be used to identify an abnormal thymus gland or the presence of a thymoma. Pulmonary function testing, which measures breathing strength, helps to predict whether respiration may fail and lead to a myasthenic crisis.

Treatment team

The treatment team is normally composed of a neurologist , a nutritionist (dietary advice), a speech pathologist, a pulmonologist, a geneticist, a neurologist, a dentist, a otolaryngologist, a physical therapist, and nurses.

Treatment

Treatment regimens for myasthenia gravis are practical rather than curative. Treatment decisions are based on knowledge of the natural history of disease in each patient and the predicted response to a specific form of therapy. Treatment goals must be individualized according to the severity of disease, the patient's age and sex, and the degree of functional impairment. The response to any form of treatment is difficult to assess because the severity of symptoms fluctuates. Spontaneous improvement, even remissions, occur without specific therapy, especially during the early stages of the disease.

Cholinesterase inhibitors

Cholinesterase inhibitors result in increased ACh accumulation at the neuromuscular junction and prolongs its effect. These drugs cause considerable improvement in some patients and little to none in others. Pyridostigmine bromide (Mestinon) and neostigmine bromide (Prostigmin) are the most commonly prescribed cholinesterase inhibitors. No fixed dosage schedule suits all patients. The need for cholinesterase inhibitors varies from day to day and during the same day in response to infection, menstruation, emotional stress, and hot weather. Different muscles respond differently; with any dose, certain muscles become stronger, others do not change, and still others become weaker. Adverse effects of cholinesterase inhibitors include gastrointestinal complaints: queasiness, loose stools, nausea, vomiting, abdominal cramps, and diarrhea.

Thymectomy

Thymectomy (removal of the thymus) is recommended for most people with myasthenia gravis. The greatest benefit from the surgery generally occurs two to five years afterwards. However, the response is relatively unpredictable and significant impairment may continue for months or years after surgery. The best responses to thymectomy are in young people early in the course of the disease, but improvement can occur even after 30 years of symptoms. Persons with disease onset after the age of 60 rarely show substantial improvement from thymectomy. Patients with thymomas (tumor on the thymus) do not respond as well to thymectomy as do patients without them.

Corticosteroids

Marked improvement or complete relief of symptoms occurs in more than 75% of people treated with prednisone, and some improvement occurs in most of the rest. Much of the improvement occurs in the first six to eight weeks of therapy, but strength may increase to total remission in the months that follow. The best responses occur in patients with recent onset of symptoms, but patients with chronic disease may also respond. The severity of disease does not predict the ultimate improvement. Patients with thymoma have an excellent response to prednisone before or after removal of the tumor. About one-third of patients become weaker temporarily after starting prednisone, usually within the first seven to ten days, but this temporary weakness lasts for only a few days. The major disadvantages of chronic corticosteroid therapy are the side effects, such as weight gain and fluid retention.

Immunosuppressant drugs

Azathioprine reverses symptoms in most patients with myasthenia gravis, but the benefits are delayed by four to eight months. Once improvement begins, it is maintained for as long as the drug is given. Symptoms recur two to three months after the drug is discontinued or the dose is reduced below therapeutic levels. Patients who experience no improvement on corticosteroids may respond to azathioprine, and the reverse is also true. Sometimes, people with MG respond better to treatment with both drugs than to either one alone. Because the response to azathioprine is delayed, both drugs may be started simultaneously with the intent of rapidly tapering prednisone when azathioprine becomes effective. Approximately one-third of patients have mild dose-dependent side effects that may require dose reductions, but do not require stopping treatment.

Cyclosporine is sometimes beneficial in treating MG. Most patients with myasthenia gravis improve within two months after starting cyclosporine and improvement is maintained as long as therapeutic doses are given. Maximum improvement is achieved six months or longer after starting treatment. After achieving the maximal response, the dose is gradually reduced to the minimum that maintains improvement. Toxicity to the kidneys and hypertension are important adverse reactions of cyclosporine. Many drugs interfere with cyclosporine metabolism and should be avoided or used with caution.

Cyclophosphamide is also given intravenously and orally for the treatment of myasthenia gravis. More than half of patients receiving cyclophosphamide experience a dramatic improvement in their symptoms after one year; however, side effects are common. Life-threatening infections are an important risk for all persons taking immunosuppressant drugs.

Plasma exchange

Plasma exchange is used as a short-term intervention for patients with sudden worsening of myasthenic symptoms, to rapidly improve strength before surgery, and as a chronic intermittent treatment for patients who are refractory to all other treatments. The need for plasma exchange and its frequency of use is determined by the clinical response in the individual patient. Almost all patients with acquired MG improve temporarily following plasma exchange. Maximum improvement may be reached as early as after the first exchange or as late as the fourteenth. Improvement lasts for weeks or months and then the effect is lost unless the exchange is followed by thymectomy or immunosuppressive therapy. Most patients who respond to the first plasma exchange will respond again to subsequent courses. Repeated exchanges do not have a cumulative benefit.

Intravenous immune globulin (IVIG)

Immune globulin given intravenously results in improvement in more than half of MG patients, usually beginning within one week of therapy and lasting for several weeks or months.

Recovery and rehabilitation

Physical and occupational therapists provide strategies to help people with myasthenia gravis maintain daily activities during almost all phases of the disease. As the progression of symptoms occurs over months or years, these strategies adapt to the changing needs of the person with myasthenia gravis. For example, wheelchairs, specialized eating utensils, and positioning aids might be required during the progressive phase. When improvement is made, shower stools, rolling carts for carrying shopping items, and exercises to promote maintenance of posture can all help avoid fatigue. While the symptoms of the disease may go into remission, recovery is not said to be complete, as symptoms may recur. The longer the person remains in remission; however, the greater is the chance that the disease will not recur

Clinical trials

As of February 2004, there were two open clinical trials for MG, both sponsored by the Rush University Medical Center in Chicago, Illinois:

  • Study of CellCept in the Treatment of MG: This is a multicenter, placebo-controlled study testing CellCept and prednisone as the initial form of immunotherapy in the treatment of MG. The purpose of the study is to determine if the combination of these two medications provides better control of MG symptoms compared with prednisone alone.
  • Study of Etanercept Among Individuals With MG: The purpose of the study is to determine if Etanercept improves muscle strength in patients with MG.

Up-to-date information on clinical trials can be found at the United States government website for clinical trials located at <www.clinicaltrials.org>.

Prognosis

Symptoms of myasthenia gravis usually progress to maximum severity within three years. After that time, persons with MG normally stabilize or improve. With treatment, the outlook for most patients with MG is bright: they will have significant improvement of their muscle weakness and they can expect to lead normal or nearly normal lives.

Many people's MG symptoms may go into remission temporarily and muscle weakness may disappear completely, so that medications can be discontinued. Stable, long-lasting complete remissions are the goal of thymus removal (thymectomy). In a few cases, the severe weakness of MG may cause a crisis (respiratory failure), which requires immediate emergency medical care. Advances in medical care have reduced the mortality rate from respiratory failure in myasthenia gravis patients to approximately three percent. Patients over the age of 40, those with a short history of severe disease, and those with thymoma tend to have less significant improvement.

Special concerns

Myasthenia gravis cannot be prevented, but avoiding the following triggers may help patients prevent exacerbations (worsening of symptoms):

  • emotional stress
  • exposure to extreme temperatures
  • fever
  • illness (e.g., respiratory infection, pneumonia, tooth abscess)
  • low levels of potassium in the blood (hypokalemia; caused by diuretics, frequent vomiting)
  • some medications, such as muscle relaxants, anticonvulsants , and certain antibiotics

Resources

BOOKS

Henderson, Ronald E. Attacking Myasthenia Gravis. Seattle: Court Street Press, 2002.

Icon Health Publications. The Official Patient's Sourcebook on Myasthenia Gravis: A Revised and Updated Directory for the Internet Age. San Diego: Icon Grp. Int., 2002.

OTHER

National Institute of Neurological Disorders and Stroke. "Myasthenia Gravis Fact Sheet." <http://www.ninds.nih.gov/health_and_medical/pubs/myasthenia_gravis.htm> (February 11, 2004).

ORGANIZATIONS

Myasthenia Gravis Foundation of America, Inc. 1821 University Ave. W., Ste. S256, St. Paul, MN 55104-2897. (651) 917-6256 or (800) 541-5454; (651) 917-1835. [email protected]. <http://www.myasthenia.org>.

Beatriz Alves Vianna

Iuri Drumond Louro

Myasthenia Gravis

views updated May 29 2018

Myasthenia Gravis

Definition

Myasthenia gravis is an autoimmune disease that causes muscle weakness.

Description

Myasthenia gravis (MG) affects the neuromuscular junction, interrupting the communication between nerve and muscle, and thereby causing weakness. A person with MG may have difficulty moving their eyes, walking, speaking clearly, swallowing, and even breathing, depending on the severity and distribution of weakness. Increased weakness with exertion, and improvement with rest, is a characteristic feature of MG.

About 30,000 people in the United States are affected by MG. It can occur at any age, but is most common in women who are in their late teens and early twenties, and in men in their sixties and seventies.

Causes and symptoms

Myasthenia gravis is an autoimmune disease, meaning it is caused by the body's own immune system. In MG, the immune system attacks a receptor on the surface of muscle cells. This prevents the muscle from receiving the nerve impulses that normally make it respond. MG affects "voluntary" muscles, which are those muscles under conscious control responsible for movement. It does not affect heart muscle or the "smooth" muscle found in the digestive system and other internal organs.

A muscle is stimulated to contract when the nerve cell controlling it releases acetylcholine molecules onto its surface. The acetylcholine lands on a muscle protein called the acetylcholine receptor. This leads to rapid chemical changes in the muscle which cause it to contract. Acetylcholine is then broken down by acetylcholinesterase enzyme, to prevent further stimulation.

In MG, immune cells create antibodies against the acetylcholine receptor. Antibodies are proteins normally involved in fighting infection. When these antibodies attach to the receptor, they prevent it from receiving acetylcholine, decreasing the ability of the muscle to respond to stimulation.

Why the immune system creates these self-reactive "autoantibodies" is unknown, although there are several hypotheses:

  • During fetal development, the immune system generates many B cells that can make autoantibodies, but B cells that could harm the body's own tissues are screened out and destroyed before birth. It is possible that the stage is set for MG when some of these cells escape detection.
  • Genes controlling other parts of the immune system, called MHC genes, appear to influence how susceptible a person is to developing autoimmune disease.
  • Infection may trigger some cases of MG. When activated, the immune system may mistake portions of the acetylcholine receptor for portions of an invading virus, though no candidate virus has yet been identified conclusively.
  • About 10% of those with MG also have thymomas, or benign tumors of the thymus gland. The thymus is a principal organ of the immune system, and researchers speculate that thymic irregularities are involved in the progression of MG.

Some or all of these factors (developmental, genetic, infectious, and thymic) may interact to create the autoimmune reaction.

The earliest symptoms of MG often result from weakness of the extraocular muscles, which control eye movements. Symptoms involving the eye (ocular symptoms) include double vision (diplopia), especially when not gazing straight ahead, and difficulty raising the eyelids (ptosis ). A person with ptosis may need to tilt their head back to see. Eye-related symptoms remain the only symptoms for about 15% of MG patients. Another common early symptom is difficulty chewing and swallowing, due to weakness in the bulbar muscles, which are in the mouth and throat. Choking becomes more likely, especially with food that requires extensive chewing.

Weakness usually becomes more widespread within several months of the first symptoms, reaching their maximum within a year in two-thirds of patients. Weakness may involve muscles of the arms, legs, neck, trunk, and face, and affect the ability to lift objects, walk, hold the head up, and speak.

Symptoms of MG become worse upon exertion, and better with rest. Heat, including heat from the sun, hot showers, and hot drinks, may increase weakness. Infection and stress may worsen symptoms. Symptoms may vary from day to day and month to month, with intervals of no weakness interspersed with a progressive decline in strength.

"Myasthenic crisis" may occur, in which the breathing muscles become too weak to provide adequate respiration. Symptoms include weak and shallow breathing, shortness of breath, pale or bluish skin color, and a racing heart. Myasthenic crisis is an emergency condition requiring immediate treatment. In patients treated with anticholinesterase agents, myasthenic crisis must be differentiated from cholinergic crisis related to overmedication.

Pregnancy worsens MG in about one third of women, has no effect in one third, and improves symptoms in another third. About 12% of infants born to women with MG have "neonatal myasthenia," a temporary but potentially life-threatening condition. It is caused by the transfer of maternal antibodies into the fetal circulation just before birth. Symptoms include weakness, floppiness, feeble cry, and difficulty feeding. The infant may have difficulty breathing, requiring the use of a ventilator. Neonatal myasthenia usually clears up within a month.

Diagnosis

Myasthenia gravis is often diagnosed accurately by a careful medical history and a neuromuscular exam, but several tests are used to confirm the diagnosis. Other conditions causing worsening of bulbar and skeletal muscles must be considered, including drug-induced myasthenia, thyroid disease, Lambert-Eaton myasthenic syndrome, botulism, and inherited muscular dystrophies.

MG causes characteristic changes in the electrical responses of muscles that may be observed with an electromyogram, which measures muscular response to electrical stimulation. Repetitive nerve stimulation leads to reduction in the height of the measured muscle response, reflecting the muscle's tendency to become fatigued.

Blood tests may confirm the presence of the antibody to the acetylcholine receptor, though up to a quarter of MG patients will not have detectable levels. A chest x ray or chest computed tomography scan (CT scan) may be performed to look for thymoma.

Treatment

While there is no cure for myasthenia gravis, there are a number of treatments that effectively control symptoms in most people.

Edrophonium (Tensilon) blocks the action of acetylcholinesterase, prolonging the effect of acetylcholine and increasing strength. An injection of edrophonium rapidly leads to a marked improvement in most people with MG. An alternate drug, neostigmine, may also be used.

Pyridostigmine (Mestinon) is usually the first drug tried. Like edrophonium, pyridostigmine blocks acetylcholinesterase. It is longer-acting, taken by mouth, and well-tolerated. Loss of responsiveness and disease progression combine to eventually make pyridostigmine ineffective in tolerable doses in many patients.

Thymectomy, or removal of the thymus gland, has increasingly become standard treatment for MG. Up to 85% of people with MG improve after thymectomy, with complete remission eventually seen in about 30%. The improvement may take months or even several years to fully develop. Thymectomy is not usually recommended for children with MG, since the thymus continues to play an important immune role throughout childhood.

Immune-suppressing drugs are used to treat MG if response to pyridostigmine and thymectomy are not adequate. Drugs include corticosteroids such as prednisone, and the non-steroids azathioprine (Imuran) and cyclosporine (Sandimmune).

Plasma exchange may be performed to treat myasthenic crisis or to improve very weak patients before thymectomy. In this procedure, blood plasma is removed and replaced with purified plasma free of autoantibodies. It can produce a temporary improvement in symptoms, but is too expensive for long-term treatment. Another blood treatment, intravenous immunoglobulin therapy, is also used for myasthenic crisis. In this procedure, large quantities of purified immune proteins (immunoglobulins) are injected. For unknown reasons, this leads to symptomatic improvement in up to 85% of patients. It is also too expensive for long-term treatment.

People with weakness of the bulbar muscles may need to eat softer foods that are easier to chew and swallow. In more severe cases, it may be necessary to obtain nutrition through a feeding tube placed into the stomach (gastrostomy tube).

Prognosis

Most people with MG can be treated successfully enough to prevent their condition from becoming debilitating. In some cases, however, symptoms may worsen even with vigorous treatment, leading to generalized weakness and disability. MG rarely causes early death except from myasthenic crisis.

Prevention

There is no known way to prevent myasthenia gravis. Thymectomy improves symptoms significantly in many patients, and relieves them entirely in some. Avoiding heat can help minimize symptoms.

Some drugs should be avoided by people with MG because they interfere with normal neuromuscular function.

Drugs to be avoided or used with caution include:

  • Many types of antibiotics, including erythromycin, streptomycin, and ampicillin
  • Some cardiovascular drugs, including Verapamil, betaxolol, and propranolol
  • Some drugs used in psychiatric conditions, including chlorpromazine, clozapine, and lithium.

Many other drugs may worsen symptoms as well, so patients should check with the doctor who treats their MG before taking any new drugs.

A Medic-Alert card or bracelet provides an important source of information to emergency providers about the special situation of a person with MG. They are available from health care providers.

Resources

ORGANIZATIONS

Muscular Dystrophy Association. 3300 East Sunrise Drive, Tucson, AZ 85718. (800) 572-1717. http://www.mdausa.org.

Myasthenia Gravis Foundation of America. 222 S. Riverside Plaza, Suite 1540, Chicago, IL 60606. (800) 541-5454. http://www.med.unc.edu.

KEY TERMS

Antibody An immune protein normally used by the body for combating infection and which is made by B cells.

Autoantibody An antibody that reacts against part of the self.

Autoimmune disease A disease caused by a reaction of the body's immune system.

Bulbar muscles Muscles that control chewing, swallowing, and speaking.

Neuromuscular junction The site at which nerve impulses are transmitted to muscles.

Pyridostigmine bromide (Mestinon) An anticholinesterase drug used in treating myasthenia gravis.

Tensilon test A test for diagnosing myasthenia gravis. Tensilon is injected into a vein and, if the person has MG, their muscle strength will improve for about five minutes.

Thymus gland A small gland located just above the heart, involved in immune system development.

Myasthenia Gravis

views updated May 18 2018

Myasthenia gravis

Definition

Myasthenia gravis is an autoimmune disease that causes muscle weakness.

Description

The name myasthenia gravis literally means "grave muscle weakness". Myasthenia gravis (MG) affects the neuromuscular junction, interrupting the communication between nerve and muscle, and thereby causing weakness. A person with MG may have difficulty moving their eyes, walking, speaking clearly, swallowing, and even breathing, depending on the severity and distribution of weakness. Increased weakness with exertion, and improvement with rest, is a characteristic feature of MG.

Genetic profile

Myasthenia gravis is not inherited directly nor is it contagious. It is usually considered sporadic, meaning that it occurs by chance. One to four percent of cases are familial, which means they occur more than once in a family. Predisposition in a family to develop myasthenia gravis may be due to autoimmunity in general.

Demographics

About 36,000 people in the United States are affected by MG; roughly 14 people per 100,000. It can occur at any age, but is most common in women under age 40, and in men who are over 60. Occasionally the disease is present in more than one person in a family.

Signs and symptoms

Myasthenia gravis is an autoimmune disease, meaning it is caused by the body's own immune system. In MG, the immune system attacks a receptor on the surface of muscle cells. This prevents the muscle from receiving the nerve impulses that normally make it respond. MG affects "voluntary" muscles, which are those muscles under conscious control responsible for movement. It does not affect heart muscle or the "smooth" muscle found in the digestive system and other internal organs.

A muscle is stimulated to contract when the nerve cell controlling it releases acetylcholine molecules onto its surface. The acetylcholine lands on a muscle protein called the acetylcholine receptor. This leads to rapid chemical changes in the muscle, which cause it to contract. Acetylcholine is then broken down by acetylcholinesterase enzyme, to prevent further stimulation.

In MG, immune cells create antibodies against the acetylcholine receptor. Antibodies are proteins normally involved in fighting infection. When these antibodies attach to the receptor, they prevent it from receiving acetylcholine, decreasing the ability of the muscle to respond to stimulation.

Why the immune system creates these self-reactive "autoantibodies" is unknown, although there are several hypotheses:

  • During fetal development, the immune system generates many B cells that can make autoantibodies, but B cells that could harm the body's own tissues are screened out and destroyed before birth. It is possible that the stage is set for MG when some of these cells escape detection.
  • Genes controlling other parts of the immune system, called MHC genes, appear to influence how susceptible a person is to developing autoimmune disease.
  • Infection may trigger some cases of MG. When activated, the immune system may mistake portions of the acetylcholine receptor for portions of an invading virus, though no candidate virus has yet been identified conclusively.
  • About 10% of those with MG also have thymomas, or benign tumors of the thymus gland. The thymus is a principal organ of the immune system, and researchers speculate that thymic irregularities are involved in the progression of MG.

Some or all of these factors (developmental, genetic, infectious, and thymic) may interact to create the autoimmune reaction.

The earliest symptoms of MG often result from weakness of the extraocular muscles, which control eye movements. Symptoms involving the eye (ocular symptoms) include double vision (diplopia), especially when not gazing straight ahead, and difficulty raising the eyelids (ptosis). A person with ptosis may need to tilt their head back to see. Eye-related symptoms remain the only symptoms for about 15% of MG patients. Another common early symptom is difficulty chewing and swallowing, due to weakness in the bulbar muscles, which are in the mouth and throat. Choking becomes more likely, especially with food that requires extensive chewing.

Weakness usually becomes more widespread within several months of the first symptoms, reaching their maximum within a year in two-thirds of patients. Weakness may involve muscles of the arms, legs, neck, trunk, and face, and affect the ability to lift objects, walk, hold the head up, and speak.

Symptoms of MG become worse upon exertion and better with rest. Heat, including heat from the sun, hot showers, and hot drinks, may increase weakness. Infection and stress may worsen symptoms. Symptoms may vary from day to day and month to month, with intervals of no weakness interspersed with a progressive decline in strength.

Myasthenic crisis is an emergency condition requiring immediate treatment. It may occur when the breathing muscles become too weak to provide adequate respiration. Symptoms include weak and shallow breathing, shortness of breath, pale or bluish skin color, and a racing heart. In patients treated with anticholinesterase agents, myasthenic crisis must be differentiated from cholinergic crisis related to overmedication.

Pregnancy worsens MG in about one third of women, has no effect in one third, and improves symptoms in another third. About 12% of infants born to women with MG have neonatal myasthenia, a temporary but potentially life-threatening condition. It is caused by the transfer of maternal antibodies into the fetal circulation just before birth. Symptoms include weakness, poor muscle tone, feeble cry, and difficulty feeding. The infant may have difficulty breathing, requiring the use of a ventilator. Neonatal myasthenia usually clears up within a month.

Diagnosis

Myasthenia gravis is often diagnosed accurately by a careful medical history and a neuromuscular exam, but several tests are used to confirm the diagnosis. Other conditions causing worsening of bulbar and skeletal muscles must be considered, including drug-induced myasthenia, thyroid disease, Lambert-Eaton myasthenic syndrome, botulism, and inherited muscular dystrophies.

MG causes characteristic changes in the electrical responses of muscles that may be observed with an electromyogram, which measures muscular response to electrical stimulation. Repetitive nerve stimulation leads to reduction in the height of the measured muscle response, reflecting the muscle's tendency to become fatigued.

Blood tests may confirm the presence of the anti-body to the acetylcholine receptor, though up to a quarter of MG patients will not have detectable levels. A chest x ray or chest computed tomography scan (CT scan) may be performed to look for thymoma.

Treatment and management

While there is no cure for myasthenia gravis, there are a number of treatments that effectively control symptoms in most people.

Edrophonium (Tensilon) blocks the action of acetylcholinesterase, prolonging the effect of acetylcholine and increasing strength. An injection of edrophonium rapidly leads to a marked improvement in most people with MG. An alternate drug, neostigmine, may also be used.

Pyridostigmine (Mestinon) is usually the first drug prescribed. Like edrophonium, pyridostigmine blocks acetylcholinesterase. It is longer-acting, taken by mouth, and well-tolerated. Loss of responsiveness and disease progression combine to eventually make pyridostigmine ineffective in tolerable doses in many patients.

Thymectomy, or removal of the thymus gland, has increasingly become standard treatment for MG. Up to 85% of people with MG improve after thymectomy, with complete remission eventually seen in about 30%. The improvement may take months or even several years to fully develop. Thymectomy is not usually recommended for children with MG, since the thymus continues to play an important immune role throughout childhood.

Immune-suppressing drugs are used to treat MG if response to pyridostigmine and thymectomy are not adequate. Drugs include corticosteroids such as prednisone, and the non-steroids azathioprine (Imuran) and cyclosporine (Sandimmune).

Plasma exchange may be performed to treat myasthenic crisis or to improve very weak patients before thymectomy. In this procedure, blood plasma is removed and replaced with purified plasma free of autoantibodies. It can produce a temporary improvement in symptoms, but is too expensive for long-term treatment. Another blood treatment, intravenous immunoglobulin therapy, is also used for myasthenic crisis. In this procedure, large quantities of purified immune proteins (immunoglobulins) are injected. For unknown reasons, this leads to symptomatic improvement in up to 85% of patients. It is also too expensive for long-term treatment.

People with weakness of the bulbar muscles may need to eat softer foods that are easier to chew and swallow. In more severe cases, it may be necessary to obtain nutrition through a feeding tube placed into the stomach (gastrostomy tube).

Some drugs should be avoided by people with MG because they interfere with normal neuromuscular function. Drugs to be avoided or used with caution include:

  • Many types of antibiotics, including erythromycin, streptomycin, and ampicillin
  • Some cardiovascular drugs, including Verapamil, betaxolol, and propranolol
  • Some drugs used in psychiatric conditions, including chlorpromazine, clozapine, and lithium.

Many other drugs may worsen symptoms as well, so patients should check with the doctor who treats their MG before taking any new medications.

A Medic-Alert card or bracelet provides an important source of information to emergency providers about the special situation of a person with MG. They are available from health care providers.

Prognosis

Most people with MG can be treated successfully enough to prevent their condition from becoming debilitating. In some cases, however, symptoms may worsen even with vigorous treatment, leading to generalized weakness and disability. MG rarely causes early death except from myasthenic crisis. There is no known way to prevent myasthenia gravis. Thymectomy improves symptoms significantly in many patients, and relieves them entirely in some. Avoiding heat can help minimize symptoms.

Resources

BOOKS

Swash, Michael, and Martin Schwarz. Neuromuscular Diseases: A Practical Approach to Diagnosis and Management. Springer, 1997.

PERIODICALS

Drachman, D. B. "Myasthenia Gravis." New England Journal of Medicine 330 (1994): 1797-1810.

Robinson, Richard. "The Body At War with Itself." Quest 4, no. 3 (1997): 20-24.

ORGANIZATIONS

Muscular Dystrophy Association. 3300 East Sunrise Dr., Tucson, AZ 85718. (520) 529-2000 or (800) 572-1717. <http://www.mdausa.org>.

Myasthenia Gravis Foundation of America. 5841 Cedar Lake Rd., Suite 204, Minneapolis, MN 55416. (800) 541-5454. Fax: (952) 545-6073.

WEBSITES

Immune Deficiency Foundation. <http://www.primaryimmune.org>.

Myasthenia Gravis Foundation of America<http://www.myasthenia.org>.

National Institute of Neurological Disorders and Stroke Fact Sheet on Myasthenia Gravis. <http://www.ninds.nih.gov/health_and_medical/pubs/myasthenia_gravis.htm>.

Catherine L. Tesla, MS, CGC

Myasthenia Gravis

views updated May 29 2018

Myasthenia gravis

Description

Myasthenia gravis (MG) is an autoimmune disease that causes muscle weakness. It affects the neuromuscular junction, interrupting the communication between nerve and muscle, and thereby causing weakness. People with MG may have difficulty moving their eyes, walking, speaking clearly, swallowing, and even breathing, depending on the severity and distribution of weakness. Increased weakness with exertion, and improvement with rest, is a characteristic feature of MG.

About 30, 000 people in the United States are affected by MG. It can occur at any age, but is most common in women who are in their late teens and early twenties, and in men in their sixties and seventies.

MG has been associated with malignant thymoma , a disease in which cancer cells are found in the tissues of the thymus.

Causes

Myasthenia gravis is an autoimmune disease, meaning that it is caused by the body's own immune system. In MG, the immune system attacks a receptor on the surface of muscle cells. This prevents the muscle from receiving the nerve impulses that normally make it respond. MG affects "voluntary" muscles, which are those muscles under conscious control responsible for movement. It does not affect heart muscle or the "smooth" muscle found in the digestive system and other internal organs.

A muscle is stimulated to contract when the nerve cell controlling it releases acetylcholine molecules onto its surface. The acetylcholine lands on a muscle protein called the acetylcholine receptor. This leads to rapid chemical changes in the muscle which cause it to contract. Acetylcholine is then broken down by acetylcholinesterase enzyme, to prevent further stimulation.

In MG, immune cells create antibodies against the acetylcholine receptor. Antibodies are proteins normally involved in fighting infection. When these antibodies attach to the receptor, they prevent it from receiving acetylcholine, decreasing the ability of the muscle to respond to stimulation.

Why the immune system creates these self-reactive "autoantibodies" is unknown, although there are several hypotheses:

  • During fetal development, the immune system generates many B cells that can make autoantibodies, but B cells that could harm the body's own tissues are screened out and destroyed before birth. It is possible that the stage is set for MG when some of these cells escape detection.
  • Genes controlling other parts of the immune system, called MHC genes, appear to influence how susceptible a person is to developing autoimmune disease.
  • Infection may trigger some cases of MG. When activated, the immune system may mistake portions of the acetylcholine receptor for portions of an invading virus, though no candidate virus has yet been identified conclusively.
  • About 10% of those with MG also have thymomas, or tumors of the thymus gland. The thymus is a principal organ of the immune system, and researchers speculate that thymic irregularities are involved in the progression of MG. A definite relationship exists between MG and thymoma: of patients with MG, 15% also have thymoma, and of patients with thymoma, 50% have MG.

Treatment

While there is no cure for myasthenia gravis, there are a number of treatments that effectively control symptoms in most people. Even though no rigorously tested treatment trials have been reported and no clear consensus exists on treatment strategies, MG is one of the most treatable immune disorders. Several factors require consideration before initiating treatment, such as the severity, distribution, and rapidity of the MG progression.

Edrophonium (Tensilon) is a drug used to block the action of acetylcholinesterase, prolonging the effect of acetylcholine and increasing strength. An injection of edrophonium rapidly leads to a marked improvement in most people with MG. An alternate drug, neostigmine, may also be used.

Pyridostigmine (Mestinon) is usually the first drug tried. Like edrophonium, pyridostigmine blocks acetylcholinesterase. It is longer-acting, taken by mouth, and well-tolerated. Loss of responsiveness and disease progression combine to eventually make pyridostigmine ineffective in tolerable doses in many patients.

Thymectomy, or removal of the thymus gland, has increasingly become a standard form of treatment for MG. Up to 85% of people with MG improve after thymectomy, with complete remission eventually seen in about 30%. The improvement may take months or even several years to fully develop. Thymectomy is not usually recommended for children with MG, since the thymus continues to play an important immune role throughout childhood.

Immune-suppressing drugs are used to treat MG if patient response to pyridostigmine and thymectomy is not adequate. These drugs include corticosteroids such as prednisone, and the non-steroids azathioprine (Imuran) and cyclosporine (Sandimmune).

Plasma exchange may also be performed to treat the condition or to strengthen very weak patients before thymectomy. In this procedure, blood plasma is removed and replaced with purified plasma free of autoantibodies. It can produce a temporary improvement in symptoms, but is too expensive for long-term treatment. Another blood treatment, intravenous immunoglobulin therapy, is also used. In this procedure, large quantities of purified immune proteins (immunoglobulins) are injected. For unknown reasons, this leads to symptomatic improvement in up to 85% of patients. It is also too expensive for long-term treatment. There are indications that IVIg is an effective immunoglobulin for some categories of MG patients.

People with weakness of the bulbar muscles may need to eat softer foods that are easier to chew and swallow. In more severe cases, it may be necessary to obtain nutrition through a feeding tube placed into the stomach (gastrostomy tube).

Alternative and complementary therapies

No alternative therapies have been shown to be effective for the treatment of MG. Reports claiming that herbal remedies or alternative treatments alleviate or cure MG have not been corroborated by properly controlled clinical trials , which are required to evaluate the benefit of such treatments.

Among complementary MG therapies, prescription of low dose atropine can help relieve the cramping and diarrhea often caused by the drug Mestinon. Propantheline bromide (ProBanthine)is a drug similar to atropine, and it may also be prescribed to treat gastrointestinal discomfort. Caution must be taken not to take too much atropine because it cancels the beneficial effects of the anticholinesterase drugs. Ephedrine is sometimes also used with anticholinesterase therapy to strengthen the muscle tissue of MG patients.

Resources

BOOKS

Swash, Michael and Martin Schwarz. Neuromuscular Diseases: A Practical Approach to Diagnosis and Manage ment. Springer, 1997.

PERIODICALS

Davitt, B. V., G. A. Fenton, O. A. Cruz. "Childhood myasthe nia." Journal of Ophthalmic and Nursing Technology 19 (March-April 2000):74-81

Garg, R. K. "Myasthenia gravis." Journal of the Association of Physicians, India 46 (March 1998):286-93.

Bedlack, R. S., and D. B. Sanders. "How to handle myasthenic crisis. Essential steps in patient care." Postgraduate Medi cine 107 (April 2000):211-214.

Carrieri, P. B., E. Marano, A. Perretti, and G. Caruso. "The thymus and myasthenia gravis: immunological and neuro-physiological aspects." Annals of Medicine 31 (October 1999) Suppl 2:52-56

ORGANIZATION

Muscular Dystrophy Association. 3300 East Sunrise Drive, Tucson, AZ 85718. (520) 529-2000 or (800) 572-1717. <http:www.mdausa.org.> 29 June 2001.

Myasthenia Gravis Foundation of America. 222 S. Riverside Plaza, Suite 1540, Chicago, IL 60606. (800) 541-5454. <http://www.myasthenia.org> 29 June 2001.

Richard Robinson

Monique Laberge, Ph.D.

KEY TERMS

Antibody

An immune protein normally used by the body for combating infection and which is made by B cells.

Atropine

An alkaloid extract from belladonna.

Autoantibody

An antibody that reacts against part of the self.

Autoimmune disease

A disease caused by a reaction of the body's immune system.

Bulbar muscles

Muscles that control chewing, swallowing, and speaking.

Immunoglobulin

A protein substance produced by plasma cells which helps to fight infection.

Malignant thymoma

A disease in which cancer cells are found in the tissues of the thymus, a small organ that lies under the breastbone.

Neuromuscular junction

The site at which nerve impulses are transmitted to muscles.

Pyridostigmine bromide (Mestinon)

An anti-cholinesterase drug used in treating myasthenia gravis.

Tensilon test

A test for diagnosing myasthenia gravis. Tensilon is injected into a vein and, if the person has MG, their muscle strength will improve for about five minutes.

Thymectomy

Removal of the thymus by surgery, radiation or chemical means

Thymus gland

A small gland located just above the heart, involved in immune system development.

myasthenia

views updated May 21 2018

my·as·the·ni·a / ˌmīəsˈ[unvoicedth]ēnēə/ • n. a condition causing abnormal weakness of certain muscles. ∎  (in full myasthenia gravis / ˈgravis/ ) a rare chronic autoimmune disease marked by muscular weakness without atrophy, and caused by a defect in the action of acetylcholine at neuromuscular junctions.

myasthenia

views updated Jun 08 2018

myasthenia (my-ăs-th'ee-niă) n. weakness of the muscles. m. gravis a chronic disease marked by abnormal fatigability and weakness of selected muscles, initially those around the eyes, mouth, and throat, resulting in drooping of the upper eyelid (ptosis), double vision, dysarthria, and dysphagia. It is an autoimmune disease in which the ability of the neurotransmitter acetylcholine to induce muscular contraction is impaired. Treatment with anticholinesterase drugs and surgical removal of the thymus in patients under the age of 45 lessen the severity of the symptoms. Steroid therapy or plasma exchange may be used to treat the more severely affected patients.