Newly Acquired Weakness in the Intensive Care Unit: Critical Illness Myopathy and Neuropathy
David A. Chad
Although preexisting neuromuscular disorders (such as myasthenia gravis and the Guillain–Barré syndrome) may cause severe weakness leading to an intensive care unit (ICU) admission, two of the most common causes of newly acquired weakness arising in the ICU setting are critical illness myopathy and critical illness polyneuropathy [1,2]. Critical illness myopathy is probably the major contributor to severe ICU-acquired weakness, causing most instances of failure to wean from a respirator in patients with severe systemic diseases in the ICU, while critical illness polyneuropathy affects 70% to 80% of patients with severe sepsis and multiorgan failure [3]. Even experienced clinicians have great difficulty distinguishing between the myopathy and the polyneuropathy of intensive care, especially because the two conditions often coexist in an individual patient [4,5,6]. In the sections that follow, we discuss each disorder and comment on the differential diagnosis of severe weakness arising in the ICU setting.
Critical Illness Myopathy
Diagnosis
The hallmark of critical illness myopathy is weakness that is typically diffuse in distribution, affecting both limb and neck muscles [7]. As is typical of most myopathic disorders, weakness tends to have a proximal predominance in the limbs, but it may also involve distal muscles profoundly. Tendon reflexes tend to be depressed but present, and on occasion, may be absent, possibly due to a generalized reduction in membrane excitability that occurs in sepsis [8]. There may be facial muscle involvement, and rarely, extraocular muscles are affected [9]; other muscles supplied by cranial nerves are usually spared. A serious and common complication of the myopathy is failure to wean from a ventilator due to marked weakness of the diaphragm. Although the majority of affected patients are adults, severe myopathic muscle weakness may occur in children who receive organ transplants [10].
Risk Factors
Critical illness myopathy develops in up to one-third of patients treated for status asthmaticus in the ICU; and in this population, intravenous corticosteroids and neuromuscular blocking agents are considered major risk factors [11]. Occasionally, the myopathy develops in patients who have received high-dose corticosteroids alone, without neuromuscular blocking agents, or in patients who have received neither corticosteroids nor neuromuscular blocking agents, but the latter group typically has severe systemic illness with multiorgan failure and sepsis [8]. Overall, critical illness myopathy accounts for 42% of weakness among patients in the surgical and medical ICU setting [12].
Laboratory Studies
Serum creatine kinase (CK), electromyography (EMG), and muscle biopsy are the most important and revealing studies in the diagnosis of ICU-acquired muscle weakness. An elevated CK level helps to support the diagnosis of a myopathic cause of weakness in an ICU patient, but in the myopathy of intensive care, the CK rise, which is found in about 50% of affected patients, only occurs early in the course of the illness, peaks within a few days of onset, and then declines back into the normal range [7].
EMG Studies
With nerve conduction studies, motor responses are typically low-amplitude or absent, while sensory responses are relatively preserved, with amplitudes that are > 80% of normal in two or more nerves (sensory responses may be reduced, however, when ICU polyneuropathy coexists; see following discussion). Sensory responses may also be reduced initially in association with sepsis and increase during clinical recovery [8]. Needle electrode examination shows fibrillation potential activity in resting muscle in some patients. On voluntary muscle activation, motor unit potentials are short in duration and polyphasic in form with early recruitment, but when there is severe weakness or encephalopathy due to sepsis, the patient may be unable to contract muscles sufficiently to permit analysis of motor unit potentials. An interesting observation made of patients with critical illness myopathy, and demonstrated by direct muscle stimulation, is that the condition leads to electrical inexcitability of the muscle membrane [13,14] so that the ratio of nerve-evoked muscle action potential to direct stimulation of muscle is close to 1. In contrast, when weakness stems from severe neuropathy, the ratio of nerve-evoked response to muscle-stimulation–evoked response is less than 1 (and close to 0).
Muscle Biopsy
With a fairly stereotypic clinical presentation, and EMG results typical of a myopathy—often with fibrillation potential activity—the muscle biopsy is usually not necessary to establish the diagnosis of ICU myopathy. When the diagnosis is uncertain, and especially when diseases with specific therapies—such as the Guillain–Barré syndrome—are considered, a muscle biopsy may prove helpful. Biopsy shows muscle fiber atrophy, especially involving the type II fibers; a variable degree of muscle fiber necrosis, the absence of any inflammatory cells; and the hallmark of the disorder: features of a disrupted
intramyofibrillar network that manifests as patchy or complete reduction in myosin–adenosine triphosphatase reactivity in nonnecrotic fibers due to a loss of myosin that may be confirmed immunocytochemically or by electron microscopy [8]. There is a spectrum of histopathological severity ranging from a relatively mild myopathy without major structural damage (designated a cachectic myopathy) to a more severe myopathy with selective thick filament loss, and extending to the most severe manifestation of myopathy characterized by pronounced necrotizing features [6].
intramyofibrillar network that manifests as patchy or complete reduction in myosin–adenosine triphosphatase reactivity in nonnecrotic fibers due to a loss of myosin that may be confirmed immunocytochemically or by electron microscopy [8]. There is a spectrum of histopathological severity ranging from a relatively mild myopathy without major structural damage (designated a cachectic myopathy) to a more severe myopathy with selective thick filament loss, and extending to the most severe manifestation of myopathy characterized by pronounced necrotizing features [6].
Pathophysiology
Myosin loss and muscle fiber necrosis probably contribute to persisting weakness. Myosin loss is characteristic of critical illness myopathy, and is essentially pathognomonic of the disorder. Corticosteroids may cause the loss of myosin, but other factors trigger the process, such as an abnormal neuromuscular junction caused by pharmacologic blockade in ICU patients [7]. Consistent with this hypothesis is the observation that a patient with myasthenia developed loss of myosin thick filaments after receiving high-dose corticosteroids [15], and that in an animal model of dexamethasone treatment plus denervation, there was a severe preferential depletion of thick filaments, leading to a reduction in muscle fiber size [16]. Some patients who are not exposed to administered corticosteroids or neuromuscular blocking agents, but who are systemically ill, often with metabolic acidosis, can also develop the myopathy of intensive care. Acidosis may stimulate glucocorticoid production, lead to an increase in muscle protein degradation, and trigger thick filament loss [7]. Finally, as noted earlier, muscle membrane inexcitability is noted in some patients with the disorder. In an animal model of ICU-related myopathy (rats treated with corticosteroids for 7 to 10 days after denervation of muscle in one leg), intracellular recordings in individual muscle fibers demonstrate that many fibers become unable to generate action potentials [17]. Paralysis appears to be due to abnormal inactivation of sodium channels, which suggests that the myopathy of intensive care may be, in part, an acquired disease of ion channel gating.