Critical Illness Neuromyopathy and the Role of Physical Therapy and Rehabilitation in Critically Ill Patients

Immobility and Disuse Atrophy

Prolonged immobility from bed rest is common in many ICUs and may contribute to ICUAW.^9,10 Immobility leads to decreased muscle protein synthesis, increased muscle catabolism, and decreased muscle mass, especially in the lower extremities.^11,12 These changes manifest as reduced cross-sectional muscle area and decreased contractile strength. Moreover, there is a general shift from slow twitch (type I) to fast twitch (type II) muscle fibers, leading to reduced muscle endurance.¹³ Experiments in healthy volunteers reveal that muscle atrophy begins within hours of immobility,¹⁴ resulting in a 4–5% loss of muscle strength for each week of bed rest.¹⁵ The interaction of critical illness with immobility may lead to even greater muscle loss.¹⁶ In a prospective study of 109 ARDS survivors, patients lost 18% of their baseline body weight by ICU discharge.⁶ Age may also be an important factor, as more elderly sarcopenic patients are admitted to the ICU, and begin with a lower muscle mass at baseline.¹⁷ Furthermore, muscle quality declines with aging, resulting in increased intramuscular fat, with associated decreased muscle thickness and cross-sectional area.¹⁸ Short-term immobility also impairs microvascular function and induces insulin resistance,¹⁹ which may contribute to neuromuscular injury in the critically ill. Finally, immobility increases production of pro-inflammatory cytokines and reactive oxygen species, resulting in further muscle proteolysis, with a net loss of muscle protein and subsequent muscle weakness.²⁰

Critical Illness Polyneuropathy and Myopathy

First described in 1984 in association with sepsis, CIP is a diffuse and symmetric sensorimotor axonal neuropathy.²¹ The mechanism of axonal degeneration may be multifactorial, including: impaired oxygen and nutrient delivery from microcirculatory dysfunction in peripheral nerves, due to sepsis and/or hyperglycemia, and increased endoneuronal edema, due to cytokine-induced changes in microvascular permeability; and neuronal bioenergetic failure from mitochondrial dysfunction, due to increased uptake of glucose and subsequent reactive oxygen species generation.^22,23 Furthermore, cytokines may exert direct toxic effects on peripheral nerves, and there may be a humoral neurotoxic factor involved in the pathogenesis of CIP.²⁴

CIM represents a spectrum of ICU-acquired muscle pathology involving metabolic, inflammatory, and bioenergetic muscle derangements. Decreased oxygen and nutrient delivery to muscles, upregulation of protein catabolism by pro-inflammatory cytokines, decreased expression of myofibrillar repair genes, and an imbalance in anabolic and catabolic hormones contribute to CIM.^22,23 Functional inactivation of the remaining muscle may occur due to membrane inexcitability from acquired ion-channel dysfunction and excitation-contraction decoupling, due to impaired calcium release within muscle fibers.²⁵

CIP and CIM often coexist, commonly referred to collectively as critical illness neuromyopathy (CINM). Muscle that is functionally denervated (from CIP) and directly injured (from CIM) may have increased susceptibility to additional insults and injury (eg, corticosteroid-induced myopathy).²⁶ Furthermore, weakness from CINM may be enhanced by immobility.²⁷

In addition to the effects of critical illness on skeletal muscle, diaphragmatic involvement may occur, with atrophy and reduced muscle force.²⁸ In a study of brain-dead organ donors (with effective functional denervation), even short-term diaphragmatic inactivity with controlled mechanical ventilation may result in marked diaphragmatic atrophy.²⁹ We hypothesize that this “2-hit” combination of immobilization and the early development of subclinical CINM may contribute to rapid muscle atrophy.³⁰

Physical Examination

Physical examination of muscle strength is commonly conducted using the Medical Research Council (MRC) scale (range: 0 = no muscle contraction, to 5 = normal strength).⁴⁴ Such physical examination can be challenging because it requires patient effort and cooperation, which may be limited by sedation, delirium, or coma.⁴⁵ As a measure of overall muscle strength, a composite MRC score from examination of 3 muscle groups in each limb is commonly used. This composite MRC score has excellent inter-rater reliability within specific non-ICU patient populations, as well as in survivors of critical illness.^45–47 Clinically important muscle weakness has been arbitrarily defined as a composite MRC score < 80% of normal (eg, a score < 48 out of a maximum of 60 based on examination of 3 muscle groups in each limb).^4,46,48 Typically, symmetric weakness is observed in all limbs, ranging from mild paresis to frank quadriplegia. In non-cooperative patients with ICUAW, noxious stimuli applied to each extremity may elicit facial grimacing with limited or absent patient withdrawal, reflecting the typical pattern of peripheral weakness with relative sparing of facial muscles.

Similar to the motor examination, the sensory examination is frequently limited by sedation, delirium, and/or peripheral edema. Deep tendon reflexes may be diminished or absent in CINM, but normal reflexes do not rule out ICUAW. Hyper-reflexia or associated spasticity suggests an alternative diagnosis (eg, central nervous system etiology), and further investigations (eg, brain and spinal cord imaging) should be considered.

Electrophysiological Testing

Given the limitations of physical examination, electrophysiological testing (ie, motor/sensory nerve conduction studies and needle electromyography) may be used in the diagnostic workup for ICUAW. In patients with CIP, nerve conduction studies often reveal a mixed sensorimotor axonopathy (ie, reduced compound muscle action potential and sensory nerve action potential amplitudes) with relative preservation of the nerve conduction velocity.²² These electrophysiologic changes can be detected as early as 24–48 hours following the onset of critical illness, and often precede clinical findings in these patients.⁴⁹ Despite their potential utility in sedated or comatose patients, certain technical factors, including local edema and limb temperature, can interfere with nerve conduction studies testing.⁵⁰

In patients with CIM, prolongation of compound muscle action potential duration suggests the presence of a myopathic process (ie, not due to muscle denervation).⁵⁰ Direct muscle stimulation may yield reduced or absent responses in CIM, but normal responses in CIP. On needle electromyography, CIM will manifest as short duration, low amplitude motor unit action potentials, with early recruitment on volitional contraction. Furthermore, non-specific abnormal spontaneous activity, including fibrillation potentials and positive sharp waves, may be present in CIM and CIP.⁵⁰

Muscle Biopsy

Definitive diagnosis of an underlying myopathy requires histologic confirmation with a muscle biopsy. Histopathologic findings consistent with CIM include muscle fiber atrophy, occasional fiber necrosis and regeneration, and selective thick filament (myosin) loss.⁵⁰

Given that CIP and CIM frequently coexist, it may be difficult to differentiate between these conditions, even using available clinical, electrophysiological, and histological data (Table 2). There are limited and conflicting data regarding prognostic differences between CIP and CIM.^48,51 However, prognosis may be correlated with the degree of neuronal involvement and severity of ICUAW. Patients who have a predominantly myopathic process may have a more favorable outcome than those with CIP and profound weakness.⁵⁰ A recent study demonstrated that patients with isolated CIM more frequently had electrophysiological signs of recovery as well as less severe weakness, as compared to patients with CINM.⁵²

Despite its limitations, physical examination is the starting point for identification of ICUAW in the cooperative patient (Table 3). Given the relative cost, invasiveness, and need for specialist physicians and technicians, electrophysiological testing and/or muscle biopsy may be reserved for weak patients with slower than expected improvement on serial clinical examination.

Strategies for the Prevention and Treatment of ICU-Acquired Weakness

Currently, there are few rigorously evaluated interventions for the prevention and/or treatment of ICUAW.^3,40 Minimizing patient exposure to corticosteroids and/or neuromuscular blocking agents, when possible, may be prudent until future studies can clarify the role of these agents in ICUAW. At present, the strongest evidence for prevention of ICUAW is tight glycemic control with intensive insulin therapy.^31,39 However, the potential benefits of intensive insulin therapy should be carefully weighed against the possibility of serious hypoglycemia, and there continues to be uncertainty regarding the optimal blood glucose range in critically ill patients.⁵⁷ Results from the recent multicenter Normoglycemia in Intensive Care Evaluation and Survival Using Glucose Algorithm Regulation (NICE-SUGAR) trial demonstrated no significant difference in days of mechanical ventilation (P = .56), ICU (P = .84) or hospital stay (P = .86) between groups, suggesting potentially no clinically important effect of intensive insulin therapy in the prevention or attenuation of ICUAW.⁵⁸ Finally, despite the lack of high quality evidence, maintenance of electrolyte homeostasis (eg, phosphate, magnesium) and adequate nutrition may be reasonable recommendations for minimizing weakness.⁴³

A relatively new therapeutic option being evaluated for prevention and treatment of ICUAW is early rehabilitation and mobilization of patients in the ICU.⁹ Having critically ill patients alert and engaged in progressive rehabilitation (eg, passive range of motion, active range of motion/bed exercises, sitting at edge of bed, transfers) leading to mobilization, despite the use of life support therapies, may reduce muscle atrophy and lead to improved strength and physical function. Moreover, mobilization and exercise may decrease oxidative stress and inflammation,^9,20 and prevent insulin resistance and microvascular dysfunction,¹⁹ which may ameliorate ICUAW.

There is a paucity of clinical trials evaluating the specific role of early rehabilitation in the chronic critically ill. However, a number of studies have examined the role of rehabilitation in patients receiving chronic mechanical ventilation. In a case series of 16 ventilator-dependent patients referred to an in-patient pulmonary rehabilitation unit, a progressive 5 phase multidisciplinary (physical, occupational, and respiratory therapy) rehabilitation program resulted in most patients (63%) being independent with most or all of their activities of daily living at discharge.⁵⁹ A retrospective study of 49 severely weak and bedridden, chronically ventilator-dependent patients (mean 18 d) referred to a tertiary care ventilator rehabilitation unit examined the effect of their progressive whole body rehabilitation program (5 d per week in an on-site gym) on patient functional outcomes.⁶⁰ At ventilator rehabilitation unit discharge, the patients had significantly improved upper and lower limb motor strength, as well as functional independence (as measured by the functional independence measurement score). All 49 patients were weaned from mechanical ventilation, although 3 patients subsequently required intermittent ventilatory support, could sit and stand, and the majority (40 patients) could ambulate at ventilator rehabilitation unit discharge. Importantly, there were no adverse events related to the rehabilitation program.

At present, there is a single report of a randomized controlled trial evaluating an early rehabilitation program in chronically ill patients admitted to a respiratory ICU (RICU).⁶¹ Patients with COPD following an episode of acute respiratory failure (with approximately 50% requiring invasive mechanical ventilation) were randomized to intensive pulmonary rehabilitation (60 patients) versus standard therapy (20 patients) after admission to a RICU. The pulmonary rehabilitation group initiated therapy within 24 hours of RICU admission, which consisted of twice daily, 30–45 min sessions focused on lower extremity and respiratory muscle training (using threshold device and breathing twice daily at target pressure of 50% of maximal inspiratory pressure), with a goal of progressing to ambulation. The standard therapy group had no specific lower extremity or respiratory muscle training early in their RICU admission. While there was no significant difference between groups in proportion regaining the ability to ambulate (87% vs 70%, P = .09), the pulmonary rehabilitation group had significantly greater improvements in 6-min walk distance (100 m), maximal inspiratory pressure 16 cm H₂O), and dyspnea scores (45%) from their baseline status, as compared to the standard therapy group.

More recently, studies have demonstrated that early mobilization, including ambulation, of mechanically ventilated patients is safe and feasible, even when occurring immediately after physiological stabilization, within 24–72 hours of acute ICU admission.^62–66 Uncontrolled studies of early mobility have been associated with greater activity levels and functional outcomes, versus usual care, in which mobility is frequently delayed until after ICU discharge.⁶⁴ A single-center, non-randomized controlled trial in 330 mechanically ventilated patients built on this earlier research demonstrating that a dedicated multidisciplinary mobility team (critical care nurse, nursing assistant, physical therapist), using a physical rehabilitation protocol, was associated with increased physical therapy and a shorter time for patients to be first out of bed (5.0 d vs 11.3 d, P < .001 adjusted for body mass index, severity of illness, and vasopressor use).⁶² Moreover, patients treated with the early mobility protocol experienced a decrease in ICU stay (5.5 d vs 6.9 d, adjusted P = .025) and hospital stay (11.2 d vs 14.5 d, adjusted P = .006) among survivors. In addition, there was a trend toward a decreased duration of mechanical ventilation (8.8 d vs 10.2 d, adjusted P = .16) and reduced hospital mortality (12% vs 18%, P = .13), without a significant increase in hospital costs, despite the added expense of the mobility team (mean cost per patient $41,142 vs $44,302, P = .26). Temporal trends indicating improved ICU and hospital stay, and declining rates of tracheostomy (29% vs 5%) and failure to wean from mechanical ventilation (12% vs 3%), also have been reported at another center.⁶⁶

Combining protocols for early mobility and sedation management may have synergistic benefits, as demonstrated in a prior trial that combined protocols for sedation and ventilator weaning.⁶⁷ To that end, a recent randomized controlled trial evaluating the use of early rehabilitation in the ICU randomized 104 mechanically ventilated patients to either early exercise and mobilization combined with daily interruption of sedation or daily interruption of sedation alone.⁶⁸ Patients in the therapy group had physical and occupational therapy initiated early, as compared to controls (median 1.5 d vs 7.4 d after intubation, P < .001). Patients in the intervention group had shorter duration of delirium (median 2 d vs 4 d, P = .02) and more ventilator-free days (23.5 d vs 21.1 d, P = .05). Serious adverse events were rare. A greater proportion of patients had a return to independent functional status at hospital discharge in the intervention group (59 vs 35%, P = .02). These encouraging results require further investigation in multicenter randomized trials.

Barriers to early mobility, both real (eg, oversedation) and perceived (eg, vasopressors, obesity), represent substantial challenges to translating this intervention into practice in many ICUs.^69–72 An important step in developing a successful early mobility program in the ICU requires a paradigm shift away from bed rest and heavy sedation, and toward a culture of prioritizing awake, spontaneously breathing patients and a focus on early rehabilitation.⁷³ Creating a supportive ICU culture for early mobilization through interdisciplinary cooperation, coordination, and communication are integral to the successful and sustained implementation of this complex intervention.^65,66,72 Local representation and champions from each relevant discipline (eg, critical care, physiatry, nursing, physical/occupational therapy, respiratory therapy) to create a vision and guiding coalition to prioritize early rehabilitation and mobilization is key to transforming ICU culture.⁶⁶

Coordination between members of the interdisciplinary team (bedside nurses, physical and respiratory therapists) is key in order to provide the most effective rehabilitation experience for mechanically ventilated patients. Mechanically ventilated patients may require increased F_IO2 and/or a change in ventilator mode (eg, from pressure support to pressure control or continuous mandatory ventilation) to facilitate tolerance of the planned activity. Given the amount of equipment (eg, portable monitor, oxygen tanks, infusion pumps, wheelchair) and personnel (eg, physical and respiratory therapist, nurse) required to ambulate mechanically ventilated patients, the use of portable ventilators may facilitate mobility sessions, particularly in space-limited settings.⁶⁵ Patients receiving supplemental oxygen at the onset of therapy may require the use of noninvasive ventilation to tolerate their sessions. Modifications to the patients' ventilator requirements can often be determined by careful monitoring of the patient's respiratory status during therapy, as well as from their tolerance of prior rehabilitation sessions.

Novel rehabilitation technology, such as neuromuscular electrical stimulation and cycle ergometry, may be useful adjunctive therapies within the context of an ICU early rehabilitation program.⁷⁴ Neuromuscular electrical stimulation induces passive contraction of muscles through low-voltage electrical impulses delivered through skin electrodes placed over target muscle groups (eg, quadriceps), and may be helpful in mitigating the development of muscle atrophy and weakness among high-risk critically ill patients.^75,76 Bedside cycle ergometry can provide muscle strength training and range of motion exercises for ICU patients who are either awake (active cycling) or sedated (passive cycling), and may also preserve muscle strength and function.⁷⁷ The role of these rehabilitation technologies in both the acute and chronic critically ill require confirmation in large, prospective clinical trials.