Oxygen Transport Deficits in Systemic Disease and Implications for Physical Therapy

The purposes of this article are to discuss the effects of some common systemic diseases on cardiopulmonary function and oxygen transport and to describe the implications for physical therapists. Pathology of every major organ system can manifest secondary effects on cardiopul- monary function and oxygen transport. Such effects are of consider- able clinical significance given that they can be life threatening and that physical therapy usually stresses the oxygen transport system. This article reviews the cardiopulmonary effects of hematologic, neuromus- cular, musculoskeletal, gastrointestinal, hepatic, renal, collagen vascu- lar and connective tissue, endocrine, and immunologic conditions. The cardiopulmonary manifestations of some common nutritional disorders (eg, obesity, anorexia nervosa) are also discussed. Physical therapists need to be able to anticipate, detect, and manage the cardiopulmonary manifestations of systemic disease given medical advances and the increasing number of patients with multisystem problems, the aging of the population, the expanding scope of physical therapy practice, and the increased professional and ethical responsi- bility associated with direct patient access. [Dean E. Oxygen transport deficits in systemic disease and implications for physical therapy. Phys Ther. 1997;77:187-202.1

Key Words: Cardiac, general; Oxygen transport; Pulmonary, general; Systemic conditions.

Elizabeth Dean

Physical Therapy . Volume 77 . Number 2 . February 1997

n addition to treating primary conditions of the heart and lungs, physical therapists treat patients with primary diagnoses of conditions that have sec- ondary cardiopulmonary complications. Although

these complications can be subtle, their consequences can be serious. The purposes of this article are to discuss the effects of some common systemic diseases on cardiopulmcl nary function and oxygen transport and to describe the implications for physical therapists with respect to assess- ment, treatment, and prevention. Compared with the oxygen transport deficits associated with primary cardicl pulmonary pathology, the secondary cardiopulmonary manifestations of systemic diseases are less well known. Pathology of every major organ system may have a second- ary effect on cardiopulmonary function and oxygen trans- port, such as impaired ventilation, perfusion, and ventilation-perfusion matching; reduced lung volumes, capacities, and flow rates; atelectasis; reduced surfactant production and distribution; impaired mucociliary trans- port; secretion accumulation; pulmonary aspiration; impaired lymphatic drainage; pulmonary edema; impaired coughing; respiratory muscle weakness or fatigue; hjpox- emia; dysrhythmias; hemodynamic instability; and mechan- ical encroachment on the heart.

In this article, the effects on the cardiopulmonary system of common hematologic, neuromuscular, musc~iloskel- etal, gastrointestinal, hepatic, renal, collagen vascular and connective tissue, endocrine, and immunologic conditions are considered. The cardiopulmonary mani- festations of some common nutritional disorders (eg, obesity, anorexia nervosa) are also considered. For each type of condition, the physical therapist must identify all the steps in the oxygen transport pathway that are affected so that treatment can be directed to the under- lying problem as much as possible (Figure).

Because impairment of oxygen transport can result from diseases other than cardiopulmonary conditions, physi- cal therapists in all specialties need expertise in antici- pating and detecting cardiopulmonary dysfunction in the absence of primary cardiopulmonary disease. Such information is essential in modifying treatment prescrip- tion, preventing complications, and establishing when a patient should be referred to another health care pro- fessional. Examples of such cases include:

an ll-year-old boy with a primary diagnosis of Down syndrome and a secondary diagnosis of atrioventricu- lar septa1 defect a 37-year-old woman with a primary diagnosis of scleroderma and a secondary diagnosis of restrictive lung disease a 75-year-old man with a primary diagnosis of right cerebrovascular accident and secondary alveolar hypoventilation (ie, reduced ventilation of the alveolar tissue of the lungs) a 42-year-old woman with a primary diagnosis of the late sequelae of poliomyelitis and secondary residual scoliosis and reduced endurance a 16-year-old girl with an anterior cruciate ligament repair and a secondary diagnosis of type I diabetes a 59-year-old woman with a primary diagnosis of rheumatoid arthritis and shortness of breath a 25-year-old man with a primary diagnosis of Crohn's disease and a secondary diagnosis of anemia

Hematologic Conditions

Pathop hysiology Hematologic conditions alter the oxygen-carryng capac- ity of the blood and the constituents, structure, consis- tency, and rheology of the Anemia associated with reduced hemoglobin and reduced oxygen-carrying capacity of the blood leads to increased demand on other steps in the oxygen transport pathway (eg, increased alveolar ventilation, increased cardiac output). Altered constituents, consistency, and rheology of the blood contribute to hypocoagulopathy, hypercoagulopa- thy, increased work of the heart and breathing, impaired tissue perfusion, and increased risk of thrombosis. Hypo- coagulopathy can lead to hemorrhage and edema, whereas hypercoagulopathy predisposes the patient to thrombus formation, emboli, and increased work of the heart and breathing."

Altered plasma proteins affect the oncotic pressure of the blood and interstitium, which is essential in preserv- ing compartmentalization of intravascular and extravas- cular fluid v01ume.~ Albumen is a primary plasma pro- tein that maintains circulatory oncotic pressure by retaining plasma in the circulation. Normally, minimal amounts of protein leak through the capillary mem- brane; thus, the oncotic pressure in the interstitial tissues is low. Excesses or deficits of blood protein constituents

E Dean. PhD, PT, is Associate Professor, School of Rehabilitation Sciences, University of British Columbia, 2211 Wesbrook Mall, Vancower, British Columbia, Canada V6T 123 (elizdeanQrehab.ubc.ca), and Clinical Associate, Physiotherapy Department, Royal

'0 m 2

Mitochondria

Heart AirwaysILungs

2 0 3 r -

Figure. The oxygen transport pathway, showing pulmonarycardiovascular-metabolic coupling that affects cellular respiration. 02=oxygen, C02=carbon dioxide, Vo2=02 uptake from the alveoli, Vco2=C02 output from the alveoli. (Modified from Wasserman K, Hansen JE, Sue DY, Whipp BJ. Principles of Exercise Testing and Interpretation. Philadelphia, Pa: Lea & Febiger; 1987.)

alter this important transcapillary fluid balance in all tissues of the body, which in turn may affect circulating blood volume.

Coagulopathies interfere with the nor~nal clotting mech- anisms of the blood. Both deficits and excesses of blood clotting factors are pathologic and interfere with oxygen transport." Deficits contribute to bleeding abnormalities and hemorrhage. Excesses contribute to abnormal clot- ting and obstruction of blood flow to vital organs, including the brain, heart, kidneys, and lungs, which in turn contributes to thromboemboli and tissue infarc- tion.3 Increased blood viscosity and increased biventricu- lar stroke work can result.

Pulmonary emboli resulting from blood clots are rela- tively common. Although frequently silent, there are three primary symptoms, namely, shortness of breath, pleuritic chest pain, and hemoptysis. Pulmonary emboli are life-,threatening and are managed medically with an aggressive course of thrombolytic and anticoagulant therapy."

Implications For Physical Therapy Management Heniatologic abnormalites require that the results of the patient's blood analysis and clotting factors be moni- tored so that physical therapy treatments can be modi- fied to minimize risks.

Patients with anemia fatigue easily; thus, treatments need to be modified accordingly. If exercise is indicated for a patient with anemia, pacing and training that distributes the intensity of the workload over time can be used to promote physiological recovery. Getting a patient mobile refers to exercise stimuli such as walking, transferring, standing, and chair and bed exercises that can be used to optimize ventilation, perfusion, and

ventilation-perfusion matching and to promote muco- ciliary transport. Mobilization often is prescribed in conjunction with a gravitational stimulus (ie, variants of the upright position) to elicit hemodynamic responses to gravity. Training in a progressive form involves alter- nating bouts of high-intensity exercise with bouts of either low-intensity exercise or rest. The patient's response to treatment is used as a guide to progress and modify treatments.

Patients with clotting abnormalities are prone to emboli or bleeding.4 The dangers of clotting include arterial occlusion and thromboemboli becoming lodged in arteries supplying vital organs (eg, brain, kidney, lungs, heart).Wommon causes of abnormal blood clotting are restricted mobility and an increase in red blood cells, which increase blood viscosity arid work of the heart.' Most clots originate in the deep veins of the legs.7 Although the degree to which movement can dislodge a blood clot has not been established conclusively, the presence of clots usually rules out movement in the affected limbs.

Lower-extremity exercises, compression stockings, and intermittent pneumatic compression devices are used to prevent thrombus formation in the legs, particularly in patients following surgery and patients who have had trauma. Compression stockings prevent peripheral pool- ing of the blood and augment venous return. Specially designed stockings used with a pneumatic compression device are programmed to inflate to a certain pressure and then deflate several times a minute, thereby simu- lating the normal action of the muscle pump in the legs.8 Stockings are applied with special attention to unifor- mity of pressure along the leg. They should be inspected for wrinkles, and they should be removed frequently for short periods (10 minutes) and reapplied. Bleeding

Physical Therapy . Volume 77 . Number 2 . February 1997 Dean . 189

secondary to hypocoagulopathy tends to occur within major organs and around areas of stress (eg, joints). Therapists need to consider the relative risk of move- ment and activity with respect to increasing bleeding versus the negative sequelae of restricted mobility and recumbency on oxygen transport. Gentle mobilization and modified exercise are usually resumed when the thrombi have resolved, based on ultrasound and other clinical studies.

Neuromuscular Conditions

Pathophysiology The type and severity of oxygen transport deficits result- ing from neurological lesions depend on the type and distribution of the lesions."-" Neuromuscular condi- tions that have been associated with cardiopulmonary manifestations include cerebral lesions (eg, stroke, cere- bral palsy, tumors, brain injuries), disorders of the spinal cord (eg, poliomyelitis, spinal cord injury), demyelina- tion diseases (eg, Guillain-Barri. syndrome, amyotrophic lateral sclerosis, multiple sclerosis), pathology of the neuromuscular junction (eg, myasthenia gravis) , and failure of the contractile mechanism of muscle (eg, myopathies).12 Central lesions associated with cerebral palsy and stroke tend to have peripheral effects (eg, altered tone of the muscles of the chest wall and chest wall deformity).

In patients with cerebral palsy, breathing can be episodic and dysrhythmic, and chest wall mokement can be compromised by spasticity and rigidity.' Reduced capac- itv to manage ainvay secretions and saliva makes these patients prone to aspiration. In addition, patients with cerebral palsy may be deconditioned due to restricted movement. Spasticity and abnormal movement patterns increase the energy cost of moving and ambulating. In the acute stage of stroke, chest wall movement and activity of the inspiratory muscles on the paralyzed side are r e d u ~ e d . ' ~ The effects of restricted movement and spasticity can contribute to the same problems observed in patients with cerebral palsy and similar neuromuscu- lar conditions.

The cardiopulmonary manifestations of spinal cord inju- ries depend on the level of the lesion. Although cervical lesions involving C-3 through C-5 result in diaphrag- matic paresis, impaired accessory muscle function, and potential ventilator dependence, involvement of lower spinal segments also affects respiratory function.14 The thoracic spinal nerves supply the intercostal, oblique, abdominal, and paravertebral rnusc le~ . '~ The lumbar spinal nerves supply the paravertebral muscles of that region and quadratus lumborum muscle, and the sacral nerves supply the paravertebral muscles of the lower- most portion of the back.'-' Residual volume is usually

increased in patients with spinal cord lesions, and inspiratory and expiratory capacities are decreased.I4 Ventilation of the lung bases is also diminished.'? Because of the loss of thoracic and abdominal muscle function in high lesions, normal position-induced changes in respiratory function can be accentuated with changes in body p o s i t i ~ n . ' ~ ~ ~ ~ In addition, patients with spinal cord injuries are hemodynamically unstable ini- tially due to the effects of spinal shock and secondary abnormal fluid shifts and hypotension. Even though these patients tend to be younger, dysrhythmias can be precipitated by hypoxemia in the absence of primary heart disease.

Anterior horn cell diseases such as poliomyelitis may result in peripheral and central lesions, either at onset or several decades later, that negatively affect cardiopulmo- nary function and gas exchange.IR Common problems include shortness of breath, reduced endurance, chok- ing and swallowing problems, impaired mucociliary transport, ineffective coughing, risk of aspiration, and sleep apnea.'"

Pathologies of muscle such as occur with muscular dystrophy, amyotrophic lateral sclerosis, and dystonias are progressive and can compromise ventilation due to hjpotonia and consequent respiratory muscle dysfunc- tion.'" Hypotonia of the upper airway structures and weak abdominal muscle strength contribute to choking, impaired swallowing, and aspiration.

Depending on the level, distribution, and severity of involvement, neuromuscular disorders may reduce respi- ratory muscle strength and endurance, inspiratory and expiratory pressures, lung volumes, and flow rates and may contribute to hypoventilation, ainvay closure, hypoxemia, and hypercapnia.

implications for Physical Therapy Management The primary cardiopulmonary problems in patients with neuromuscular dysfunction include alveolar hypoventi- lation, atelectasis, impaired mucociliary transport, secretion accumulation, aspiration, impaired ventilation- perfusion matching, and impaired coughing effective- ness. Conditions associated with autonomic nervous svstem dysfunction contribute to abnormal fluid distri- bution, relative hypovolemia, and orthostatic hypoten- sion.'l In addition, these patients often have minimal aerobic reserve capacitv because of restricted mobility.

Patients who have autonomic nervous system dysfunc- tion warrant stringent monitoring because they are prone to hemodynamic instability. Although tilt tables may have a role in this process, they may contribute to orthostatic intolerance because the patient cannot

190 . Dean Physical Therapy . Volume 77 . Number 2 . February 1997

recruit the pumping action of the muscles of the legs even if the legs are not paralyzed.

Interventions such as mobilization and body positioning (particularly in an upright position), breathing control and coughing maneuvers, and postural drainage are prescribed to enhance alveolar ventilation, resolve atel- ectasis, enhance ventilation-perfusion matching, opti- mize mucociliary transport, and maximize coughing effectiveness in the patient with neuromuscular d y ~ f u n c t i o n . ~ ~

Optimizing alveolar ventilation is a primary goal for patients with progressive neuromuscular dysfunction. End-tidal carbon dioxide, arterial saturation, and the sensation of dyspnea are important indicators of hyp~vent i la t ion .~ Glossopharyngeal breathing, which has been used extensively by patients with poliomyelitis to maximize vital capacity and inspiratory reserve, may have a role in the management of patients with other types of neuromuscular deficits.24

*Grway protection is a priority to avoid aspiration. The patient should be instructed in deep breathing and supported coughing maneuvers in conjunction with mobilization and body positioning. Specific supported coughing interventions include costophrenic-assisted coughing, Heimlich-type assist, abdominal thrust, and chest wall compression manei~vers .?~~"jIn addition, coughing can be self-assisted, as well as coordinated with flexion and extension movements of the trunk in differ- ent body positions. The patient inspires during exten- sion and attempts to forcefully exhale during flexion movements. These maneuvers are coordinated with mobilization and body positions (eg, upright, hands- and-knees, and semirecumbent positions) to enhance respiratory muscle eff~ciency and expiratory flow rates. Patients who are at risk of aspiration and their families should be instructed in the Heimlich maneuver, an emergency procedure to relieve upper airway

Although the supine and Trendelenburg positions reduce the risk of passive regurgitation, these positions promote aspiration of pharyngeal contents. To prevent both regurgitation and aspiration, the optimal position is the lateral Trendelenburg po~i t ion . '~ This position, however, may be contraindicated for patients with increased intracranial pressure or gastric dysfunction. Regardless of body position, patients are particularly prone to aspiration when on sedatkes, tranquilizers, narcotics, and muscle relaxants and when they are under the influence of anesthesia." These agents blunt the airway reflexes and prolong gastric emptying.

Patients should be encouraged to identify situations and foods that contribute to choking or impaired swallowing and to avoid them as much as possible. Eating during social situations, for example, when the patient may be talking and laughing, increases the risk of aspiration; thus, patients should be instructed to be particularly attentive at these times.

In cases when the patient is unable to remove airway secretions effectively with conservative measures, suc- tioning may be indicated. The negative effects of suc- tioning on oxygen transport, however, have been well documented.'" If mechanically ventilated, the patient is hyperventilated and hyperoxygenated prior to suction- ing if she or he is likely to become desaturated. The procedure is performed quickly and with adequate rest periods between passes of the suction catheter. The patient's respirations and hernodynamic responses to suctioning are monitored.30

Altered function of skeletal muscle, including the respi- ratory muscles, compromises ventilation. Excessive or reduced activity impairs breathing efficiency and increases the work of breathing. Reduced activity of the pharyngeal and laryngeal muscles that protect the upper airway predisposes the patient to obstructive sleep apnea and a~piration.'~,"'

Generalized or local muscle weakness or paresis has particular implications for physical therapy manage- ment. In patients with weakness and deformity resulting from long-term disability (eg, poliomyelitis, spinal cord injury), viable muscle compensates for nonworking motor units or entire muscles. These muscles incur abuse secondary to overuse." In patients with a history of poliomyelitis, for example, reduction in the motor unit pool results in excessive demands being placed on remaining motor units.34 The remaining motor units are chronically overworked and d o not benefit from bouts of rest, in contrast to normal motor units.35 Over time, age-related decrement in motor units contributes to a disproportionate loss of function." Increasing exercise load on these muscles, therefore, can contribute to further deterioration and loss of function.g7 Thus, exer- cise (both general aerobic conditioning and individual muscle training) should be prescribed to achieve goals without inflicting further damage and loss of function. Weak muscles that respond to strengthening stimuli need to be distinguished from fatigued muscles that need to rest.

Muscular weakness or paresis of the diaphragm and other respiratory muscles is of considerable clinical importance. Paresis of these muscles impairs ventilation and gas exchange. The corresponding increase in the work of breathing is superimposed on an already com-

Physical Therapy . Volume 77 . Number 2 . February 1997 Dean. 191

promised oxygen transport delivery system. Comparable to peripheral muscles, weak respiratory muscles respond to resistive muscle trainingm; however, the function of fatigued respiratory muscles will deteriorate? To ensure that the appropriate treatment is prescribed, weak ven- tilatory muscles must be distinguished from fatigued ventilatory muscle^.^^^^^^' Optimizing respiratory muscle strength and endurance with mobilization and exercise should be a priority for patients with chronic lung disease, and specific ventilatory muscle training may augment this effect in some patients4"

Respiraton muscle fatigue is assessed by evaluating force development in response to stimulation over time and fatigue patterns, relaxation rates, and electromyographic activity." The differentiation of weakness and fatigue of ventilatory muscles is complicated when they ~0exist. l :~ For routine clinical purposes, distinguishing weakness and fatigue is based on history, assessment, and the patient's response to a trial of inspiratory muscle train- ing or rest. Patients who deteriorate or fail to demon- strate an improvement in ventilatory muscle strength with training most likely have fatigued respiratory mus- cles. These ventilatory muscles require rest rather than training. The respiratory muscles of patients who have difficulty weaning from mechanical ventilation may also require rest. Alternatively, inspiratory muscle training may augment weaning from mechanical ventilation in some patients.

Patients with spinal cord injuries often show unique breathing patterns during the first year postinjury.14 Initially, respiratory function is impaired when a person sits compared with when the person is positioned supine. Ventilatory adaptation to the sitting position may reflect improvements in accessory muscle function, chest wall stability, thoracoabdominal coupling, or some com- bination of these compensations. Despite these compen- sations, patients with chronic cervical spinal cord inju- ries tend to have rapid shallow breathing.45 Patients with high cervical lesions with partial or complete sparing of spinal nemes C3 through C5 have impaired ventilatory reserve due to partial innervation of the respiratory muscles. Training of the ventilatory muscles using inspiratory resistive loading devices has a role in improv- ing ventilatory muscle strength and endurance, which in turn can increase exercise t ~ l e r a n c e . ~

Patients with progressive neuromuscular diseases (eg, muscular dystrophy, multiple sclerosis) are living longer. These patients are at risk of developing respiratory muscle weakness as the disease progresses. Nighttime ventilation (eg, continuous positive airway pressure delivered by face mask) has been one means of provid- ing intermittent rest to the respiratory muscles. A major priority for these patients is to avoid or delay the need

for intubation and mechanical ventilation, particularly invasive mechanical ventilation. Patients with progressive neurornuscular diseases have a poor prognosis for being weaned from invasive mechanical ent ti la ti on.^"^^

The aerobic capacity of patients with neuromuscular dysfiinction may be variable, as has been reported for patients with a history of po l i~nlye l i t i s .~~ Physical disabil- ity reduces activity and may therefore reduce aerobic capacity due to increased exercise stress and energy d e m a i ~ d . ~ V n other cases, disability may provide an aerobic stimulus that enhances aerobic capacity. The overall aerobic capacity of patients with neuromuscular dysfurlction should be assessed to determine (1) whether cardiopulmonary conditioning is indicated, (2 ) whether the patient's disability is contributing to over- training and overuse, and (3) whether preventive mea- sures (eg, flu shots, cessation of smoking, avoidance of secondhand smoke and other poor air quality environ- ments, minimizing contact with persons with respiratory infections) are indicated. Although cardiopulmonary conditioning may also be indicated, exercises should be modified to adjust for the loss of physiologic reserve capacity and to avoid musculoskeletal strain, overuse, and excessive e~e r t i on .~Wommensura t e with the type and severity of the disease, cardiopi~lmonary condition- ing is prescribed to optimize the efficiency of the oxygen transport system. These esercise-induced effects may include either central or peripheral effects, or both (eg, the heart and lungs improve their efficiency at pumping and oxygenating blood, collateral vascularization is increased to optimize blood-flow distribution through the muscles, muscle oxidative enzymes and myoglobin concentrations are increased to maximize peripheral extraction of oxygen at the tissue level) .4"50

Another consideration in the management of the patient with neurornuscular dysfunction is movement economy. i2fouerr~ent economy refers to the metabolic effi- ciency of energy expenditure during movement. Nor- mally, movement is performed such that the metabolic cost is minimized and energy is not wasted. Patients with abnormal asymmetric muscle function, particularly of the postural muscles, and patients with musculoskeletal deformities (structural or functional) expend more energy during activities and locomotion.x~5~ This increased metabolic demand imposes an increased load on the patient's oxygen transport system. Thus, to min- imize excessive energy expenditure, treatment should be directed at minimizing these effects and optimizing the efficient use of energ). using postilral correction exer- cises; proper biomechanics and postural alignment; gait education; prescription of walking aids, devices, and lightweight footwear; and activity-pacing and energy- corlservation interventions. Orthotic devices may reduce

192 . Dean Physical Therapy . Volume 77 . Number 2 . February 1997

this energy cost by normalizing gait and reducing exces- sive movements and ~ w a y : ~ ~ , ~ ~

The prescription of activity-pacing and energyxonservation interventions for patients with neuromuscular dysfunction has not been well studied or defined." For the patient with low functional work capacity, paced training is one of the most justifiable modes of training of the aerobic system, given the enhanced recovery and greater work capacity associated with it.55-57 Such training promotes bouts of relatively high- to low-intensity activity or of low-intensity actiklty to rest over a prolonged period of time. Thus, the amount of muscular work that can be achieved with paced training is greater than the amount of muscular work that can be achieved in a single bout of activity or exercise. In addition, fatigue can be minimized by promoting degrada- tion of lactate with reduced intensities of exercise, and the rate and quality of recovery can be enhan~ed .~"

The approach to the management of some patients with neuromuscular conditions is becoming increasingly aggressive. Malouin et for example, advocate an intensive task-oriented gait training program in the early stages of recovery from stroke. Strokes primarily affect older adults, who have a high incidence of coronary artery disease, hypertension, and d~srhythrn ias .~Vn addition., such individuals may have been deconditioned before their strokes, or they may become deconditioned after their strokes. Given these considerations, patients being treated following strokes should be monitored with respect to their cardiopulmonary and cardiovascu- lar status (eg, heart rate, blood pressure, rate-pressure product, electrocardiographic activity, breathing pat- tern, dyspnea, chest discomfort, exertion). Changes in these responses should lead therapists to make appro- priate treatment modifications and to ensure that the physiologic stress imposed on patients is safe and not excessive.

Musculoskeletal Conditions

Pathoph,~siology Respiratory insufficiency can result from abnormalities of the chest wall secondary to congenital deformities, acquired diseases, and t r a u m a ~ . ~ ~ ~ ~ W e f o r m i t y of the chest wall reduces the mobility of the thorax and thereby increases the work of breathing." Shallow, rapid breath- ing often results, which increases minute ventilation at the expense of alveolar ventilation. Examples of chronic deformities that impinge on cardiopulmonary function include kyphosis, kyphoscoliosis, tuberculous osteomy- elitis, and ankylosing sp~ndylitis.~" Other causes of chest wall defbrmity include traumatic injury of the vertebral column, ribs, and sternum. Age-related changes of the lungs and chest wall also contribute to chest wall defor-

mity, displacement of the diaphragm and abdominal muscles, and altered respiratory mechanics." The effects of these changes on gas exchange are accentu- ated because of the age-related decrease in arterial oxygen tension and gas exchange.

Normal cardiopulmonary function and gas exchange depend on the normal configuration of the cardiopul- monary anatomy. Asymmetry of the chest wall, for exam- ple, interferes with the regional gradients of ventilation and perfusion. Physiologic dead space and shunt are exaggerated, leading to hypoxemia and hypercapnia. Severe chest wall deformity and reduced adherence and ventilatory efficiency can result in hypoxemia, hypercap- nia, and respiratory acidosis." Chronic hypoxemia leads to hypoxic pulmonary vasoconstriction, pulmonary hypertension, and right heart failure.

Chronic chest wall deformities often result from kypho- sis, kyphoscoliosis, ankylosing spondylitis, chest wall hyperinflation, and flattening of the diaphragm second- ary to chronic airflow limitation, and protrusion and retraction of the sternum (pigeon breast and funnel breast). Postthoracotomy deformity may be encountered in patients who had thoracoplasty surgery for tuberculo- sis several decades ago.

Chest wall trauma is a primary cause of acute chest wall deformity. This injury is often complicated by heart and lung contusions, bleeding, and internal injuries. Multi- ple rib fractures, specifically, two or more fractures in two or more places, can lead to a flail segment or a flail chest. This flail segment moves paradoxically on breath- ing." Impaired chest wall stability and motion are asso- ciated with encroachment and atelectasis of the under- lying airways and lung parenchyma, which contributes to alveolar hypoventilation and impaired mucociliary trans- port." In addition, pain from fractured ribs limits deep breathing and coughing even when the chest wall is intact. If pharmacologic analgesia interferes with patient arousal and capacity to cooperate with treatment, the physician needs to be informed and alternative analgesia needs to be considered.

implications for Physical Therapy Management The management of chest wall deformities includes optimization of postural and biomechanical alignment; thoracic mobilization; and minimization of the neuro- muscular, musculoskeletal, and cardiopulmonary sequelae. Range-of-motion exercises, stretching, and strengthening of the chest wall muscles are often pre- scribed. Severe deformity can lead to respiratory insuffi- ciency and, in extreme cases, to respiratory failure. In acute cases, musculoskeletal deformities restrict mobili- zation and body positioning. Restricted mobility and reduced positioning alternatives threaten oxygen trans-

Physical Therapy . Volume 77 . Number 2 . February 1997 Dean. 193

port by removing the normal physiologic "stir-up" that is associated with normal movement and changes in posi- tion. Alveolar ventilation is reduced, tidal volume and vital capacity are reduced, and the work of breathing is increased. In chronic cases, patients with deformities, particularly spinal abnormalities, may be less able to engage in physical activities; thus, they are prone to deconditioning. In addition, the energy cost of move- ment may be increased due to spinal malalignment, increased postural sway, and gait deviation.

Management of the cardiopulmonary complications of acute rib fractures primarily involves pain control. With- out optimal pain control, the patient's ability to cooper- ate fully with treatment is compromised. Varied body positions and frequent changes in body position that simulate position changes that normally occur are necessary to ~naximize effective alveolar ventilation, ventilation-perfusion matching and gas exchange, sur- factant production and distribution, and mucociliary transport.":' Interventions to control pain include relax- ation procedures, strategic pacing and selection of posi- tions and movement, and transcutaneous electrical nerve stimulation. In addition, pharmacologic manage- ment may include a range of medications. Medications with minimal systemic effects (as opposed to medica- tions with greater systemic effects, such as narcotic analgesics), are usually preferred, whenever possible, to ensure that the patient can cooperate fully with the therapist. Epidural analgesia is often favored to reduce many of the systemic effects of analgesic medications, particularly narcotics." Physical therapy treatments should be coordinated with the patient's analgesia schedule. Mobilization and body positioning coordi- nated with breathing control and coughing maneuvers are the mainstays of treatment.25~~~96b

Gastrointestinal, Hepatic, and Renal Conditions

Pa thophysiology Although the cardiopulmonary system is anatomically distinct from the gastrointestinal, hepatic, and renal systems, these organ systems are functionally integrated with the heart and lungs. Thus, primary pathology affecting the gastrointestinal tract, liver, and kidneys can lead to cardiopulmonary manifestations and pose a threat to oxygen transport.

Despite the general anatomic distinction between the gastrointestinal and cardiopulmonary systems, there are numerous lymphatic channels between the abdominal and thoracic cavities.20 In addition, mass and volume changes in the abdominal cavity alter thoracoabdominal interaction and the relative position of the diaphragm, which separates the two cavities. These effects emanate

from abnormal fluid dynamics within the gastrointesti- nal system. Coughing and bronchospasm can result from a vagally mediated reflex secondary to refluxed acid contents in the esophagus." Reflux is potentiated in obese patients with increased intra-abdominal pressure68 and in immature infants. Reflux is also potentiated in smokers and heavy alcohol consumers, in whom esoph- ageal sphincter function is reduced.

Aspiration of foreign substances into the lungs is associ- ated with numerous conditions, such as decreased levels of consciousness and reduced pharyngeal, esophageal, and gastrointestinal m0tility.~,7'j In addition, gastro- esophageal reflux is associated with iatrogenic factors, including intubation, tracheostomy, anesthesia, and nasogastric tubes. Chronic bronchitis, asthma, hemopty- sis, coughing, and pulmonary fibrosis have been associ- ated with r e f l ~ x . ~ l

Cardiopulmonary dysfunction (eg, impaired coughing, increased pulmonary markings on chest roentgeno- grams, submucosal inflammatory changes) can be a manifestation of ulcerative colitis.72 Asymptomatic patients with Croh~l's disease and normal chest roent- genograms have been reported to have reduced forced vital capacity and diffusing capacity.79

Hypoxemia is common in patients with chronic liver disease.74 Several mechanisms appear to be responsi- ble.75-77 Pulmonary closing volume is increased, result- ing in areas of low ventilation-perfusion matching. Ascites increases intra-abdominal pressure, which con- tributes to increased pulmonary closing volume (ie, closure of the dependent airways and alveoli) .78 A diffu- sion defect has also been implicated. Arterial partial pressure of oxygen is correspondingly reduced, and arterial desaturation is potentiated; these effects are accentuated with recumbency. The rich lymphatic drain- age system of the gastrointestinal tract is overwhelmed, which creates back pressure for lymphatic drainage from the lungs and may contribute to pleural effusions. Dif- fusing capacity is reduced, and the alveolar-arterial oxy- gen difference is increased.

Chronic liver disease is also associated with intrapulmo- nary shunting; anastomoses connecting the portal, medi- astinal, and pulmonary venous beds; and reduced pul- monary vascular function. Pulmonary edema occurs secondary to hepatic encephalopathy and cerebral ede- ma.79 Vascular changes in the lungs have been well documented in patients with chronic liver disease and reflect the importance of the liver in the control of vasoactive substances that regulate normal fluid balance, including lung fluids. The major pulmonary abnormal- ity, however, is intrapulmonary shunting secondary to pulmonary vascular dilatation." Chest roentgenography

194 . Dean Physical Therapy . Volume 7 7 . Number 2 . February 1997

shows bibasilar interstitial infiltrates. Pulmonary vascular dilatation contributes to hypoxemia, which can be wors- ened when the patient assumes an upright position (ie, orthodeoxia). Dyspnea occurring in an upright position and relieved with recumbency is termed plutypnea (unlike orthopnea, in which dyspnea occurs with recum- bency and is relieved by assuming an upright position).

Parenchymal changes associated with chronic liver dis- ease can be associated with infiltrates, obstructive airflow limitation, and the secondary effects of ascites and pleural effusions on lung volumes. Oliguric renal failure is also seen in severe liver disease and is known as hepatorenal syndrome. Fluid overload and increased peri- bronchial fluid contribute to airway closure. After dialy- sis, a fall in body weight correlates with reduced airway c l o ~ u r e . ~ In addition, vital capacity increases, residual volume is reduced, and forced expiratory flow rates increa~e.~ ' Acute fulminant liver failure is associated with multisystemic complications and high mortality. Cerebral edema is a lethal complication that leads to respiratory depression, cardiorespiratory arrest, and death. Noncardiogenic pulmonary edema is also a com- mon complication, necessitating positive end-expiratory pressure during mechanical ventilation and pulmonary artery pressure monitoring.

Secondary cardiopulmonary complications of renal dis- orders are termed pul.mona?y-renal syntiromes. Some com- mon features of these syndromes include alveolar hem- orrhage, which leads to an increased diffusing capacity, interstitial and alveolar inflammation, pulmonary vascu- lar changes, and immunological changes.H2

Patients with liver disease are prone to hypoxemia, airflow obstruction, and, in severe cases, cardiac arrest. These f;~ctors can indicate the need for intubation and mechanical ventilation. Because distress can be reduced with supplemental oxygen, the pathophysiologic defect has been considered a diffusion-perfusion defect rather than an anatomical sh~nt.~"xygenation should be monitored carefully during treatment, given that hypox- emia and dyspnea can be worsened in patients when they assume an upright position from a supine position or when they change body positions.

The kidneys have an essential role in the production and regulation of certain humoral regulators of metabolism and of hemodynamic and fluid balance.x4 These organs have a major effect on oxygen t r a n ~ p o r t . ~ ~ Thus, pathol- ogy of the kidneys affects these life-sustaining processes.

implications for Physical Therapy Management With respect to gastrointestinal conditions, reflux and aspiration are largely preventable. Although head-up positions minimize reflux, they can promote aspiration

of pharyngeal contents. Side-lying positions prevent regurgitation and a ~ p i r a t i o n . ~ ~ These positions promote oropharyngeal accumulation of secretions and ease of suctioning. upright positions minimize the risk of aspi- ration in part because they reduce intra-abdominal pressure. Signs and symptoms of aspiration include acute bronchospasm, increased airway resistance, and dyspnea. Ensuing ventilation-perfusion mismatch and shunting lead to arterial hypoxemia. Positioning patients with gastrointestinal dysfunction for breathing control and coughing maneuvers requires special attention to minimize the risk of aspiration.

Patients with gastrointestinal dysfunction are at risk for impaired metabolism due to their medications being evacuated, not being absorbed properly, or both. The responses of these patients to medications will therefore be less predictable, which may also affect the response to treatment. Monitoring of gastrointestinal status and medication responses is essential in conjunction with the patient's response to physical therapy.

Because of the fundamental role of the kidneys in fluid and electrolyte balance, the fluid status of the patient and his or her ability to maintain plasma volume and regulate fluid balance at rest and during physical exer- tion must be monitored by clinical indices of hydration and urinary output. Associated electrolyte changes must also be observed. Electrolyte changes will affect excitable tissues (eg, cardiac muscle, smooth muscle, nervous tissue) as well as homeostasis. Renal insufficiency leads to extracellular volume excess, which ultimately affects the electrolyte concentrations in the blood. Severe hyperpotassemia, for example, occurs with anuria or oliguria."(j

The kidneys have a primary role in the production and regulation of renin and the synthesis of angiotensin, a potent vasoactive mediator. Thus, hemody~~amic lability, particularly abnormal blood pressure control, may result from kidney disease. Blood pressure and heart rate should be closely monitored at rest and during treat- ment to ensure that hemodynamic responses are not attenuated or inappropriate. Erythropoietin, which is responsible for stimulating red blood cell production from bone marrow, is primarily secreted by the kidneys; thus, anemia is a common complication of renal dys- function. Patients with anemia are readily fatigued. Treatments and activity, therefore, should be paced to minimize fatigue.

Physical Therapy . Volume 77 . Number 2 . February 1997 Dean . 195

Collagen Vascular and Connective Tissue Conditions

Pathop hys iology The collagen vascular and connective tissue diseases (eg, systemic lupus erythematosus, scleroderma, rheumatoid arthritis) are characterized by inflammation of the con- nective t i s s ~ e . ~ ~ ~ ~ ~ Collagen and connective tissue are constituents of most organs; thus, chronic inflammation and related injury can irnpair organ function systemi- cally. In many patients with systemic lupus erythemato- sus and scleroderma, cardiopulmonary manifestations are apparent.sg Oxygen transport is compromised by involvement of the airways, lungs, alveolar capillary membrane, chest wall, heart, and va~cu la tu re .~~ Connec- tive tissue changes and fibrosis of the structures of the chest wall and within the lung parenchyma result in a loss of alveolar tissue, reduced diffusing capacity, reduced lung volumes, and reduced chest wall expan- sion."' Lung compliance is reduced, and the work of breathing is increased. This "shrinking lung syndrome" associated with connective tissue conditions may predis- pose the patient to ventilatory in~ufficiency.~' Both the electrical and mechanical behaviors of the heart can be compromised, leading to impaired electromechanical coupling and cardiac pumping insufficiency." Reduced cardiac output and hypoxemia may ensue. Oxygen extraction at the tissue level may also be affected by the presence of increased connective tissue.

Patients with rheumatoid arthritis may have various types of associated cardiopulmonary pathology. Common pul- monary pathologies include diffuse interstitial pulmo- nary fibrosis, reduced diff~ising capacity, bronchiolitis, pleuritis, pulmonary effusions, and airflow ob~truction."~ The restrictive pattern of lung disease associated with rheumatoid arthritis may reflect an increase in collage- n a ~ e . ~ ~ With respect to cardiac pathology, pericarditis and pericardial effusion with associated electrocardio- graphic changes are not uncommon findings."xQ7 Con- strictive pericarditis may result from acute pericarditis; however, this condition may occur with no documented history of pe r i ca rd i t i~ .~~

implications for Physical Therapy Management The relative involvement of the heart, lungs, kidneys, and blood vessels for a patient with collagen vascular or connective tissue disease must be established. The effec- tiveness of lymphatic drainage and its role in fluid balance regulation may also be affected. Treatment is directed at maximizing alveolar volume, promoting mucociliary transport, optimizing ventilation-perfusion matching, reducing undue work of the heart and of breathing, and optimizing circulatory fluid balance and distribution." Body positioning is prescribed to manip- ulate the intrapleural pressure gradient, and thus the

alveolar volume, as well as the distributions of ventilation and perfusion and gas exchange. Body positioning also promotes lymphatic drainage. Breathing control and coughing maneuvers are coupled with body positioning to augment inspiratory volumes, flow rates, and muco- ciliary transport and to reduce airway resistance. Body positioning, specifically the upright position, is also prescribed to optimize circulatory fluid volume and to reduce the work of the heart.

General body conditioning is a priority for patients with collagen vascular or connective tissue conditions to maximize the efficiency of the oxygen transport system by exploiting the reserve of the unaffected steps in the pathway, thereby minimizing undue increases in the work of breathing and of the heart. Optimal cardiopul- monary conditioning is a priority to reduce the effects of associated cardiopulmonary manifestations of the colla- gen vascular and connective tissue diseases. The exercise prescription is based on each patient's multiple prob- lems, limitations, and goals.

Endocrine and Metabolic Conditions

Pathophysiology Endocrine and metabolic disorders, such as disorders of the thyroid gland, pancreas (diabetes mellitus), and adrenal glands, can adversely affect cardiopulmonary function and oxygen t r a n s p ~ r t . ~ . ~ ~ ~ ' Thyroid hormone has an important role in the drive to breathe and surfactant synthesis. Hypothyroidism contributes to obstructive sleep apnea, pleural effusions secondary to altered capillary membrane fluid balance, and pericar- dial effusions. Muscle weakness associated with hypothy- roidism leads to reduced vital capacity and to reduced inspiratory and expiratory pressures. Hyperthyroidism increases the cellular metabolic rate, thus increasing oxygen consumption and carbon dioxide production.

Patients with diabetes are prone to cardiopulmonary complications such as aspiration, respiratory infections, reduced sensation of respiratory loading, and micro- angi0pathy.l~l,~~2 Late complications include autonomic neuropathy, peripheral vascular disease, cardiomyopa- thy, and renal i n su f f i~ i ency . '~~u tonomic neuropathy affects vagal activity and airway function. Ischemic heart disease, which is accelerated in patients with diabetes, and cardiomyopathies are common and may lead to congestive heart failure, cardiogenic pulmonary edema, and renal insufficiency. Peripheral vascular disease may result in tissue ischemia, necrosis, and lower-extremity amputation.

Although primary adrenal insufficiency is rare, the indi- rect effects of pathology, illness, medications, and arousal are clinically i m p ~ r t a n t . ~ The primary cate-

196 . Dean Physical Therapy . Volume 77 . Number 2 . February 1997

cholamines, norepinephrine and epinephrine, are the two principal vasoactive humoral transmitters in the body. The inhibition and facilitation of the release of these essential transmitters affect airway smooth muscle activity and cardiac activity (at rest or during exercise) and contribute to the regulation of vascular smooth niuscle activity for regulation of peripheral blood flow for blood pressure control, tissue nutrition, and therm~regulation.~

Implications for Physical Therapy Management Altered metabolic and endocrine function requires med- ical attention, iisually in the form of pharmacologic support. The effectiveness of this support and whether deficits have been remediated determine the modifica- tions needed in physical therapy treatments.

Physical therapists may be consulted to prescribe exer- cise for persons with insulin-dependent diabetes to adjust insulin administration, help minimize or elimi- nate pharmacologic support, and maximize overall fit- ness and well being.Io4 Exercise is known to increase cellular insulin sensitivity, which may reduce or even eliminate the need for insulin or other medications for some individuals with type I1 diabetes.Iog In addition, exercise increases the efficiency of the oxygen transport system and cellular respiration in patients with diabe- tes.50,Y04 The improved aerobic capacity and health ben- efits of exercise, along with optimal nutrition (ie, low-fat, low-sugar, complex carbohydrate, and high-fiber diet) and medical management, may minimize the devastat- ing long-term multisystemic effects of diabetes and thus reduce the morbidity and mortality associated with this condition.

immunological Conditions

Pahophysiology Both congenital immunodeficiency and acquired immu- nodeficiency can lead to cardiopulmonary compromise. Inflammation and infection associated with immuno- deficiency are the common primary pathophysiological problem^.^^"'^)^ Acquired immunodeficiency syndrome (.4IDS) is a disorder of cell-mediated imrriunity, which leads to lymphocyte death. Pneumocystis carinii pneu- monia is the leading pulmonary infection associated with AIDS."'"

implications for Physical Therapy Management A primary goal of physical therapy in the management of patients who are immunocompromised is infection con- trol. The primary means of controlling infection is hygienic practices, including hand washing, gloving, masking, and gowning as required. Pulmonary compli- cations can be anticipated in these patient~.~"Vatients with pulmonary coinplications secondary to being

imm~~nocompromised have reduced alveolar ventila- tion, are prone to impaired mucociliary transport, have poor cough reflexes and an inability to cough effectively, and are prone to pulmonary and other opportunistic infections. In addition, these patients are often debili- tated and easily fatigued. In extreme cases (eg, end-stage AIDS), the patient may have considerable pain. Fre- quent and judicious mobilization and body positior~ing enhance gas e ~ c h a n g e ~ ~ ~ ) , ~ ~ ~ and promote patient com- fort and rr~aintenance of strength. If pneumonia devel- ops, breathing control and coughing maneuvers may be indicated. Postural drainage may be required for some patients. If suctioning is indicated, strict procedures are used to minimize the introduction or spread of infec- tious microorganis~l~s.

Physical activity is known to have beneficial effects on immunity in the healthy individual."' Thus, mobiliza- tion that is prescribed commensurate with the patient's overall status may augment irr~munologic function. Mobilization for its additional immunoprotective effects is a controversial approach, and further investigation is needed, particularly in the management of patients who are severely ill and immunocompromised.

Nutritional Disorders

Pathop hys iology Obesity contributes to deficits in oxygen transport and impaired gas e x ~ h a n g e . " ~ The degree of severity of oxygen transport deficit is commensurate with the indi- vidual's body weight and level of deconditioning. Defi- cits include alveolar hypoventilation due to the increased mass of the chest wall and abdomen and the increased energy required to displace that mass during respiration, systemic and pulmonary hypertension, increased intra-abdomiilal Inass and pressure, impaired diaphragmatic excursion, cardiomegaly and displace- ment of the heart and lungs within the thoracic cavity, axis deviation of the heart, and dysrhythmia~.I*,~l~ Weak- ness and laxity of the oropharyngeal and hypopharyn- geal structures contribute to upper ailway obstruction and obstructive sleep apnea.

In severe cases, morbid obesity leads to chronic alveolar hypoventilation, hypoxemia, arterial desaturation, reac- tive pulmonary vasoconstriction, right ventricular insuf- ficiency and failure, peripheral swelling, and increased work of breathing and of the heart.12 Other symptoms include daytime somnolence, sleep apnea, labored and rapid shallow breathing, and reduced exercise tolerance. Although patients who are moderately obese may be asymptomatic, they are at increased risk of cardiopulmo- nary compli~at ions~~%n conjuilctiorl with even minor medical problems or surgical interventions, and they are at increased risk of adverse reactions to pharmaco-

Physical Therapy. Volume 77 . Number 2 . February 1997 Dean. 197

logical support. Morbid obesity can contribute directly to respiratory insufficiency (ie, alveolar hypoventilation syndrome) .fiu

Reduced activity and loss of conditioning are factors contributing to the cardiopulmonary manifestations of obesity. Reduced activity contributes to increased pro- duction of fat-storing enzymes and reduced production of fat-burning enzymes."'LllVncreased activity and exercise, therefore, result in increased production of fat-burning enzymes and reduced production of fat- storing enzymes. Although aerobic exercise generally contributes to fat breakdown and its metabolic utiliza- tion, prolonged exercise (ie, greater than 90 minutes) at a heart rate below the aerobic training zone (ie, 60%- 70% of maximum heart rate) has been associated with the greatest fat-burning effects.lo4 Optimal weight loss and health result from a combination of proper nutri- tion (ie, low-fat, low-sugar, high-complex carbohydrate, and high-fiber diet) and e x e r c i ~ e . ~ ~ ~ - l ~ ~

Eating disorders such as anorexia nervosa contribute to deficits in oxygen transport secondary to general debility and metabolic ca tabol i~m.~g The strength and endur- ance of the respiratory muscles are correspondingly reduced. Coughing is weak and inefficient. Nutritional deficits include anemia and fluid and electrolyte imbal- ance, which can precipitate cardiac dysrhythmias and death in advanced cases."

Implications for Physical Therapy Management Management of the patient with obesity for any condi- tlon warrants careful attention to deficits in and threats to oxygen transport. These patients are more easily compromised during treatment compared with patients who are not obese. Recumbency may exacerbate symp- toms. Patients with obesity often experience less distress with the head of the bed elevated. Patients with obesity should not slouch when they are recumbent because doing so compromises diaphragmatic descent and con- tributes to closure of the dependent airways. In a supine position, the weight of the abdomen encroaches on the underside of the diaphragm, limiting its excursion. Thus, patients with obesity are often less compromised in a side-lying position in which the abdomen can be displaced forward, permitting increased diaphragmatic excursion (ie, semiprone with abdomen free). The semi- prone position provides many of the benefits of the prone position without increasing abdominal pressure. Patients with obesity need to be monitored for signs of cardiopulmonary distress during body positioning, par- ticularly in recumbent position^."^ In addition to restric- tion of diaphragmatic motion from the shift of the abdominal mass toward the thoracic cavity in recumbent positions, the heart is compressed and compromised by surrounding structures. Cardiac output is reduced,

hypoxemia is potentiated, and cardiac dysrhythmias can ensue.

Anorexia nervosa may be viewed by physical therapists as either a primary or a secondary condition. Primary physical therapy management ranges from intensive care to a judicious modified exercise program prescribed to maintain some degree of mobility, strength, and overall conditioning. Patients with this condition are malnour- ished; thus, an assessment should be done to establish the impact 0x1 cardiopulmonary function. The focus of a mobilization program is to avert the negative sequelae of restricted activity rather than to maximize aerobic capac- ity, endurance, and strength. It is essential that the oxygen and energy demands d o not exceed the patient's capacity to meet these demands phys i~ logica l ly .~~ Dehy- dration and electrolyte imbalance may accompany mal- nutrition in the patient with anorexia; thus, blood volume, hemodynamic, and electrocardiographic responses may be a b n ~ r m a l . I o ~ ( ~ ~ ~ ~ ~ - ~ Due to nutri- tional deficits, patients with anorexia may also be anemic and have abnormal immunity. Thus, the physical thera- pist needs to monitor serial blood laboratory values. Patients with anorexia fatigue readily.

Some patients with anorexia nervosa are compulsive exercisers, which increases metabolic demand. In con- junction with psychological and nutritional counseling, the patient should be counseled with respect to reducing excessive physical exercise and conserving energy.

Summary and Conclusion The example of the 75-year-old man with a primary diagnosis of right cerebrovascular accident described at the beginning of the article can be used to illustrate the cardiopulmonary manifestations of a systemic disease affecting an older person and some of the key points that must be considered in the physical therapy manage- ment. Neurological physical therapy for this older patient with a stroke includes control of muscle func- tion, control of pain secondary to overactive muscles, increasing muscle activity in paretic muscles, balance and coordination training, range-of-motion exercises, strengthening exercises, gait reeducation (often with aids such as an ankle-foot orthosis and a quad cane), and endurance training. Many of these interventions elicit an exercise stimulus and stress the oxygen transport system; thus, the patient's cardiopulmonary status needs to be monitored. In view of this patient's age, arterial oxygen tensions can be expected to be low. If the patient smoked, arterial desaturation would likely be accentu- ated. Intensive aerobic training has been advocated for patients following a s troke: '~uch intensive training, however, is risky for this patient population without appropriate monitoring and exercise prescription. Patients with stroke are usually older, are often hyper-

198 . Dean Physical Therapy . Volume 77 . Number 2 . February 1997

tensive, have evidence of coronary artery disease, and have cardiac dysrhythmias. Thus, treatments including any form of exercise stress warrant the inclusion of hemodyriamic monitoring. In addition, beta-blocking agents that are commonly used for blood pressure control attenuate exercise-induced heart rate and blood pressure responses; thus, other cardiovascular and car- diopulmonary measures of exercise response must be used.

Obesity may complicate the oxygen transport status of some patients following a stroke; thus, nutritional status should be considered. In addition, many older persons tend to be dehydrated, requiring consideration of fluid balance. Sleep apnea and impaired sleep should be assessed to ensure that the patient is adequately restor- ing physiologically from a night's sleep. Without ade- quate sleep, the patient cannot perform well physically during the day.

Because dysfunction in almost every organ system of the body can have cardiopulmonary consequences, physical therapists need to be able to predict and detect such manifesi.ations. Although the presentation of these car- diopulmonary manifestations may be subtle, the patient's prognosis is often poorer with even relatively mild cal-diopulmonary involvement. The patient there- fore should be appropriately monitored, and treatment for cardiopulmonary manifestations or the patient's primary diagnosis should be modified accordingly.

With an increasing trend toward direct access in the -

profession, physical therapists need to be vigilant about secondary underlying conditions. Known or suspected underlying conditions need to be assessed thoroughly so that the physical therapist can determine whether phys- ical therapy is contraindicated, what therapies are indi- cated, and how therapy should be modified. Further- more, physical therapists need to be able to anticipate abnorm.al treatment responses and to determine when a patient needs to be referred to another health care professional. Virtually all physical therapy intementions are associated with hemodynamic stress and demands on the oxygen transport system. Thus, this stress on oxygen demand must be considered with respect to the capacity of every patient to transport oxygen, which encompasses the delivery, uptake, and utilization of oxygen.

With changes in the demography of the population and in health care problems, physical therapists are seeing more patients than ever before who have complex, multisystem problems. Such problems can be seen in the medically stable individual living in the community or a nursing home, in the medically stable patient being treated in the hospital, and in the unstable patient in intensive care with multiorgan system failure. High-risk

patients are not restricted to the intensive care setting. Physical therapists in all specialties need an understand- ing of the cardiopulmonary consequences of systemic diseases because these effects can range from being relatively minor with little effect on function to being life threatening.

References 1 Bromberg PA, Ross, DW. Thr lungs and hematologic disease. In: Murray JF, Nadel J, eds. T~xtbook a/ R e . ~ p i r a t o ~ Medicin?. Philadelphia, Pa: W B Saunders Co; 1988: 1906-1920.

2 Femi-Pearse D. Gazioglu KM, Yu PN. Pulmonary function and infection in sickle cell disease. JAppl Physiol. 1970;28:574-577.

3 Green D, Esparaz B. Coagulopathies in the critically ill patient. In: Cane RD, Shapiro BA, Davison R, eds. Cast Studies in Critical C(rre Medicine. 2nd ed. Chicago, Ill: Year Book Medical Publishers Inc; 1990:308-320.

4 Guyton AC. Textbook o/Medical Physiology. 8th ed. Philadelphia, Pa: WB Saunders Co; 1991.

5 Spence TH. Pulmonary embolization svndromr. In: Civetta IM. ailo or RW, Kirby RR, rds.' Cn'tiral Care. ~ h i l a d e l ~ h i a , Pa: JB Lippincott Co; 1988:1091-1102.

6 Sal~man EM'. Davies GC. Prophylaxis of venous thrombosis. Ann Surg. 1980;191:207-218.

7 M'rngcr NK. Early ambulation: the physiologic basis revisited. Adu Cardiol. 1982;31:138-141.

8 Kolari PJ, Pekanmaki K, Pohjola RT. Transcutaneous oxygen tension in patients with post-thrombotic leg ulcers: treatment with intermittent pneumatic compression. Cardiouasc Res. 1988;22:138-141.

9 Cooper CB, Trend PS, U'iles CM. Severe diaphragm weakness in multiple sclerosis. Thorax. 1985;40:631-632.

10 DeTroyer A, De Bey1 DZ, Thirion M. Function of the respiratory muscles in acute hemiplegia. Am Rm Kespir Dis. 1981;123:631-632.

11 Griggs RC, Donohoe LM. Recognition and management of respi- ratory insufficiency in neuromuscular disease. J Chronir Dis. 1982;35: 497-500.

12 Bates DV. Respiratory Funrtion in Disease. 3rd ed. Philadelphia, Pa: WB Sauriders Co; 1989.

13 Hoffman LA. Ineffrctive airway clearance related to neuromuscular dysfunction. NUTS Clin North Am. 1987;22:151-166.

14 Fugl-Meyer AR. Effects of respiratory muscle paralysis in tetraplegic and paraplegic patients. Scand J Retinbil Mpd. 1971 ;3:141-150.

15 Bake B, Fugl-Meyer AR, Grimby G. Breathing patterns arid regional ventilation distribution in tetraplegic patients and in normal subjects. Clin Sci. 197'2;42:117-128.

16 Chen CF, Lien IN: Wu MC. Respiratory function in patients with spinal cord injuries: effects of posture. Paraplzgia. 1990;28:81-86. 17 Fullford FE, Brown JK. Position as a cause of deformity in children with cerebral palsy. Deu Med Child Neurol. 1976;18:305-314.

18 Dean E. Ross J, Road JD, et at. Pulmonary function in individuals with a history of poliomyelitis. Chest. 1991;100:118-123.

19 Dean E. Clinical decision making in the manageineut of the late sequelae of polioniyelitis. Phys Ther. 1992;71:752-761.

20 Civetta JM, Taylor RW, Kirby RR, eds. B.itiral Care. Philadelphia, Pa: JB Lippincott Co; 1988.

Physical Therapy. Volume 77 . Number 2 . February 1997 Dean . 199

21 Bannister R. Clinical features of autonomic failure, A: symptoms, signs, and special inbestigatlons. In: Bannister R, ed. AvtonomzcFc~zlurr: A Textbook of Clznzcal Dl~olderr oj the Autonomtc Neruous .S'ystrm 2nd ed. Oxford, England: Oxford Ulliversity Press Ltd; 1989:267-288.

22 Dean E. Mobilizatioil and exercise. In: Frownfelter D. Dean E, eds. Principles and Pmctzcr of Cardiopulmonaty Physical Thnapy. 3rd ed. St Louis, Mo: Mosby, 1996;265-298.

23 Neremakis C. Neurologic: essential physiologic concerns. 111: Civetta JM, Taylor RW, Kirby RR, eds. Critical Care. Philadelphia, Pa: JB Lippincott Co; 1988:1191-1197.

24 Bach JR. New approaches in the rehabilitation of the traumatic high-level quadriplegic. Am J Phv.r Med Rehabil. 1991 ;70: 13-19.

25 Linder SH. Functional electrical stimulation to enhance cough in quadriplegia. Chest. 1993;103:166-169.

43 Smith PEM, Calverley PMA, Edwards RHT, et al. Practical problenls in the respiratory care of patients with ~rluscular dystrophy. N E n d J Med. 1987;316:1197-1205.

44 Loveridge B, Sanii R, Dubo HI. Breathing pattern adjustments during the first year following cemical spinal cord i~?jury. Paraplegia. 1992;30:479488.

45 Loveridge B, Dubo HI. Breathing pattern ill chronic quadriplegia. .4rrh Phys Med Rrhobil. 1990;71:495-499.

46 Bach JR. Piilmonary rehabilitation considel-ations for Duchennc muscula~ rlystrophy: the prolongation of life by respiratory musclr aids. C~ztircrl EiPl~in~~s in Physical and fihabili/ation 12k.,dicin(,. 1992;3:239-269. 47 Bach JR. Mechanical insufflationcxsufilation: comparison of peak expiratory flows with manually assisted and unassisted coughing tech- niques. Chr~t. 1993:104:1553-1562.

26 Massery M. The patient with neuromuscular and musculoskeletal 48 Dean E, Ross J. Movement energetics of individuals with a history of' dysfunction. In: Frownfelter D, Dean E, eds. Pnncipler and Practicr of poliomyelitis. Arch Phys Med Rehabil. 1993;74:478-483.

- .

Cardiopulmonaty Physical Therapy. 3rd ed. St Louis, Mo: Mosby: 1996: 49 Wasserrnan KL, b h i p p BJ. Exercisr physiology in health and 679-702. disease. Am &v Respir Dis. 1975;112:219-249. 27 Cameron JL. Zvidema GD. Aspiration pneumonia: magnitude and 50 Whipp BJ, Ward SA. Cardiopulmonan coupling during exercise. frequency of the problem. J A M . 1972;219:1194-1196. E.xb Biol. 1982:100:175-193. < . 28 Goodwin SR. Aspiration syndromes. In: Civetta JM, Taylor RW, 51 Mossberg KA, Linton KA, Friske K. Ankle-foot orthoses: effect on Kirby RR, eds. Critical Cow. PhiladeIphia. Pa: JB Lippincott Go; 1988:1081-1090. energy expenditure of gait in spastic diplegic children. Arch Phjs Mrd

Rehabil. 1990;71:490-494. 29Young CS. A review of the adverse effects of airway suction. 52 Waters RL, Hislop HJ, Perry J, et al. Energetics: application to the Physiotherapy. 1984;70:104-106.

studv and management of locomotor disorders. Orthufi Clin ,Vorih Am. -

30 Walsh JM, Vanderwarf C, Hascheit D: Fahey PJ. Unsuspected 1958;9:351-362. hemodynamic alterations during endotracheal suctioning. Chrst. 1989; 95:162-165. 53 Corcolan PJ, Jebsen RH, Brengelmann GL, et al. Effects of plastic

and metal lea braces on speed and erierw cost of herni~aretic - L.,

31 Bach JR, O'Brien J , Krolenberg R, Alba AS. hfanagement of end ambuldtion. ilrch Phys Mrd Rehabtl. 1970;51.69-77. I stage respiratory failure in Duchenne muscular dystrophy. Muscle Nen~e. 1987;10:177-182,

32 Bach JR, Alba SA, Shin D. Management alternatives for post-polio respirato~y i~lsufficiency: assisted ventilation by nasal or oral-nasal interface. Am JPhys bfed Rehab~l. 1989;68:264-271. 33 Perry J, Barnes G, Gronely JK. The post-polio syndrome: an overuse phenomenon. Clin Orthop. 1988;33:145-162.

34 Johnson RT. Late progressioil of poliomyelitis paralysis: discussio~l of pathogenesis. Revtm of Infectious Diseases. 1984;6(suppl 2):S568- S570.

35 Wiechers DO, Hubbell SL. Late changes in the motor unit after acute poliomyelitis. Muscle Nerve. 1981;4:524-526.

54 Dean E, Dallimore M. Activity rest profiles: a basis for fatigue management in patients with the late sequelae of poliomyelitis. In: Procr~dings of the Canadian Plzysiothnt~py Congress; \fic/ona, B~itish Colztm- bin, Canada; 1996.

55 Mckdle WD, Katch FI, Katch VL. Exerci.c~ Phy.riology: E?t@rg3;, N u t ~ i - tion, find Human Peiformance. Philadelphia, Pa: Idea & Febiger; 1991. 56 Overend TJ. Paterson, DH, Cunningham D4. The effect of interval and continuous training on aerobic parameters. Can J Spott Sci. 199'2;17:129-134.

57 Gorostiaga EM, Walter CB, Foster C: Hiscksnon RC. Uniqueness of intelval and continuous training at the same mairltained exercise intensity. J Appl Physiol. 1991;63:101-107.

36 Larsson L, Grimby G, Karlsson J. hluscle strength and speed of 58 Malouin F, Putvin M. PrPvost J, et al. Use of arl intensive task- movement in relation to age and muscle morphology. J A p p l Pl~ysiol. orierited gait training program in a series of patients with aciite 1979;46:451-456. cerebrovascu1a~- accidents. Phys Ther. 1992;72:781-793.

37 Bennett RL., Knowlton GC. Overwork weakness in partially denrr- 59 Dean E. Advances in rehabilitation for older persons with cardio- vated skeletal muscle. Clin Orthop. 1958;12:22-29. pulmonary dysfunction. In: Katz PR, b n e RL,, Mezey MD, eds. 38 McCool FD, Tzelepis GE. Inspiratory muscle training in the patient Advancrs in Long-term Care, I.olumr 2. New l'ork, NY Spl-inger Publishing

with neuromuscular disease. Ptlys Ther. 1995;75: 1006-1 114. Co Inc; 1993:l-71.

39 Moxham J. Respiratory muscle fatigue: aspects of detection and 60 Hobson I,, Hammon WE. Chest assessment. 111: Frownfelter D, ed. treatment. Bulletin of European Physiopalholo~ of Rrrpiration. 1984;20: Chwl Physical 7%n-apy and Pulmonnty Rrhnbilitc~tion. St Louis, Mo: Mosby; 437-444. 1987:147-397.

61 Sinha R, Bergofsky EH. Prolonged alteration of lung mechanics in 40 Clanton TL, Diaz PT. Clinical assessment of the respiratory muscles. Phys Ther. 1995;75:983-995. kyphoscoliosis by positive pressure hypeririflation. Am k l Respir Dis.

1972; 106:47-57. 41 Reid WD, Dechman G. Considerations when testing and training the respiratory muscles. Phys Ther. 1995;75:971-982. 62 Shin B, hlackenzie CF, Chodoff P. Is IMV superior to controlled

ventilation in the manaeernent of flail chest? Cvt Carp MPIJ. 1979.7. " ~ - - ~ - ~ - . - . ,.-

42 Reid WD, Samrai B. Respiratoq muscle training for patients with 138-143. - .

chronic obstructive disease. Phys Ther. 1995;75:996-1005. I

2 0 0 . Dean Physical Therapy. Volume 77 . Number 2 . February 1997

63 Dean E. Bod! positioning. 111: Frownfelter D, Dean E, eds. f i n r i p h I r o i r t i u l r ~ o n i i Phjsiral Thrrapy. 3rd ed. St Louis, hlo: \lo5by: 1996:'LYY -320.

64 Thiagarajah S. Regional anesthesia. In: Levine RD, ed. .4irrslhesiol- 00. Philadelphia, Pa: JB Lippincott (:o; 1984: 17-27. 65 Massen; M, Frownfelter D. Facilitating aimray clearance by cough and suction techniques. In: Fro\cnfelter D. Dean E, eds. Principlus and Prort~rr' o f ( ~ a r d i ~ ~ u 1 r n o n a i ~ Plrjticrrl Thernp?.. :lrd ed. St Louis, Mo: Mosby; 1996:3ti7-S82.

66 Froicnfelter D, Massev b1. Facilitating ventilatory patterns and breathing strate,?. In: Frownfelter D, Dean E, eds. Prinriplrs crndPmr-tirr o j C n r t i ~ i $ ~ ~ c l m o r ~ a i ~ Physirnl Tlrr~rrpy. 3rd ed. St Louis, Mo: Mosby; l996:383-41 ti.

67 Barish CF, LVu M'C. Castell DO. Respiraton complications of gastt"~csnphageal reflux. Arch lntrnr Med. 1985; 14.5: 1882-1 888.

68 Dean E. Intensive care unit management of seconda~y cardiopul- monay: dysfirnrtion. In: Fro\\,nfclter D, Dean E, eds. P r i r ~ c i p k itnd hortire o f ( , ' a r d i ~ g ~ r l i ~ r o ~ ! ' h q s i r a l Thmrpr. 3rd ed. St Louis, Mo: Mosby; 1996:5!4-616.

69 Ibar~er J , Penafiel .I, Raurich JS1, et al. Gastrointestinal reflux in intubatrd patients receiving rnteral nutrition: effect of supine and se~uirrcr~~rnbent positions. JPES J P~lrrntrr Entrral 1V1rrr. 1992;16:411)- 422.

70 Miller +J Deglutition. Wzj\iol &I. 1982;62: f 20-184, 71 Be~,ja~nin SB. Extra-esophageal complications of gastroesophageal reflux. / ( I in (;ostroentrrol. 1986;8(suppl) :68-71. 72 Higctnhottom T, Cochrane (;M, Clark TJH, e t al. Bronchial disease in ulrerative cc~~litis. Thorax. 19H0;35:581-585.

73 M'alleart B, Columbel JF, Tomrnel AB, et al. Evidence of Ivn~phw cytic al~;eolitis in Crohtl's disease. Chert. 1985:87:36.?~367.

74 Funahashi A, Kutt). A\T, Prater SL. H!poxaernia and cirrhosis of the liver. Thorrrr. 1976;31:303-308.

75 Daolid FS, Reeves JT. Schaefer JV. Failt~re o f hypoxic pulmonary \asoco~~striction ill patients with live1 cirrhosis. ,/ ( : [ /?I lnur\t. 1972;51: 1076-1080.

76 Larc~s CD. Shu11tq in and o \e r the lungs. Krspzratzon. 1972;29:24-39.

77 Rut1 F, Hughes JhlB. Stanley S, et al. Regional lung f1111ction in patients \\ith hepatic cirl-hosis. ,J Clin Irrr!ert. 197 1:50:240:C2413.

78 Hanson (:A, Ritter .a, Lluran M', et al. A~cites: its effect i ipo~l status inflation of the respirator\. system. .am Rm RPspirDis. 1990:142:39-42.

79 Trev:by PN, Warren R. (:ontini S, et al. Incidence and pathophvsi- o l o p of pullnollan edema in fl~lminant Ilepatic failure. Grt.rtromtmo1- o,q. 1978;74:859-865.

80 Sherlock S. The h e r lung interfbcc. .Semir~ars 1 1 1 He.~pirator). Alrrlicine. 1988;9:247-253.

81 Lee HY, Strettorl TB, Barnes AM. The lungs in I-enal f . ~ i l ~ ~ ~ - e . Thorax. 1975;30:46-53.

82 Matthay RA, Bromberg SI, P u ~ m a ~ i (:E. Pulrnonan-re~~al syn- dromes: a rrvie\c. l'alu J Biol ,\led. IF)XO;.i:l:497-523. 8 3 k o w k a h'IJ, Cortrse DA. Severe hypoxen~ia aswciated with liver disease. ,\layo (;ltnii. Pror. 1YX7;6?: 164-1 73. 84 Rankin JA. blatthay KI . Pulmonar) r e ~ ~ a l syndrolnes, 11: etiology and pathogenesis. lir1r.J Biol ,\lerl. 1982;55: 11-26.

85 \'endcr J . Pulmona~? aspiration. In: Cane RD. Shapiro BA, Davison R, eds. Crr.se ,S'/n/liri i i ~ C?i/~rrrl (;(ire .\l/,(li(.irze, Chicago, Ill: Year Book h1edic;il Publishers Inc; lYYO:2.il-?6.5.

86 Vanatta ,JC, Fogelman MJ. ~\ iqrr 'c Fluid Balance: A Clii~iral ~\lanurrl. 4th ed. Chicago, Ill: Year Book Sledical Publishers Inc; 1988:123-128.

87 Ragg LR, Hughes DT. Serial pulmonaryfunction tests in progrrhsive systemic sclerosis. Tl~or-ox. 197

108 Murra? JF, Felton CP, Garay SM. Pulmonary complications of the acquired immunodeficiency syndrome. N Engl J Med. 1984;310:1682- 1688.

109 Phair,IP. Infection in the immunocompromised patient. In: Canc RD, Shapiro BA, Davision R, eds. Cci.tr Studies in Cntiral Care iMedici71r. 2nd ed. Chicago, Ill: Year Book Medical Publishers Inc; 1990:347-361.

110 Hess D, Agarwal NN, Myers CL. Positioning. lung function, and kinetic bed therapy. Respiralmy Cure. I!j92;3?:181-197. 111 Langer M, Mascheroni D. Marcolin R, et al. The prone position in ARDS patients: a clinical study. C:hrcl. 1988;94:103-107.

112 F'yne DB. Regulation of netrophil function during exercise. Sports Med. 1994;17:245-258.

113 Ross J , Dean E. Body positioning. In: Zadai C, ed. Clinics in Ptiysical Thvap?: Pulmotin~ Managemmt 171 Physical Therapy. New York, NY Churchill Livingstone Inc; 199'2:79-98.

115 hliller W. Diet composition, energy intake, and exercise in relation to hod) fat in men and women. Am J Clin Nutr. 1990;.52:426-430. 116 de Boer J. Adaptation of energy metabolism of overweight women to lowenerg\. intake, studied with whole body calorimeters. Am J (:[??I 1Vutr. 1986;44:585-595.

117 Blair S. Physical fitness and all-cause mortality: a prospective st~tdy of healthy men and women. JAIMA. 198!);262:2395-2401. 118 Browner W. U'hat if Americans ate less fat?,lA~CM. 1991;263:3285- 3291.

119 Foblin L. Body composition. cardiovascular, and renal function in adolescent patients with anorexia nenosa. Acta Pediatr Scand. 1997; 268(suppl) :1-20, 120 Nudcl DB, Gootman N. Nussbauni MP. Altered exercise perfor- mance and abnormal sympathetic responses to exercise in patients with anorexia nervosa. JPediatr. 1985;105:34-37.

114 Alexander JK. The cardiomyopathy of obesity. Prog Cardiovasc Dix. 1985:27:325-334.

Call for Reviewers

Phys ica l T h e r a p y is currently seeking qualified individuals to serve as manuscript reviewers. Reviewers should have:

Extensive experience in area(s) of content expertise Experience as authors of articles published in peer-reviewed journals

Familiarity with peer review is essential.

If ~ O I J are interested in becoming a reviewer for the Journal, please send a cover letter and a copy of your curriculum vitae to:

Editor Phys ica l T h e r a p y 1111 North Fairfax Street Alexandria, VA 22314-1488

I Interested in becoming involved, but not sure you have the time to review manuscripts? The Journal is also looking for article abstracters and booWsoftware/videotape reviewers. Send us a letter expressing your interest and stating your general areas of expertise, along with a copy of your curriculum vitae. We look forward to hearing from you. 202 . Dean Physical 'Therapy. Volume 77 . Number 2 . February 1997