Cerebral air embolism treated by pressure and hyperbaric oxygen.

We used pressure and hyperbaric oxygen to treat 2 patients with cerebral air embolism, occurring as the result of invasive medical procedures, and neither suffered any permanent damage detectable by clinical examination and MRI. This outcome contrasts with reports of infarct and disability among untreated victims of air embolism.

Effect of lidocaine after experimental cerebral ischemia induced by air embolism.

To investigate possible approaches to the treatment of neural damage induced by air embolism and other forms of acute cerebral ischemia, somatosensory evoked potentials (SEP's) were measured after cerebral air embolism in the anesthetized cat. Air was introduced into the carotid artery in increments of 0.08 ml until the SEP amplitude was reduced to approximately 10% or less of baseline values. Either a saline or lidocaine infusion was begun 5 minutes after inducing cerebral ischemia. In the saline-treated group, SEP amplitude was reduced to 6.7% +/- 1.6% (mean +/- standard error of the mean) of baseline, with a return to 32.6% +/- 4.7% of baseline over a 2-hour period. In the lidocaine-treated group, SEP amplitude was reduced to 5.9% +/- 1.5%, with a return to 77.3% +/- 6.2% over a 2-hour period. The results suggest that lidocaine administration facilitates the return of neural function after acute cerebral ischemia induced by air embolism.

Hormonal changes during decompression sickness.

Changes in plasma hormone levels were studied in anesthetized dogs during decompression sickness. Hormone levels were measured in 4 groups: control (no dive, n = 9); air group (air dive, ventilated with air postdive, n = 6); helium-oxygen (He-O2) group (air dive, ventilation changed to He-O2 at 30 min postdive, n = 9); nonsurvivor group (air dive, died within 30 min postdive, n = 9). Dived animals were subjected to repetitive dives until pulmonary artery pressure doubled. Plasma epinephrine (Epi) and norepinephrine (NE) concentrations rapidly increased postdive in all animals. Serum angiotensin-converting enzyme (ACE) activity increased postdive in the He-O2 group only, and these increases were small. Diving did not alter serum concentrations of cortisol, thyroxine (T4), or triiodothyronine (T3); however, T4 and T3 fell in all animals, probably as a consequence of anesthesia. He-O2 breathing did not affect concentrations of Epi, NE, cortisol, T4, T3, or serum ACE activity.

Failure of heparin, superoxide dismutase, and catalase to protect against decompression sickness.

The effects of heparin (HEP), superoxide dismutase (SOD), and catalase (CAT) on the course of decompression sickness (DCS) were studied in anesthetized dogs (Canis familiaris). Animals were divided into 4 groups: a drug assay group (n = 4) received HEP + SOD or HEP + SOD + CAT but were not dived; a control group (n = 14) was dived without drug treatment; a HEPSOD group (n = 11) received HEP + SOD predive and postdive; and a HEPSODCAT group (n = 15) received HEP + SOD + CAT before diving. All dived animals were subjected to repetitive air dives to 10 ATA until pulmonary artery pressure at least doubled within 10 min postdive. Physiologic variables were measured for 3 h postdive or until death. Animals were not recompressed. More early deaths occurred in the HEPSOD (7/11) and HEPSODCAT (8/15) groups than in the control group (5/14). All dived animals developed pulmonary hypertension, systemic hypotension, hemoconcentration, acidosis, hypoxemia, and interstitial pulmonary edema postdive. Drug therapy did not alter these responses to decompression. We conclude that without recompression, treatment with either HEP + SOD OR HEP + SOD + CAT does not improve the outcome of severe DCS in this animal model.

Effects of He-O2 breathing during experimental decompression sickness following air dives.

The effects of ventilation with He-O2 during decompression sickness (DCS) and venous air embolism were studied. Fifteen anesthetized dogs were mechanically ventilated and subjected to repeated air dives until pulmonary artery pressure at least doubled within 10 min postdive. At 30 min postdive, ventilation was either continued with air (controls, n = 7) or changed to He-O2 (n = 8) for an additional 90 min. All animals developed pulmonary hypertension, systemic hypotension, hemoconcentration, hypoxemia, hypercarbia, and pulmonary edema. Breathing air or He-O2 postdive did not alter these responses, but He-O2 breathing produced an 11% increase in pulmonary vascular resistance (PVR). In 3 other anesthetized dogs that were not subjected to dives, ventilation was changed to He-O2 at various times during an intravenous infusion of air; He-O2 breathing caused a 22% increase in PVR. We conclude that breathing He-O2 during DCS resulting from air dive can intensify pulmonary vascular obstruction.

Respiratory mechanics in men following a deep air dive.

The mechanical properties of the lungs were measured in 10 men before and after a simulated air dive to 285 ft of seawater (87 m). The objective was to determine whether a dive likely to produce pulmonary bubble emboli would alter lung mechanics. Lung function was measured predive and at 1, 2, 3, 6, 7, and 23 h postdive. Measurements of lung function were also made at identical times on a control day when no dive was made. Each set of measurements included precordial Doppler signals, pulmonary resistance, quasistatic lung compliance, forced vital capacity (FVC), forced expired volume after 1.0 s (FEV 1.0), the ratio of FEV 1.0 to FVC (FEV 1.0/FVC%), and maximal airflow after 50 and 75% of the vital capacity had been expired (Vmax50 and Vmax75, respectively). Base-line measurements of pulmonary resistance and quasistatic compliance were normal in all subjects. FVC and FEV 1.0 were greater than predicted for most subjects and were increased proportionately so that the FEV 1.0/FVC% was normal. Following the dive, bubble signals were heard in four subjects, and two subjects had mild symptoms of decompression sickness. No subject demonstrated any alteration in lung function that could be attributed to the dive. We concluded that stressful decompressions capable of producing "silent" pulmonary bubble emboli do not alter lung mechanics.

In vivo microbubble detection in decompression sickness using a second harmonic resonant bubble detector.

A resonant bubble detection method based on a second harmonic technique has been used to monitor the femoral vascular system of dogs subjected to rapid decompression. For this study, the detector consisted of two acoustic transducers mounted at right angles to each other that were packaged in a perivascular cuff configuration. This detector responds selectively only to bubbles near resonant size (4.2 mum in diameter); solid particles and large bubbles produce no response. The detector was used to monitor a total of 15 dogs. Eleven dogs were subjected to a series of simulated underwater dives until acute symptoms of decompression sickness occurred; 4 dogs served as controls. In the dived group, either the femoral vein or the femoral artery was monitored. Resonant bubbles were observed in the femoral veins of all 6 dogs monitored at this location. During arterial monitoring, most dogs showed no response, but an occasional weak response was observed in 2 of the dogs. No resonant bubbles were detected in the femoral artery or the femoral vein in any of the controls. The data suggest that this bubble detection method is feasible for in vivo use. Furthermore, 4 mum diameter bubbles are much more prevalent in the veins of dogs suffering from decompression sickness than they are in dog arteries, presumably because they are filtered out effectively by the pulmonary circulation. Modifications of this method are discussed to enhance its accuracy and applicability for quantifying bubble size, location, and number.

Morphological and physiological responses of the lungs of dogs to acute decompression.

The lung's response to decompression was studied in dogs anesthetized with pentobarbital sodium. Arterial pressure, hematocrit, right ventricular pressure, left ventricular end-diastolic pressure (LVEDP), dynamic compliance (CL), pulmonary resistance (RL), and arterial PO2, PCO2, and pH were measured prior to and for 3 h after a simulated air dive to 300 feet of seawater. Bronchoscopy was performed predive and at 3 h postdive. At 3 h animals were killed, and sections of lung were excised for histological examination. The decompression profile used regularly produced pulmonary hypertension, systemic hypotension, hemoconcentration, and arterial hypoxemia. CL fell in all but one dived animal. RL was more variable but remained unchanged postdive in most animals. The decompression stress did not alter the bronchoscopic and histological appearance of the airway mucosa. Pulmonary edema was regularly observed in histological sections and occurred without elevations of LVEDP. We concluded that noncardiac pulmonary edema is the principal response of the lung to decompression stress.

The value of fiberoptic bronchoscopy in the management of pulmonary collapse.

Nineteen fiberoptic bronchoscopic procedures were performed on ten patients for the treatment of pulmonary collapse. All but two patients were being treated for severe, life-threatening nonpulmonary diseases. Thick, tenacious, and, at times, purulent mucous plugs were successfully aspirated from the bronchial passages. Complete to partial radiologic reexpansion of the collapsed pulmonary region was observed following all but one procedure. Significant improvement in blood gas levels was also noticed immediately after the procedure. Bronchoscopic examination in these seriously ill patients did not cause any complications. The therapeutic value of fiberoptic bronchoscopic procedures in patients developing pulmonary collapse due to thick secretions and mucous plugs was demonstrated.