Vasoconstriction

Hyperoxia-induced vasoconstriction occurs in both arterial and venous vasculature and has been demonstrated in cerebral, retinal, renal, muscle, and myocardial circulations. Despite reduction in blood flow from vasoconstriction, tissue oxygen partial pressures increase because of the increased amount of oxygen dissolved in plasma.⁵⁴ Edema reduction occurs because filtration of capillary fluid is decreased, whereas vascular outflow and improved oxygen delivery are maintained. This vasoconstriction can be beneficial in peripheral edema and intracerebral edema and decreases edema in burns and post-ischemic tissues.^{15,130,135,136} Hence blood flow in the microcirculation is improved through decreasing interstitial fluid pressures from edema reduction. This effect is important in the treatment of brain injuries from carbon monoxide poisoning or arterial gas embolism, spinal cord decompression sickness, and crush injuries.

Antibacterial Effect

HBO has been shown to have a potent inhibitory effect on growth of various microorganisms. HBO causes a direct bactericidal effect on anaerobic bacteria through production of toxic radicals in the absence of free radical degrading enzymes, such as superoxide dismutase, catalases, and peroxidases.⁷⁸ HBO also has a bacteriostatic effect on selected facultative and aerobic organisms.⁸⁹ Tissue PO₂ of 30 to 40 mm Hg is necessary for oxidative killing of microorganisms by neutrophils. Increased PO₂ in infected and hypoxic tissue enhances neutrophil function and return of antimicrobial activity. HBO also augments the bactericidal action of aminoglycosides and potentiates the effect of certain sulfonamides.^64,83 Aminoglycoside and cephalosporin antibiotic transport across the bacterial cell wall requires tissue oxygen tensions above 30 mm Hg. Overall, HBO enhances transport and augments antibiotic efficacy.

Wound Healing

The relationship between tissue wound hypoxia and wound healing has been well documented.^75,76 Tissue hypoxia decreases fibroblast replication, collagen deposition, angiogenesis, resistance to infection, and intracellular leukocyte bacterial killing, which are all oxygen-sensitive responses essential to normal wound healing. Intermittent elevations of tissue PO₂ reverse localized tissue hypoxia and correct the pathophysiology related to oxygen deficiency and impaired wound healing. HBO enhances collagen synthesis, stimulates angiogenesis, improves leukocyte function of bacterial killing, and blunts systemic inflammatory responses.^74,76,103 In addition, hyperbaric oxygen stimulates vascular endothelial growth factor (VEGF) release and induces platelet-derived growth factor (PDGF) receptor appearance.^17,160,208 The net result of serial increased PO₂ from HBOT is improved local host immune responses, clearance of infection, enhanced tissue growth, angiogenesis with progressive improvement in local tissue oxygenation, and epithelialization of hypoxic wounds.

Ischemia–Reperfusion Injury

Ischemia-reperfusion injury (IRI) is tissue damage that occurs after reperfusion of ischemic tissue. IRI is mediated by oxygen-derived free radicals, such as superoxide and hydroxyl free radicals, which are produced during prolonged periods of ischemia followed by reperfusion. These oxyradicals can lead to cell death by lipid peroxidation and generation of further free radicals. Oxyradicals are generated from xanthine oxidase and neutrophils. Neutrophil endothelial adhesion and subsequent release of free radicals play an important role in endothelial and microcirculatory damage.^86,152

HBO protects tissues from reperfusion injury. HBO provides additional oxygen for reperfused tissues to generate scavengers such as superoxide dismutase, catalase, peroxidase, and flutathione, which detoxify destructive oxygen radicals before they damage tissues.⁴⁹ HBO antagonizes the beta₂ integrin system, which initiates the adherence of neutrophils to postcapillary venule endothelium.^178,180 Reperfusion injury may be inhibited by HBO through a decrease in leukocyte venular endothelial adherence, release of toxic oxygen species, and arteriolar vasoconstriction; hence progressive arteriolar vasoconstriction is inhibited.²⁰⁶ HBO inhibits intracellular adhesion molecule (ICAM-1) expression, which plays a role in neutrophil adhesion and ischemia-reperfusion injury.²⁶ Additionally, HBO upregulates transforming growth factor beta 1 (TGF-β1), which decreases reperfusion injury by upregulating bcl-2 and inhibiting tumor necrosis factor alpha (TNF-α).⁶³ Nitric oxide (NO) plays an important role in IRI, regulating vascular tone and neutrophil adhesion. HBOT appears to increase NO production by inducing nitric oxide synthase (NOS) production.^7,26,179 It is possible that the beneficial effect of HBOT in IRI is primarily mediated by NO.²⁵

HBO has been shown to be beneficial in almost all animal models of ischemia-reperfusion studied and results in increased microvascular perfusion in skeletal muscle and improved skin flap survival.^{97,202,206,207} It may be an important adjunct for treatment of tissue at risk for reperfusion injury that can accompany crush injury, limb replantation, compartment syndrome, and decompression illness. New data suggest a role of HBOT in preventing ischemia-reperfusion injury associated with myocardial infarction and cerebral ischemia.

Altitude Illness

Several portable hyperbaric chambers are available for emergency treatment of severe acute mountain sickness, high-altitude pulmonary edema, and high-altitude cerebral edema, particularly when descent is not feasible or while waiting for evacuation (Figures 78-4 to 78-6; Figure 78-6, online). They are constructed of relatively lightweight fabrics and require no use of portable oxygen. The portable chambers are pressurized with ambient air using manual foot pumps or hand pumps and can simulate a descent of 1500 to 2500 m (5000 to 8200 feet). Hyperbaric treatment should only be used as an emergency measure and does not substitute for descent or evacuation.

FIGURE 78-4 Chinook Medical Gear’s Gamow portable altitude chamber. A, In the field. B, Close-up.

(Courtesy Chinook Medical Gear, Inc.)

FIGURE 78-5 Certec chamber.

(Courtesy Certec Company.)

FIGURE 78-6 Treksafe Portable Altitude Chamber (PAC).

(Courtesy Treksafe Company.)

The patient should be told to breathe normally and instructed on equalizing his or her ears by swallowing or by Valsalva maneuver. The patient is placed inside the portable chamber, the zipper is pulled shut, and the bag is inflated with the foot pump to 2 psi (104 mm Hg) above ambient pressure. Two pop-off pressure values are set at 2 psi and prevent overpressurization of the bag. All the bags must be pumped continually 8 to 12 times per minute in order to flush air through the chamber to prevent carbon dioxide (CO₂) buildup. Patients should be treated for approximately 1 hour and then removed from the bag and reassessed. Additional cycles of descent and reassessment are continued until the patient improves and is able to descend or until evacuation is available. Patients with severe high altitude pulmonary edema (HAPE) may not be able to lie flat; hence one end of the chamber can be propped up 30 to 40 cm (12 to 16 inches). In severe cases, a patient can breathe oxygen at 4 to 6 L/min during the treatment by placing an oxygen bottle inside the chamber.

Three portable chambers are currently available for use at high altitude. The Gamow bag (see Figure 78-4) was invented by Dr. Igor Gamow at the University of Colorado. It is cylindric, lightweight (the bag, pump, and carrying day pack weigh approximately 7 kg [15 lb]), and easy to use. It measures 2.5 × 0.6 m (8 × 2 feet) and can maintain an internal pressure of 2 psi (104 mm Hg or 0.13 atm). The Certec hyperbaric chamber comprises two bags: an outside envelope made to withstand tension and provide stability and an inside envelope of polyurethane that allows for more durability of the chamber (see Figure 78-5). The Certec chamber weighs 4.8 kg (10.5 lb) and measures 2.2 × 0.65 m (7 × 2 feet); it can be pressurized to a slightly higher inflation pressure (internal pressure of 165 mm Hg or 0.22 atm or 3.2 psi) than can the Gamow bag. This is equivalent to about 800 m (2625 feet) greater simulated altitude descent; however, it is unclear whether this is important clinically. The Portable Altitude Chamber (PAC) is about the same size as the Gamow bag but allows more room at the head and shoulders and has a radial zipper at the head, allowing easier assess for the patient (see Figure 78-6, online). All three chambers have been used successfully at altitude; early symptom relief and improvement in peripheral oxygen saturation and cerebral oxygenation have been reported.^4,77 These chambers have no utility in the treatment of diving injuries.

Life Support Technology Group (LST) and the Center for Investigation of Altitude Medicine (CIMA) in Cusco, Peru, have developed a series of Acute Mountain Sickness (AMS) hyperbaric treatment profiles using standard hyperbaric chambers that can be pressurized to 3 ATA.²⁸ These AMS profiles provide rapid pressurization to sea level and beyond, with exposure to hyperbaric oxygen followed by a gradual decrease in ambient pressure while the patient breathes air. LST and CIMA report that these AMS hyperbaric treatments virtually eliminate the AMS rebounding often seen with conventional treatment, in which the patient either remains at altitude or is recompressed back to 1500 to 2438 meters briefly and then returns to the same altitude where AMS symptoms first manifested. These are proposed protocols and are not the standard of care in treating AMS.

Diving Injuries

Sturdier portable chambers exist for treatment of diving related injuries. Although there are a number of hard, small recompression chambers used in commercial diving operations, these chambers are not collapsible or easily portable. Two collapsible chambers are available for treatment of diving injuries. These chambers are used primarily by the USN and commercial diving operations. They are collapsible and pressurized with air from a scuba cylinder while the patient breathes 100% oxygen from a face mask. The patient can be transported within the portable chamber to a large recompression facility and moved under pressure into a large multiplace chamber. Unlike the lightweight portable chambers used for treatment of altitude illnesses, these have a working pressure of 2.8 ATA or 27 psi (equivalent of 60 fsw).

The SOS Hyperlite Hyperbaric Stretcher is the most widely used collapsible chamber for treatment and transportation under pressure of a patient suffering from DCS or AGE to a permanent recompression chamber (Figure 78-7). The chamber is made of Kevlar and has two removable endplates with communication system and availability to deliver 100% oxygen to the patient. It is capable of a standard treatment depth of 2.82 ATA and weighs approximately 75 kg (165 lb). Also called the Emergency Evacuation Hyperbaric Stretcher (EEHS), it has received certification for use within the U.S. Department of Defense and is currently in use by the U.S. Coast Guard, all four services of the U.S. military, the Russian Navy, and the U.S. space agency, NASA.

FIGURE 78-7 The Hyperlite by SOS Limited is compressed with air from a scuba cylinder. The injured diver breathes 100% oxygen from a separate oxygen bottle.

Another collapsible and portable hyperbaric chamber is the Italian-made GSE chamber. A smaller version, the Hyperbaric Backpack, is available. This chamber is 76 cm (30 inches) in diameter, 2 m (7 feet) long, and weighs 42 kg (92 lb). It is a double bag of translucent composite polyester and specified for 6 ATA. Another chamber, the Chamberlite 15, is probably the simplest and one of the lightest units on the market. It is capable of providing 100% oxygen at 2 to 2.4 ATA pressure with special adapters. This unit is constructed of foldable polyurethane, has 10 viewing ports, and weighs less than 18 kg (40 lb), thus making it highly portable by standard stretcher or two-person carry. However, depth of treatment is limited, because treatment of diving injuries requires a minimum treatment depth of 2.82 ATA. It has been used in studies on carbon monoxide (CO) poisoning and may be a useful tool for emergency treatment of CO poisoning in the field.¹⁶¹

CNS Oxygen Toxicity

CNS toxicity occurs during oxygen exposures of 1.4 atm or greater. Symptoms may include dizziness, irritability, tunnel vision, tinnitus, nausea, and seizures. The incidence of oxygen-induced seizures is about 1/10,000 patients treated at 2.4 ATA. Susceptibility to oxygen-induced seizures varies among individuals and in any single individual from day to day. Factors that increase susceptibility include exertion, increased PCO₂, increased metabolic rate from fever, thyrotoxicosis, adrenal stress, and acute cerebral injury. Catecholamines can lower the seizure threshold and increase the risk for CNS O₂ toxicity. Oxygen-induced seizures are self-limited and resolve quickly after discontinuing oxygen. No permanent neurologic sequelae have been reported from HBO-induced seizures, and anticonvulsants are not indicated. Intermittent exposure to brief periods of air during HBOT significantly extends oxygen tolerance and prevents oxygen toxicity.

Pulmonary Oxygen Toxicity

Symptoms of early pulmonary oxygen toxicity include substernal burning, slight cough, mild dyspnea, and chest tightness and can be seen in patients treated for decompression sickness, air embolism, and gas gangrene when treatments are prolonged. These symptoms resolve after discontinuing therapy. Pulmonary oxygen toxicity is rare using current treatment tables. Patients do not experience significant alteration in pulmonary gas exchange when treated with standard HBO treatment protocols.²⁰¹