Absolute quantification (ml blood/sec ∗ mm2 tissue) of normal vs. diabetic foot skin microvascular blood perfusion: Feasibility of FM-PPG measurements under clinical conditions.

Fluorescence-mediated photoplethysmography (FM-PPG) is the first routine clinical methodology by which to quantifiably measure tissue blood perfusion in absolute terms (mL blood/sec ∗ mm2 tissue). The FM-PPG methodology has been described in detail previously in this journal (MVR 114, 2017, 92-100), along with initial proof-of-concept measurements of blood perfusion in both ocular and forearm skin tissues. The motivation for the current study was to investigate whether FM-PPG can be used readily and routinely under realistic clinical conditions. The vehicle for doing this was to measure medial foot capillary blood flow, i.e., tissue perfusion, in 7 normal subjects, mean = 6.76 ±â€¯2.29 E-005 mL/(sec ∙ mm2), and lesion-free areas of 8 type-2 diabetic patients with skin ulceration, mean = 4.67 + 3.15 E-005 mL/(sec ∙ mm2). Thus, perfusion in the diabetics was found to be moderately lower than that in the normal control subjects. Earlier skin perfusion measurements in medial forearms of 4 normal subjects, mean = 2.64 + 0.22 E-005 mL/(sec ∙ mm2), were lower than both the normal and diabetic foot perfusion measurements. Variability in the heartbeat-to-heartbeat blood perfusion pulses in the skin capillaries, defined as the ratio of the standard deviation among beat-to-beat pulses divided by the mean perfusion of those pulses, was determined for each subject. Average variability in foot skin was 21% in the diabetic population, versus 16% for normal subjects; and it was 18% in forearm skin. We conclude that absolute quantitative FM-PPG measurement of skin blood perfusion at the level of nutritive capillaries is feasible routinely under clinical conditions, allowing for quantitative measurement of skin tissue blood perfusion in absolute terms.

Involvement of platelet-endothelial cell adhesion molecule-1 in neutrophil recruitment in vivo.

During inflammation, neutrophils migrate from the vascular lumen into extravascular sites. In vitro assays have suggested that platelet-endothelial cell adhesion molecule-1 [PECAM-1 (CD31)], a member of the immunoglobulin superfamily, is required for the transmigration of neutrophils across endothelial monolayers. Antibody to human PECAM-1, which cross-reacts with rat PECAM-1, was found to block not only in vivo accumulation of rat neutrophils into the peritoneal cavity and the alveolar compartment of the lung but also neutrophil accumulation in human skin grafts transplanted onto immunodeficient mice. On the basis of these findings in three different models of inflammation, it appears that PECAM-1 is required for neutrophil transmigration in vivo and may thus be a potential therapeutic target.

Nitric oxide production and perivascular nitration in brain after carbon monoxide poisoning in the rat.

Nitric oxide is a short-lived free radical and physiological mediator which has the potential to cause cytotoxicity. Studies were conducted to investigate whether nitric oxide, and the potent oxidant peroxynitrite, were generated in brain during experimental carbon monoxide (CO) poisoning in the rat. Nitric oxide production was documented by electron paramagnetic resonance spectroscopy, and found to be increased by ninefold immediately after CO poisoning. Evidence that peroxynitrite was generated was sought by looking for nitrotyrosine in the brains of CO-poisoned rats. Nitrotyrosine was found deposited in vascular walls, and also diffusely throughout the parenchyma in inummocytochemical studies. The affinity and specificity of an anti-nitrotyrosine antibody was investigated and a solid phase immunoradiochemical assay was developed to quantity nitrotyrosine in brain homogenates. A 10-fold increase in nitrotyrosine was found in the brains of CO-poisoned rats. Platelets were involved with production of nitrotyrosine in the early phase of exposure to CO. However, nitrotyrosine formation and leukocyte sequestration were not decreased in thrombocytopenic rats poisoned with CO according to the standard model. When rats were pre-treated with the nitric oxide synthase inhibitor, L-nitroarginine methyl ester, formation of both nitric oxide and nitrotyrosine in response to CO poisoning were abolished, as well as leukocyte sequestration in the microvasculature, endothelial xanthine dehydrogenase conversion to xanthine oxidase, and brain lipid peroxidation. We conclude that perivascular reactions mediated by peroxynitrite are important in the cascade of events which lead to brain oxidative stress in CO poisoning.

Platelet function in humans is not altered by hyperbaric oxygen therapy.

A pilot survey of platelet function was performed on 6 patients undergoing hyperbaric oxygen therapy (2.0 ATA O2 for 2 hours, 6 days/week) for prophylaxis against osteoradionecrosis. Blood was drawn immediately prior to and after the first, tenth and twentieth treatment for measurements of platelet aggregation, ATP release and expression of activated alphalIb3 integrin. No significant differences were observed due to hyperbaric oxygen exposures.

Oxygen-dependent antagonism of lipid peroxidation.

Measurements of the rates for formation of conjugated dienes, malonylaldehyde, and lipid hydroperoxides show that increasing the concentration of O2 from 0.11 mM to 0.35 mM or 0.69 mM can slow the rate of linoleic acid peroxidation in a xanthine oxidase/hypoxanthine system. This effect is seen at pH 7.0 but not 7.4 and depends on the presence of monounsaturated fatty acids (oleic, cis, or trans vaccenic acid). Oxygen antagonism of ascorbic acid-iron-EDTA mediated lipid peroxidation is similarly dependent on fatty acid mixtures and occurs at pH 5.0 and 6.0 but not 7.0. The efficiency of initiation of peroxidation in the xanthine oxidase system is unaffected by monounsaturated fatty acids and O2 concentration. Increasing the O2 concentration increases the rate of superoxide radical production, but there is no change in salicylate hydroxylation (e.g., OH. production) or ferrous ion concentration. Oxygen-mediated slower rates of lipid peroxidation are associated with either increased H2O2 production or, based on an indirect assay, singlet O2 production. Increased O2 concentrations increase the rate of azobisisobutyronitrile-initiated lipid peroxidation as expected but addition of exogenous superoxide radicals slows the rate. Under similar conditions superoxide reacts with fatty acids to produce singlet O2. Overall, the data suggest that O2-mediated antagonism occurs because of termination reactions between hydroperoxyl (HO2.) and organic radicals, and singlet O2 or H2O2 are products of these reactions.

A model of wound healing in chronically radiation-damaged rat skin.

The aim of this investigation was to develop a model for studying the chronic effects of radiation on wound healing in the rat. Six months after rats received a single radiation exposure of 20 Gy, a random-pattern dorsal skin flap was elevated. Two weeks after the flap was elevated, irradiated animals showed diminished scar formation and wound breaking strength, as compared with controls (P < 0.05). The effect of hyperbaric oxygen treatment was investigated in some rats who received 20 sessions at 2.4 atmospheres absolute for 90 min daily, 5 days per week, prior to flap elevation and 10 sessions after creation of the flap. Treated animals showed a trend toward improvements in wound breaking strength and scar formation (P = 0.06). A reproducible model of chronic radiation damage in the rat was established. Further studies involving investigations at times more that 2 weeks post-wounding are needed.

Carbon monoxide-mediated brain lipid peroxidation in the rat.

Clinical and animal data suggest that the pathogenesis of CO poisoning extends beyond the inhibition of hemoglobin function, but no mechanism has been identified. Evidence of neurological compromise, particularly loss of consciousness, has been implicated as a marker for increased mortality and morbidity in clinical reports. Experiments were carried out with rats to assess whether CO exposure may cause brain lipid peroxidation. With the use of two methods, measurement of conjugated dienes and thiobarbituric acid reactivity, brain lipid peroxidation could be documented as a result of exposure to CO at a concentration sufficient to cause unconsciousness. Products of lipid peroxidation were increased by 75% over the base-line values 90 min after CO exposure. Unconsciousness was associated with a brief period of hypotension, so brief that in itself it caused no apparent insult. Lipid peroxidation occurred only after the animals were returned to CO-free air, and there was no direct correlation with the carboxyhemoglobin level. This work may provide an explanation for a number of currently poorly understood clinical observations regarding CO poisoning.

Dehydrogenase conversion to oxidase and lipid peroxidation in brain after carbon monoxide poisoning.

The conversion of xanthine dehydrogenase to xanthine oxidase and lipid peroxidation were measured in brain from carbon monoxide- (CO) poisoned rats. Sulfhydryl-irreversible xanthine oxidase increased from a control level of 15% to a peak of 36% over the 90 min after CO poisoning, while the conjugated diene level doubled. Reversible xanthine oxidase was 3-6% of the total enzyme activity over this span of time but increased to 31% between 90 and 120 min after poisoning. Overall, reversible and irreversible xanthine oxidase represented 66% of total enzyme activity at 120 min after poisoning. Rats depleted of this enzyme by a tungsten diet and those treated with allopurinol before CO poisoning to inhibit enzyme activity exhibited no lipid peroxidation. Treatment immediately after poisoning with superoxide dismutase or deferoxamine inhibited lipid peroxidation but had no effect on irreversible oxidase formation. Biochemical changes only occurred after removal from CO, and changes could be delayed for hours by continuous exposure to 1,000 ppm CO. These results are consistent with the view that CO-mediated brain injury is a type of postischemic reperfusion phenomenon and indicate that xanthine oxidase-derived reactive oxygen species are responsible for lipid peroxidation.

Release of glutathione from erythrocytes and other markers of oxidative stress in carbon monoxide poisoning.

Rats exposed to CO in a manner known to cause oxidative stress in brain exhibited a twofold increase in plasma levels of oxidized proteins, thiobarbituric acid-reactive substances (TBARS), oxidized glutathione (GSSG), and reduced glutathione (GSH). Changes were neither directly related to hypoxic stress from carboxyhemoglobin nor significantly influenced by circulating platelets or neutrophils. Treatment with the nitric oxide synthase inhibitor N omega-nitro-L-arginine methyl ester inhibited elevations in GSH and GSSG but not changes in oxidized proteins or TBARS, suggesting that two oxidative mechanisms may be operating in this model and that GSH and GSSG elevations involved nitric oxide-derived oxidants. Elevations of blood GSH and GSSG occurred at different anatomic sites, indicating that no single organ was the source of the increased peptides. Animals that underwent exchange transfusion with a hemoglobin-containing saline solution did not exhibit elevations in GSH and GSSG, suggesting that blood-borne cells released these peptides in response to oxidative stress. In in vitro studies, erythrocytes, but not platelets and leukocytes, responded to oxidative stress from peroxynitrite by releasing GSH, whereas no release was observed in response to nitric oxide or superoxide. Glucose, maltose, and cytochalasin B, agents that protect extracellular components of the hexose transport protein complex from oxidative stress, prevented GSH release. The data indicate that nitric oxide-derived oxidants are involved in CO-mediated oxidative stress within the vascular compartment and that elevations of several compounds may be useful for identifying exposures to CO likely to precipitate brain injury.

Effects of carbon monoxide on the brain may be mediated by nitric oxide.

Carbon monoxide (CO) is known to be a toxic molecule due to the high affinity of hemoglobin for it. However, it has recently been shown that low doses of CO may play a physiological role. The aim of the present study was to examine processes occurring in the brain during exposure to 1,000 parts per million CO that result in an increase in cerebral blood flow (CBF) but are not accompanied by changes in oxidation metabolism. This study was carried out in awake rats with the multiprobe assembly developed in this laboratory for the simultaneous continuous measurement of CBF, intramitochondrial NADH redox levels, direct current potential, and extracellular concentrations of K+, Ca2+, and H+ as well as the electrocorticogram. Exposure to 1,000 parts per million CO in air resulted in an increased CBF without any concomitant changes in any of the other metabolic or ionic parameters measured. This indicates that tissue hypoxia was not the trigger for this vasodilation. Injection of N omega-nitro-L-arginine (L-NNA), a nitric oxide synthase inhibitor, before exposure to CO effectively blocked the increase in CBF that was observed when the animal was exposed to CO without prior injection of L-NNA. Furthermore, electrocorticographic depression was observed after the combined treatment of L-NNA and CO. In conclusion, exposure to relatively low doses of CO apparently does not have a deleterious effect on oxidative metabolism because the increase in CBF after this exposure is sufficient to prevent changes in oxidative metabolism, as indicated by the fact that NADH levels remained constant. This protective autoregulatory effect may be mediated by nitric oxide.

Multiparametric monitoring of the awake brain exposed to carbon monoxide.

We have applied in vivo real-time techniques to monitor the physiological changes associated with exposure to a pattern of carbon monoxide (CO) known to cause brain oxidative stress. Using a multiparametric monitoring device connected to the brain, we exposed unanesthetized rats to two levels of CO, 0.1 and 0.3% in air. Energy metabolism was evaluated by the optical monitoring of relative cerebral blood flow (CBF) and intramitochondrial redox state. Ionic homeostasis was assessed by measurements of K+,Ca2+, and H+ or Na+ levels in the extracellular space. The electrical parameters monitored were the electrocorticogram and direct current steady potential. Under 1,000 ppm of CO, the CBF was increased significantly without any measurable change in the NADH redox state, suggesting that the cause for the increased CBF was not hypoxia. Exposing the awake rat to 1,000 ppm of CO (40 min) followed by 3,000 ppm of CO (20 min) led to an increase in CBF followed by episodes of spontaneous brain depolarizations characterized by changes in ionic homeostasis and blood flow. These changes were similar to those recorded under cortical spreading depression. In most animals exposed to 3,000 ppm of CO, spontaneous oscillations in CBF and NADH redox state that were negatively correlated were recorded. The results indicate that an inspired CO level of 0.1% had effects largely restricted to blood flow, whereas at a higher CO level an additional impairment in energy supply resulted in a complex pattern of effects similar to that caused by brain ischemia.

Carbon monoxide poisoning--a public health perspective.

Carbon monoxide (CO) may be the cause of more than one-half of the fatal poisonings reported in many countries; fatal cases also are grossly under-reported or misdiagnosed by medical professionals. Therefore, the precise number of individuals who have suffered from CO intoxication is not known. The health effects associated with exposure to CO range from the more subtle cardiovascular and neurobehavioral effects at low concentrations to unconsciousness and death after acute or chronic exposure to higher concentrations of CO. The morbidity and mortality resulting from the latter exposures are described briefly to complete the picture of CO exposure in present-day society. The symptoms, signs, and prognosis of acute CO poisoning correlate poorly with the level of carboxyhemoglobin (COHb) measured at the time of hospital admission; however, because CO poisoning is a diagnosis frequently overlooked, the importance of measuring COHb in suspicious settings cannot be overstated. The early symptoms (headache, dizziness, weakness, nausea, confusion, disorientation, and visual disturbances) also have to be emphasized, especially if they recur with a regular periodicity or in the same environment. Complications occur frequently in CO poisoning. Immediate death is most likely cardiac in origin because myocardial tissues are most sensitive to the hypoxic effects of CO. Severe poisoning results in marked hypotension, lethal arrhythmias, and electrocardiographic changes. Pulmonary edema may occur. Neurological manifestation of acute CO poisoning includes disorientation, confusion, and coma. Perhaps the most insidious effect of CO poisoning is the development of delayed neuropsychiatric impairment within 2-28 days after poisoning and the slow resolution of neurobehavioral consequences. Carbon monoxide poisoning during pregnancy results in high risk for the mother by increasing the short-term complication rate and for the fetus by causing fetal death, developmental disorders, and chronic cerebral lesions. In conclusion, CO poisoning occurs frequently; has severe consequences, including immediate death; involves complications and late sequelae; and often is overlooked. Efforts in prevention and in public and medical education should be encouraged.

Preliminary report on the effect of hyperbaric oxygen on cystoid macular edema.

The treatment of established cystoid macular edema has been enigmatic. This is a preliminary study of five patients treated by intermittent hyperbaric oxygen with an intensive regimen of 1.5 hours two times per day for seven days and two hours per day for an additional 14 days. Visual acuity improved within 14 days in all five patients: One patient improved from 20/40 to 20/15, one from 20/50 to 20/25, one from 20/200 to 20/40, one from 20/70 to 20/25, and one diabetic patient improved from 20/70 to 20/25. Vision has tended to regress with time.

Blood flow and ionic responses in the awake brain due to carbon monoxide.

This study examined the effect of 2000 ppm CO on the brain of an awake rat. Measurements of regional perfusion as well as metabolic, ionic and electrical activities were used to examine whether mechanisms responsible for changes in brain perfusion were separable from those attributable to compromises in neuronal metabolism. Exposure to 2000 ppm CO resulted in elevation of cerebral blood flow. The stability of mitochondrial NADH redox level during CO exposure indicated that tissue hypoxia did not develop. The elevation in blood flow was inhibited by L-nitroarginine methyl ester, indicating that nitric oxide was responsible for the CO-induced elevation in blood flow. Exposure to 2000 ppm CO also triggered a significant decrease in pH and rise in extracellular potassium ion, possibly due to ion-pump inhibition. The amplitude of the electrocorticogram wave activity decreased, indicative of a compromise to physiological activity. These changes were not observed in rats anesthetized with pentobarbital during CO exposure, although anesthesia had no effect on the CO-induced elevation in blood flow and there was still no change in mitochondrial NADH redox level. We concluded that CO acts by separate mechanisms to alter cerebral vasoactivity and neuronal metabolic responses and that both processes are independent of hypoxic stress.

Mechanism of oxidative stress from low levels of carbon monoxide.

The purpose of this study was to determine whether platelets and vascular endothelial cells would liberate nitric oxide free radical (NO)* and NO-derived oxidant species after exposure to carbon monoxide (CO) at concentrations up to 100 parts per million (ppm). We hypothesized that exposure to environmentally relevant concentrations of CO would increase production of agents that may be involved in human pathological processes, such as atherosclerosis. Platelets obtained from rats released NO when incubated with CO, but CO did not increase platelet nitric oxide synthase activity. Platelets released comparable NO levels when they were exposed to CO in vitro and when taken from rats that had been exposed to CO. Partial pressures of CO as low as 10 ppm could successfully compete with NO for intraplatelet binding sites in in vitro studies. We conclude that CO enhanced the release of NO from platelets because it inhibited NO sequestration by intraplatelet binding sites, and that this phenomenon can occur with exposure to CO concentrations found in the environment. Bovine pulmonary artery endothelial cells released NO in response to CO exposure. Carbon monoxide did not affect the transport of L-arginine across the plasma membrane or nitric oxide synthase activity; therefore, the mechanism appeared to be based on a disturbance of intracellular NO sequestration. Cells incubated with CO also released into the surrounding medium peroxynitrite, an NO-derived oxidant, based on oxidation of dihydrorhodamine 123 and p-hydroxyphenylacetic acid. Peroxynitrite-mediated oxidative stress to endothelial cells was identified as increased concentrations of nitrotyrosine in cell lysates, and by measuring the release of radioactive chromium. Carbon monoxide caused an acute injury when cells were continuously exposed for 4 hours, and a delayed injury when cells were exposed for 2 hours. Delayed injury was documented by leakage of radioactive chromium and by uptake of a vital fluorescent stain, ethidium homodimer-1, between 6 and 20 hours after CO exposure. Oxidative stress caused by CO exhibited several unique aspects because CO exposure did not alter the cellular content of reduced sulfhydryls nor did CO augment oxidative stress caused by superoxide, hydrogen peroxide, or a flux of NO. We concluded that concentrations of CO achieved in vivo when humans are exposed to CO concentrations found in the environment can cause endothelial cells to liberate NO and NO-derived oxidants, and that these products can adversely affect cell physiology.

Smoke inhalation.

Appropriate intervention in patients with smoke inhalation requires an understanding of the dynamic aspects of this complex respiratory emergency. This article reviews the etiology, pathophysiology, and treatment of the smoke inhalation injury.

Use of hyperbaric oxygen in toxicology.

HBO has become recognized as a potential treatment for a variety of toxins. HBO is helpful because it provides an excess of dissolved oxygen, which not only can sustain life in the absence of hemoglobin, but in some cases can actually increase the clearance of toxins. In addition, it is now apparent that HBO serves more complex roles in toxicological injuries, such as modifying PMN-endothelial interactions and preventing oxidative tissue injury. The major drawback of HBO therapy is the lack of controlled clinical trials, partly due to the rarity of most of the toxins discussed. In fact, the field of hyperbaric medicine has come under increasing criticism for this failure. There is a physiologic basis for use of HBO in the toxins discussed. Unfortunately, only for CO is patient volume adequate for studies to document efficacy. Regarding the other toxins mentioned, the use of HBO should be reserved for carefully selected cases in which patients have failed routine care or are at risk for delayed effects.

Smoke inhalation-induced alveolar lung injury is inhibited by hyperbaric oxygen.

Smoke-induced lung injury in rats was assessed in terms of histopathology, gross mortality, neutrophil accumulation and as capillary leak. Administration of hyperbaric oxygen (HBO2), 2.8 atm abs for 45 min, inhibited adhesion of circulating neutrophils subsequent to smoke inhalation. HBO2 reduced pulmonary neutrophil accumulation whether used in a prophylactic manner, 24 h before smoke inhalation, or as treatment immediately after the smoke insult Emphasis was placed on prophylactic administration of HBO2 to avoid the possibility that beneficial effects may be related to hastened removal of carbon monoxide. Based on all parameters tested, smoke inhalation injury was reduced by prophylactic aadministration of HBO2. The beneficial effect appears related to inhibition of neutroophil adhesion to the vasculature.

Neutrophil sequestration and the effect of hyperbaric oxygen in a rat model of temporary middle cerebral artery occlusion.

A rat model of reversible occlusion of the middle cerebral artery was developed to assess the role of neutrophils and prophylactic hyperbaric oxygen (HBO2) on cerebral injury. Blood flow to the ipsilateral caudate putamen nucleus was reduced by approximately 50% during 2 h of arterial occlusion, but unaffected on the contralateral side. Neutrophil accumulation in brain was documented as myeloperoxidase concentration, which was elevated in both ipsilateral and contralateral cerebral hemispheres at 1 and 46 h after occlusion/reperfusion. HBO2 administered before ischemia at 2.8 atm abs for 45 min, as well as antibody-induced neutropenia, reduced neutrophil accumulation, functional neurologic deficits, and cerebral infarct volume. These data demonstrate that one mechanism for benefit of HBO2 is related to its ability to ameliorate post-ischemic injury by inhibiting neutrophil sequestration. This mechanism should be taken into consideration when choosing partial pressures of oxygen for investigational clinical protocols.

Ventriculo-peritoneal shunt performance under hyperbaric conditions.

A novice scuba diver with an implanted ventriculo-peritoneal (VP) shunt inquired about the performance characteristics of his shunt while diving. A literature search revealed no information regarding shunt performance under hyperbaric conditions. The manufacturer could not certify that the shunt would function under pressure. Therefore, four VP shunts were tested according to the manufacturer's testing protocol at 1 and 4 atm abs in a multiplace hyperbaric chamber. The pressure (in mm of H2O) required to establish flow through the shunts was recorded. Trials at 1 atm abs (n = 12) and 4 atm abs (n = 12) show that all shunts performed within the pressure range specified by the manufacturer.