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SAM-TDR-64-6.EN OCRINE AND METABOLIC EFFECTS OF SHORT-DURATION HYPEROXIA It C5) TECHNICAL DOCUMENTARY REPORT NO. SAM-TDR-64-6 February 1964 USAF School of Aerospace Medicine Aerospace Medical Division (AFSC) Brooks Air Force Base, Texas Task No. 775801
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FOREWORD This report was prepared by the following personnel in the Physiology Department: HENRY B. HALE, Ph.D. EDGAR W. WILLIAMS, B.A. JOHN E. ANDERSON, M.A. JAMES P. ELLIS, JR, M.A. Statistical analyses were performed by Richard C. MeNee, Biometrics Department.
A1BSTRACT This investigation was concerned with the effects of breathing 1000/c oxygen (by mask) at I atmosphere ambient pressure for 4 hours on sympathoadrenal, adrenocortical, and metabolic functions in healthy human subjects. Control determinations were made on the same subjects on a separate- occasion by having the subjects breathe room air (by mask). Sympathoadrenal activity was appraised by means of urinary epinephrine and norepinephrine determinations; adrenocortical activity was appraised by means of plasma cortisol and urinary 17-hydroxycorticosteroid determinations; and metabolic appraisal was made by means of urinary creatinine, urea, uric acid, phosphate, potassium, and sndiim. Evidence of hyperoxia-induced adrenocortical and sympathoadrenal depression was found-plasma cortisol concentration, as well as catecholamine excretion, falling below the control levels. Urine volume also was relatively low, as were urinary sodium and phosphate values. Mask discomfort was shown to be an obscuring factor, since it acted oppositely to hyperoxia in many respects. This technical documentary report has been reviewed and is approved. ROBERT B. PAYNE Colonel, USAF, MSC Chief, Operations Division
ENDOCRINE AND METABOUC EFFECTS OF SHORT-DURATION HYPEROXIA 1. INTRODUCTION against the valve seat, and no ambient air can be admitted to the mask through this chan- Additional knowledge of the physiology of nel. The regulator is a simple mechanism hyperoxia is needed in view of the frequent use operated by normal changes in pressure occurof 100'; oxygen by flying personnel and ring during the breathing cycle. Thermal cornastronauts during preflight periods and by re- fort was insured by having air temperature in search and training personnel prior to decom- the test chamber constant at 7 5 - F. Baropression in altitude chambers. The possibility metric pressure approximated 750 mm. Hg. To that preflight hyperoxia may be a predisposing offset pre-existing variation in metabolic status factor for subsequent stresses seems not to in the subjects at the different test times, have been investigated extensively, nor is there half of the subjects breathed oxygen on the much knowledge on the compensatory responses first occasion and room air on the second, while to high oxygen pressure. Sympathetic and the remaining subjects were tested in the neuroendocrine changes during hyperoxia seem opposite order. Television programs were likely since a parasympathetic response to viewed by the subjects during both tests. hyperoxia has been demonstrated in the human (3). Logically, sympathoadrenal and Venous blood samples taken terminally were adrenocortical depression would be beneficial in analyzed for cortisol, using the method of hyperoxia, since it is known that epinephrine Sweat (14), which relies on sulfuric acidand corticosteroids havu enhancing effects on induced fluorescence. Preliminary (pretest) oxygen toxicity (11). The present investiga- cortisol determinations, although highly detion, which was preliminary in nature, deals sirable, were not made because it was thought 'plb gmnnbnnranl, n~~rnnrtv~u *'~fl-~ -mnpntn,n -e 1t thine- nri-ll- time muorjt sponses to hyperoxia in healthy human sub- have an obscuring influence on physiologic jects. In addition, certain metabolic functions responses to hyperoxia. were examined for evidence of oxygensensitivity. Urine samples taken terminally were analyzed for 17-hydroxycorticosteroids (17-2. METHODS OHCS) by means of the Reddy method (13), which is based on the phenylhydrazine reaction. A group of 24 healthy adult men was These determinations, along with plasma corstudied on two occa-ions, with the time between tisol, provide means for assessing adrenocortests amounting to n.i,,'e ihan a week. On both tical activity. occasions, the subjects rested in rcjining chairs from 0800 to 1200 hours, wearing aviator-type Urinary epinephrine and norepinephrine oxygen masks wt..'4h ' eie strapped tightly to determinations were made by means of a the face and connected to diluter-demand modification of the trihydroxyindole mcthod oxygen regulators whic-h delivered either pure (4). Epinephrine excretion relates to adrenooxygen (the e'm:rimeiial situation) or room medullary activity primarily, while norepinephair (control situaaon). The mask contains a rine reflects changes in sympathetic nerves single flapper valve wh- h permits the expired (15). The Technicon AutoAnalyzer was used air to be blown off to the outside atmosphere. to measure urinary creatinine, urea, uric acid, During inspiration, the flapper seals tightly inorganic phosphate, potassium, and sodium. I
These latter urinary constituents reflect any that appear in blood (10), the lag time changes in nitrogen and mineral metabolism, amounting to about 2 hours. Urinary 17-OHCS as well as changes in acid-base balance. determinations apparently are not as useful as plasma cortisol determinations in short-term 3. RESULTS hyperoxia studies. In future studies, posthyperoxia urinary determinations are, therefore, Evidence of slight adrenocortical depression to be used. was found--cortisol values for hyperoxia and normoxia averaging, respectively, 6.2 and 7.8 Evidenas obtain of. sho wn in,,g.1100 ml. plasma (P <.025). The value sympathoadrenal depression. As shown in obtained during normoxia is not statistically statically table 1, norepinephrine excretion, as well as different from one obtained previously (9) for nonstressed adult males (8.2 pg./100 ml. plasma); the value obtained during hyperoxia, Summary of results however, is significantly below this level (P <.005). Urinary variabl Experimental condition Normoxia Hyperoxia A strict time schedule was followed to have the normoxia and hyperoxia tests agree precisely with respect to time of day. Since Epinephrine (g.) Norepinephrine (4g.) 1. 5.16 0.86 2.88 <.01 <.01 plasma cortisol concentration normally falls Ratio: NE/E 4.2 5.3 <.001 progressively throughout the morning hours 1U7-OHCS (pg.)* 288 325 NS (1, 10), nonadherence to a strict time schedule Urine volume (ml./hr.) 103 60 S.001 would have made interpretation impossible. Creatinine (eg.)hr.) 82 80 NS The slightly lower cortisol value found after Urea (gin.) 1.46 1.33 NS 4 hours of oxygen breathing, therefore, can be Uric acid (iag.) 31 32 NS considered physiologically meaningful, and Potium (meq.) 5 5.1 NS oxygen influence on the processes that underlie Sodium (m g.) 1. 1. <.01 or control the diurnal shift may be inferred. Phosphate (as F) 3.g. 40 28 <.01 Since oxygen effects (at 1 atmosphere) are Ratio a/k 3.4 _.6.0 known to be slow in onset, generally not appear- Except where otherwise indicated. urinary constituents are ing in the first 4 hours (11), it is not surprising pearied 1 as quantity/lee mg... eatinine. to find this effect to be low in magnitude. n 2. epinephrine excretion, was lower during In processing the urine samples, it was hyperoxia than during normoxia. The reducnecessary to store them temporarily in a tion in norepinephrine excretion amounted to freezer. Unfortunately, electrical power failure 44/., while that for epinephrine amounted to occurred which caused thawing of some of the 57',;. These differences in magnitude of reurine samples; consequently, the urinary 17- duction suggest that the two parts of the OHCS data were incomplete. Based on the sympathoadrenal system differ in oxygendata for only 12 of the 24 subjects, urinary sensitivity. This differential effect is evident 17-OHCS excretion during normoxia agreed in the norepinephrine/epinephrine ratio with that found previously for nonstressed men (NE/E). (the mean value for the present group was 288 Ig./100 mg. creatinine, while that found It was recognized that mtisk discomfort previously was 280 Ag./100 mg. creatinine). would be a factor in both test situations. Other The mean value obtained when these 12 sub- investigators (11) have noted that mask effects jects experienced hyperoxia was 325.g.1100 may obscure effects of hyperoxia. To test for mg. creatinine, but this value does not differ mask influence, the present results were comstatistically from either of the above values, pared with those obtained previously for non- Changes in urinary corticosteroids lag behind stressed (nonmasked) subjects. The present 2
group, when normoxic, had the same mean mg. creatinine. This suggests that the oxygen NE/E ratio as the nonmasked group (for both, mask was influential on sodium excretion and the mean NE/E value was 4.2); however, that hyperoxia was a partially counteracting epinephrine and norepinephrine values were factor. Of importance is the finding that the relatively high, which suggests that the mask mean Na/K ratio following hyperoxia aphad a stimulatory effect on the sympatho- proached that found for nonmasked subjects adrenal system. Despite this opposing in- (who averaged 2.4 meq. sodium per meq. fluence, hyperoxia-induced depression was potassium). Phosphate excretion during norclearly demonstrated. moxia was high relative to the value found in nonmasked subjects who averaged 30 mg./100 Urine volume differences (table I) also seem mg. creatinine. In this respect, there also to represent mask-oxygen interplay. Accord- seems to have been interplay between the ing to Currie and Ullmann (2), breathing factors of oxygen pressure and mask discomthrough external airway resistances leads to fort. polyuria, not because of differences in tidal or minute volume of ventilation or chemical 4. DISCUSSION changes in the blood, but rather because of intrathoracic pressure fluctuations which re- This study, while only preliminary, gave flexively depress antidiuretic hormone secre- fairly definitive results. Evidence of adrenotion. The finding of a lower rate of urine flow cortical and sympathoadrenal depression was during hyperoxia suggests that oxygen in found, and there was evidence of mask-oxygen excess has a counteracting influence on mask- interaction. Although the primary interest induced changes. The site at which oxygen was on effects of oxygen-breathing, the finding acts to reduce urine output remains to be deter- of mask-hyperoxia interplay seems a valuable mined. The finding of reduced urine output one, since mask discomfort and preflight in association with reduced plasma cortisol con- hyperoxia are factors in the flying situation centration and reduced catecholamine excretion as well as in decompression studies. These is of interest, since impaired excretion of water factors, in combination, undoubtedly have has been observed following adrenalectomy, and contributed to results obtained in many experitreatment with either corticosteroids or mental studies and may have made interpretacatecholamines improves water excretion in tions difficult. Recently, Marchbanks et al. (9) adrenalectomized animals (12). evaluated adrenocortical, sympathoadrenal, and metabolic aspects in pilots flying single-place, high-performance aircraft and found, by means Despite the variation in urine output, ofteesm plmanduirydemncreatinine excretion did not vary significantly of these same plasma and urinary determina- (table I). With creatinine variation thus tions, variation not seen in pilots who were shown to be random in character, all other off-duty. Comparison of the results for norurinary constituents were expressed as ratios moxic, mask-wearing subjects in the present with creatinine. Along with creatinine, in- experiment with the results for one of the significant variation was found for potassium, flying groups proved interesting. The flying urea, and uric acid (table I). On the basis group averaged 1.82 pg. epinephrine, which is of these findings, it does not seem that general only slightly higher than the value obtained in of hes fidinsit oesnotsem tat eneal the present mask-breathing, normoxic group metabolic status was greatly different on the tepeetms-rahnnroi ru mtabolistocatsi as. g(1.30 pg.). The same is true for their norepitwo test occasions. nephrine excretion, the flying group averaging 5.72 pg. and the masked group averaging Urinary sodium and phosphate differentiat- 5.16 pg. The mean NEiE ratio for the flying e(l hyperoxia from normoxia (table I). The group was 3.2, while that for the masked group sodium values, on bhh occasions, were high was 4.2. Urinary 17-OHCS values for these in comparison with the previously studied non- two groups were also similar, the flying group stressed subjects who averaged 8.1 meq. 100 averaging 298 pg. and the masked group 3
averaging 288 1g. However, the flying group tomy led to increased resistance to hyperoxia averaged 13.2 1g. of cortisol per 100 ml. plasma, and that administration of cortisone counterwhich is significantly above the level noted in acted the beneficial effect of adrenalectomy. the masked group (7.8 ag./100 ml. plasma). Gerschman and Fenn (7) noted that rats kept Mask discomfort, therefore, may have been a in pure oxygen at 1 atmosphere showed no contributing factor in the catecholamine re- signs of adrenocortical stimulation nor nympsponse to flight, but it does not account for toms of oxygen poisoning; with higher oxygen the plasma cortisol response to flight. The pressures, symptoms of oxygen poisoning apflying group did not show abnormal phosphate peared and there was evidence of adrenocorexcretion, but in sodium excretion they ap- tical stimulation. It is well established that proached the level found for the present masked oxygen effects are roughly proportional to the (normoxic) group, averaging 14.6 meq./100 partial pressure and duration of exposure (11); mg. creatinine (the masked group averaged and it is logical to think that, with oxygen 16.5 meq.). There was further resemblance pressure at only 1 atmosphere, adrenocortical in that the flying group had a mean Na/K depression may account, in part, for the slow ratio of 3.6 (the masked group averaged 3.4). onset of symptoms. Since the evidence points Mask discomfort, which is one of the many toward sympathoadrenal depression as well, it factors in the flying complex, seemingly ac- seems that generalized neuroendocrine deprescounts for a number of the so-called "flight" sion represents an early response to hyperoxia. effects. Individuals vary greatly in their reactions to oxygen, and a given individual may vary great- Apart from these practical considerations, ly on different occasions (11). It may be that the finding of evidence of adrenocortical de- neuroendocrine status contributes to this pression is of interest, and it may be inter- variability. Of some pertinence is the finding preted as a compensatory change. Support for of seasonal variation in catecholamine excretion this comes from the study of Gerschman et al. (5, 8). We are, therefore, currently investigat- (6), who showed (in rodents) that adrenalec- ing oxygen-sensitivity in relation to season. REFERENCES I. Brown, H., E. Englert, Jr., S. Wallach, and E. L. 7. Gerschman, R., and W. 0. Fenn. Ascorbic acid Simons. Metabolism of free and conjugated content of adrenal glands of rats in oxygen 17-hydroxycorticosteroids in normal subjects. poisoning. Amer. J. Physiol. 176:6-8 (1954). J. Clin. Endocr. 17:1191.1201 (1957). F. Hale, H. B., E. W. William., and J. P. Ellis, Jr. 2. Cmurie, J. C. M., and E. Ullmann. Polyuria during Catecholamine excretion in heat-acclimatized experimental modifications of breathing. J. men. SAM-TDR-63-20. Mar. 1963. Physiol. (London)I 155:435-455 119611. ). Msarchbanks, V. H., Jr., H. B. Hale, and J. P. 3. D)aly, W. J., and S. Bondurant. Circulatory ef- Ellis, Jr. Stress responses of pilots flying 6- fects of oxygen breathing. Aerospace Med. hour overwater missions in F-100 and F-104 31:333 (1962). aircraft. Aerospace Med. 34:15-18 (19631. 4 4. Feller, It. P. Modification of the trihydroxyin- 1W. Migeon, C. J., F. H. Tyler, J. P. Mahoney, A. A. dole method for the estimation of epinephrine Florentin, H. Castle, E. L. Bliss, and L. T. and norepinephrine in urine. SAM Report 60- Samuels. The diurnal variation of plasma levels 71, Aug. 11960. and urinary excretion of 17-hydroxycorticoster-.9. Feller., I. P., and It. B. lhale. Hluman synpatbt,- oids in normal subjects, night wurkers, and adrenal responsiveness in autumn, winter, and blind subjects. J. Clin. Endocr. 16:622-0;3 spring. SAM-TI)R-63-46, June 1963. (1956).. Gerschnman, it., I). I.. Gilbert, S. W. Nye, 1P. W. ll. Mullinax, P. F., Jr., and D. E. Beischer. Oxygen Nadig, and W. 0. Fenn. Role of adrenalectomy toxicity in aviation medicine. An analysis of and adrenal-cortical hormones in oxygen poison- recent literature. J. Aviation Med. 29:660-667 ing. Amer. J. Physiol. 178:346-350 (1954). (1958).
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