Cerebral cortex does not modulate "regulated" decrease in core temperature during hypoxemia in rats

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

Cerebral cortex does not modulate "regulated" decrease in core temperature during hypoxemia in rats

Evvi-Lynn M. Rollins and James E. Fewell

Department of Physiology and Biophysics, University of Calgary, Health Sciences Centre, Calgary, Alberta, Canada T2N 4N1

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

In newborns and adults of a number of species including humans, exposure to acute hypoxemia produces a "regulated" deceasein core temperature, the mechanism of which is unknown. Consideringthat various cortical areas participate in autonomic regulationincluding thermoregulation, the present experiments were carriedout to test the hypothesis that the cerebral cortex plays a rolein modulating the regulated decrease in core temperature duringacute hypoxemia. This hypothesis was tested by determining thecore temperature response to acute hypoxemia in chronically instrumentedadult Sprague-Dawley rats before and after cortical spreadingdepression (i.e., functional decortication) was produced by thelocal application of potassium chloride to the dura overlyingthe cerebral hemispheres. There was no effect of cortical spreadingdepression on baseline core temperature. Core temperature decreasedduring acute hypoxemia in a similar fashion when the cerebralcortex was intact as well as during functional decortication.Thus our data do not support the hypothesis that the cerebralcortex modulates the regulated decrease in core temperature thatoccurs in adult rats during acute hypoxemia.

cortical spreading depression; functional decortication

	INTRODUCTION

Top Abstract Introduction Methods Results Discussion References

IN NEWBORNS AND ADULTS of a number of species including humans, core temperature decreases during acute hypoxemia (6, 24,29). Gordon and Fogelson (17) and Dupre and Owen (10) haverecently shown that the decrease in core temperature during acutehypoxemia in adult rats is a "regulated" rather than a "forced"phenomenon (16) and thus represents an example of "rheostasis"(30), or regulation around a shifted set point, rather thana failure of "homeostasis" (2). The mechanism of this regulateddecrease in core temperature during acute hypoxemia is not known.

Numerous mechanisms have been suggested to elicit the regulated decrease in core temperature during acute hypoxemia. Theseinclude a direct effect hypoxemia on thermosensitive neurons inthe preoptic area of the anterior hypothalamus (39) as wellas the release of various peptides in the central nervous system[e.g., arginine vasopressin (44) and endogenous opioids (26)]that influence thermoregulation. Furthermore, because numerousexperiments have provided evidence that various cortical areasparticipate in autonomic regulation (3), including thermoregulation,it is also possible that the cerebral cortex plays a role in modulatingthe regulated decrease in core temperature during acute hypoxemia.Thus the purpose of the present experiments was to test the hypothesisthat the cerebral cortex plays a role in modulating the regulateddecrease in core temperature during acute hypoxemia. This hypothesiswas tested by determining the core temperature response to acutehypoxemia in chronically instrumented adult rats before and aftercortical spreading depression (i.e., functional decortication)as first described by Leao (22) was produced by the local applicationof potassium chloride to the dura overlying the cerebral hemispheres.

	METHODS

Top Abstract Introduction Methods Results Discussion References

Experiments were carried out on 29 male Sprague-Dawley rats (Charles River Breeding Laboratories, St.-Constant, PQ, Canada)weighing 216 ± 11 g on the day of surgery. The rats were housedin individual cages at 22 ± 1°C in a light-dark cycle with lightson from 0700 to 1900 and were handled at least five times beforean experiment to familiarize the animal with the investigator.All animals had continuous access to food (Lab Diet 5001, St.Louis, MO) and tap water.

Surgical preparation. Each rat was anesthetized by an injection of pentobarbital sodium (65 mg/kg ip). A paramedian laparotomy was done, and a free-floatingbattery-operated biotelemetry device (PhysioTel TA10ETA-F20; DataSciences International, St. Paul, MN) was inserted into the peritonealcavity for later measurement of core temperature. The dorsum ofthe skull was then exposed and holes were drilled over both parietooccipitalcortices using a 4-mm handheld trephine. Care was taken not todamage the dura and to achieve hemostasis. A polyvinyl chloridecylinder (15 mm in diam, 10 mm in height, with a screw cap) witha small flange was then placed within the skin margins and securedwith one or two sutures. A piece of Parafilm was laid over thetrephine holes, and a piece of filter paper, soaked in warm physiologicalsaline, was placed in the cylinder. The cap was screwed onto thecylinder to protect the dura from drying and cooling. The animalswere allowed to recover from surgery and were not studied beforethe 2nd postoperative day.

All surgical and experimental procedures were carried out in accordance with the "Guide to the Care and Use of ExperimentalAnimals" provided by the Canadian Council on Animal Care, andwith the approval of the Animal Care Committee of the Universityof Calgary.

Experimental apparatus. The experiments were carried out with the rats in a metabolic chamber that consisted of a double-walled Perspex cylinder (27cm long, 7.5 cm ID) with a plastic grid along the bottom intowhich flowed room air or 10% O₂ in N₂ at 2.0 l/min. Chamber ambienttemperature was controlled by circulating water from a temperature-controlledbath (Endocal Refrigerated Circulating Bath RTE-8DD; Neslab, Newington,NH) through the space between the walls. For measurement of coretemperature, the metabolic chamber was placed over a platformantennae (PhysioTel CTR 86; Mini-Mitter, Sunriver, OR), whichreceived the output frequency (Hz) from the biotelemetry device;this was interfaced with a peripheral processor (Dataquest III;Data Sciences International, St. Paul, MN) connected to an IBMcomputer.

Experimental protocol. The rats were studied at an ambient temperature of either 27 ± 1°C (i.e., thermoneutral temperature) or 18 ± 1°C. Each animalwas randomly assigned to either a normoxemic or hypoxemic groupand underwent two experiments on successive days. One experimentwas carried out during "functional decortication" produced bycortical spreading depression, and one experiment was carriedout with the rat's cerebral cortex intact; the sequence of thetwo experiments was alternated between animals.

On the day of an experiment, each rat was brought into the laboratory and weighed. To ensure that there was no postoperativedamage to the dura or underlying structures, the animals werethen tested for the presence or absence of bilateral visual andtactile placing reactions (1). If bilateral visual and tactileplacing reactions were present, the rat was then placed into themetabolic chamber for 1 h. After collection of control data, therats were taken out of the metabolic chamber, and a filter papersoaked with either potassium chloride or normal saline was appliedto the dura. The rats were returned to the chamber for 10 minand then removed once more and tested for the presence or absenceof bilateral visual and tactile placing reactions. The rat wasthen returned to the chamber. After 30 min, the O₂ mixture flowinginto the chamber was either left at 21% or changed to 10%, anddata were collected at 6-min intervals for the next 60 min. Atthe end of each experiment, the animal was tested once again forthe presence or absence of bilateral visual and tactile placingreactions.

Cortical spreading depression. Application of depolarizing chemicals (e.g., K⁺; Ref. 23) to the cortex of rats induces so-called spreading depression (i.e.,a slowly spreading wave of neural depolarization and depressionof electroencephalographic activity, which traverses cortex ata rate of ~3 mm/min and lasts ~2 min). The presence of a hypertonicpotassium chloride solution in contact with the cortex will leadto repetitive waves of spreading depression and thus a long-lastingdepression of electroencephalographic activity; this constitutesfunctional decortication (1).

Statistical analysis. Statistical analysis was carried out using a four-factor ANOVA for repeated measures followed by a Student-Newman-Keuls multiplecomparison test to determine whether ambient temperature, time,state of cortex, or gas mixture affected core temperature (43).

	RESULTS

Top Abstract Introduction Methods Results Discussion References

Core temperature decreased during acute hypoxemia when the cerebral cortex was intact as well as during functional decortication(Fig. 1); the overall response was accentuated when the animalswere studied at 18°C compared with 27°C (ambient temperature bygas mixture, P = 0.001). There was no effect of cortical spreadingdepression on baseline core temperature or on the core temperatureresponse to hypoxemia at either ambient temperature (state ofcortex, P = 0.568; state of cortex by ambient temperature, P =0.590; state of cortex by gas mixture, P = 0.241; state of cortexby ambient temperature by gas mixture, P = 0.536). Exposure toacute hypoxemia produced an initial period of excitement, whichwas followed by a period of quiescence; this response was notaffected by functional decortication.

View larger version (36K):
[in this window]
[in a new window]

Fig. 1. Influence of ambient temperature and state of cortex on core temperature before and during acute hypoxemia in adult male rats. Data are means ± SD. C, control period; D, period after application of either potassium chloride or normal saline to dura; E1-E10, experimental periods of acute hypoxemia. * P < 0.05 vs. control by ANOVA and Newman-Keuls.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

Our experiments provide new information regarding possible mechanisms underlying the regulated decrease in core temperatureduring acute hypoxemia in adult rats. A novel finding in our studywas that the decrease in core temperature during acute hypoxemiawas not influenced by functional decortication induced by corticalspreading depression. Thus our data do not support the hypothesisthat the cerebral cortex modulates the regulated decrease in coretemperature during acute hypoxemia in adult rats.

A number of experiments, both anatomical and physiological in nature, have provided evidence that various cortical areas areinvolved in autonomic function (3). For example, experimentscarried out in the 1930s and 1940s showed that surgical decorticationimpaired the ability of dogs, cats, and monkeys to thermoregulatewhen they were exposed to hot or cold environments (7, 32).Moreover, recent experiments utilizing the technique of corticalspreading depression have shown that functional decorticationin rats inhibits warm-sensitive neurons and facilitates cold-sensitiveneurons in the preoptic area of the hypothalamus as well as increasingboth metabolic heat production and operant skin heating behaviorand reducing operant skin cooling behavior (33, 34, 36).The area responsible for this thermoregulatory behavior appearsto be the sulcal prefrontal cortex, a site of convergence of skinand hypothalamic temperature signals (35) and a site known tohave projections to the hypothalamic thermosensitive neurons (18,19). DeLuca et al. (8) have shown that electrical stimulationof the prefrontal but not the parietal or occipital cortex increasesmetabolic rate through activation of the sympathetic nervous system.Shibata et al. (35) have suggested that sulcal prefrontal corticalneurons play a role in processing and integrating thermal signalsarising from different parts of the body, probably in connectionwith the emotional and/or motivational aspect of neural sensationand thermoregulatory behavior.

Cortical spreading depression did not significantly affect baseline core temperature in our experiments; this was true whenthe rats were studied in an ambient temperature at or below thermoneutrality.Our data are in keeping with the results of DeLuca et al. (9),Monda and Pittman (28), and Monda et al. (27) but differ fromthe results of Shibata et al. (36, 37) and Hori et al. (19),who found that cortical spreading depression activated thermoregulatoryeffectors to increase core temperature. Although the reason forthese differences is not readily apparent, it may be related tothe strain of rats used, since the former investigators used Sprague-Dawleyrats, whereas the latter investigators used Wistar rats. The differencesare not related to gender, since both male and female Sprague-Dawleyrats were used in the former investigations.

Previous experiments carried out in our laboratory as well as in the laboratories of others have provided information aboutpossible mechanisms underlying the regulated decrease in coretemperature during acute hypoxemia. For example, experiments carriedout on conscious guinea pigs (11), rats (13, 15, 25),and cats (14) have provided evidence that the carotid chemoreceptorsand/or baroreceptors are not essential for the decrease in coretemperature to occur during acute hypoxemia. In fact, becausecore temperature and O₂ consumption decrease more in carotid-denervatedthan in carotid-intact animals, it appears that the carotid chemoreceptorsand/or baroreceptors actually buffer or moderate the changes inthese variables during acute hypoxemia.

Wood (44) has suggested that an increase in central levels of arginine vasopressin may mediate the changes in core temperatureobserved during hypoxemia. Evidence to support this hypothesisis provided by the following. Hypoxemia stimulates the releaseof arginine vasopressin into plasma (12) and cerebrospinal fluid(38, 42) of animals; intracerebroventricular administrationof arginine vasopressin elicits hypothermia in rats (20, 21,31); arginine vasopressin is an endogenous antipyretic peptidein mammals (5, 41). Conversely, our experiments on core temperatureresponses to hypoxemia in Long-Evans (which have arginine vasopressin-containingcells in central nervous system) and Brattleboro rats (which lackarginine vasopressin-containing cells in central nervous system;Ref. 40) do not support this hypothesis, since core temperaturedecreases more in Brattleboro rats during both moderate and severehypoxemia than in Long-Evans rats (4).

Mayfield et al. (26) have recently provided evidence that endogenous opioids participate in mediating the decrease in coretemperature after hypoxic conditioning in adult mice. In theirexperiments, however, hypoxic conditioning, which consisted ofexposing adult mice to 4.5% O₂ for 1.5, 2.0, and 2.5 min separatedby 5 min of 21% O₂, produced sustained decreases in core temperature.These sustained decreases in core temperature after return tonormoxemia, which are in contrast to previous results obtainedin our laboratory (4), most likely resulted from the severedegree of hypoxemia used during their hypoxic conditioning. Inour view, the role that endogenous opioids play in mediating theregulated decrease in core temperature to a moderate level ofacute hypoxemia remains unknown. Other possible mediators of theregulated decrease in core temperature during hypoxemia includehistamine, adenosine, and $alpha$ -melanocyte-stimulating hormone. Theinfluence of these agents requires further investigation.

	ACKNOWLEDGEMENTS

The authors thank Dr. Francine G. Smith for a critical review of this manuscript.

	FOOTNOTES

This study was supported by The Alberta Children's Hospital Foundation and the Medical Research Council of Canada. This workwas done during J. E. Fewell's tenure as a Senior Medical Scholarof the Alberta Heritage Foundation for Medical Research.

Address for reprint requests: J. E. Fewell, Heritage Medical Research Bldg. 206, University of Calgary, 3330 Hospital Dr., NW, Calgary, AB, Canada T2N 4N1.

Received 8 July 1997; accepted in final form 19 December 1997.

	REFERENCES

Top Abstract Introduction Methods Results Discussion References

1. Bures, J., O. Buresova, and J. P. Huston. Ablation and stimulation of the brain. In: Techniques and Basic Experiments for the Study of Brain and Behaviour. Amsterdam, Netherlands: Elsevier, 1976, p. 171-217.

2. Cannon, W. B. Organization for physiological processes. Physiol. Rev. 9: 399-431, 1929[Free Full Text].

3. Cechetto, D. F., and C. B. Saper. Role of the cerebral cortex in autonomic function. In: Central Regulation of Autonomic Functions, edited by A. D. Loewy, and K. M. Spyer. New York: Oxford Univ. Press, 1990, p. 208-223.

4. Clark, D. J., and J. E. Fewell. Body-core temperature decreases during hypoxic hypoxia in Long-Evans and Brattleboro rats. Can. J. Physiol. Pharmacol. 72: 1528-1531, 1994[Medline].

5. Cooper, K. E., N. W. Kasting, K. Lederis, and W. L. Veale. Evidence supporting a role for endogenous vasopressin in natural suppression of fever in the sheep. J. Physiol. (Lond.) 295: 33-45, 1979[Abstract/Free Full Text].

6. Cross, K. W., J. P. M. Tizard, and D. A. H. Trythall. The gaseous metabolism of the newborn infant breathing 15% oxygen. Acta Paediatr. 47: 217-237, 1958.

7. Delgado, J. M. R., and R. B. Livingston. Some respiratory, vascular and thermal responses to stimulation of orbital surface of frontal lobe. J. Neurophysiol. 11: 39-55, 1948[Free Full Text].

8. DeLuca, B., M. Monda, S. Amaro, and M. P. Pellicano. Thermogenic changes following frontal neocortex stimulation. Brain Res. Bull. 22: 1003-1007, 1989[Medline].

9. DeLuca, B., M. Monda, M. P. Pellicano, and A. Zenga. Corticol control of thermogenesis induced by lateral hypothalamic lesion and overeating. Am. J. Physiol. 253 (Regulatory Integrative Comp. Physiol. 22): R626-R633, 1987[Abstract/Free Full Text].

10. Dupre, R. K., and T. L. Owen. Behavioral thermoregulation by hypoxic rats. J. Exp. Zool. 262: 230-235, 1992[Medline].

11. Fewell, J. E., D. Megirian, and K. M. Stobie-Hayes. Influence of carotid denervation on the body-core temperature and metabolic responses to changes in ambient temperature during normoxemia and acute hypoxemia in guinea pigs during postnatal maturation. Can. J. Physiol. Pharmacol. 75: 104-111, 1997[Medline].

12. Forsling, M. L., and E. Ullmann. Release of vasopressin during hypoxia. J. Physiol. (Lond.) 241: 35P-36P, 1974.

13. Gautier, H., and M. Bonora. Ventilatory and metabolic responses to cold and hypoxia in intact and carotid body-denervated rats. J. Appl. Physiol. 73: 847-854, 1992[Abstract/Free Full Text].

14. Gautier, H., M. Bonora, S. A. Schultz, and J. E. Remmers. Hypoxia-induced changes in shivering and body temperature. J. Appl. Physiol. 62: 2477-2484, 1987[Abstract/Free Full Text].

15. Gautier, H., M. Bonora, and H. C. Trinh. Ventilatory and metabolic responses to cold and CO₂ in intact and carotid body-denervated awake rats. J. Appl. Physiol. 75: 2570-2579, 1993[Abstract/Free Full Text].

16. Gordon, C. J. A review of terms for regulated vs. forced neurochemical-induced changes in body temperature. Life Sci. 32: 1285-1295, 1983[Medline].

17. Gordon, C. J., and L. Fogelson. Comparative effects of hypoxia on behavioral thermoregulation in rats, hamsters, and mice. Am. J. Physiol. 260 (Regulatory Integrative Comp. Physiol. 29): R120-R125, 1991[Abstract/Free Full Text].

18. Hori, T., M. Shibata, T. Kiyohara, and T. Nakashima. Effects of cortical spreading depression on hypothalamic thermosensitive neurons in the rats. Neurosci. Lett. 32: 47-52, 1982[Medline].

19. Hori, T., M. Shibata, T. Kiyohara, and T. Nakashima. Prefrontal cortical influences on behavioural thermoregulation and thermosensitive neurons. J. Therm. Biol. 9: 27-31, 1984.

20. Kasting, N. W., W. L. Veale, and K. E. Cooper. Convulsive and hypothermic effects of vasopressin in the brain of the rat. Can. J. Physiol. Pharmacol. 58: 316-319, 1980[Medline].

21. Kruk, Z. L., and R. T. Brittain. Changes in body core and skin temperatures following intracerebroventricular injection of substances in the conscious rat: interpretation of data. J. Pharm. Pharmacol. 24: 835-837, 1972[Medline].

22. Leao, A. A. P. Spreading depression of activity in the cerebral cortex. J. Neurophysiol. 7: 359-390, 1944[Free Full Text].

23. Leao, A. A. P., and R. S. Morrison. Propagation of spreading cortical depression. J. Neurophysiol. 8: 33-45, 1945[Free Full Text].

24. Legallois, C. Deuxieme memoire sur la chaleur animale. In: Oeuvres. Paris: Le Rouge, 1813, p. 21-66.

25. Matsuoka, T., A. Dotta, and J. P. Mortola. Metabolic response to ambient temperature and hypoxia in sinoaortic-denervated rats. Am. J. Physiol. 266 (Regulatory Integrative Comp. Physiol. 35): R387-R391, 1994[Abstract/Free Full Text].

26. Mayfield, K. P., E. J. Hong, K. M. Carney, and L. G. D'Alecy. Potential adaptations to acute hypoxia: Hct, stress proteins, and set point for temperature regulation. Am. J. Physiol. 266 (Regulatory Integrative Comp. Physiol. 35): R1615-R1622, 1994[Abstract/Free Full Text].

27. Monda, M., S. Amaro, and B. DeLuca. Non-shivering thermogenesis during prostaglandin E₁ fever in rats: role of the cerebral cortex. Brain Res. 651: 148-154, 1994[Medline].

28. Monda, M., and Q. J. Pittman. Cortical spreading depression blocks prostaglandin E₁ and endotoxin fever in rats. Am. J. Physiol. 264 (Regulatory Integrative Comp. Physiol. 33): R456-R459, 1993[Abstract/Free Full Text].

29. Mortola, J. P. Hypoxic metabolism in mammals. News Physiol. Sci. 8: 79-82, 1993.[Abstract/Free Full Text]

30. Mrosovsky, N. Reactive rheostasis. In: Rheostasis. Oxford, UK: Oxford Univ. Press, 1990, p. 77-116.

31. Naylor, A. M., W. D. Ruwe, and W. L. Veale. Thermoregulatory actions of centrally administered vasopressin in the rat. Neuropharmacology 25: 787-794, 1986[Medline].

32. Pinkston, J. O., P. Bard, and D. M. Rioch. The responses to changes in environmental temperature after removal of portions of the forebrain. Am. J. Physiol. 109: 515-531, 1934.

33. Shibata, M., T. Hori, T. Kiyohara, and T. Nakashima. Facilitation of thermoregulatory heating behavior by single cortical spreading depression in the rat. Physiol. Behav. 31: 651-656, 1983.

34. Shibata, M., T. Hori, T. Kiyohara, and T. Nakashima. Activity of hypothalamic thermosensitive neurons during cortical spreading depression in the rat. Brain Res. 308: 255-262, 1984[Medline].

35. Shibata, M., T. Hori, T. Kiyohara, and T. Nakashima. Convergence of skin and hypothalamic temperature signals on the sulcal prefrontal cortex in the rat. Brain Res. 443: 37-46, 1988[Medline].

36. Shibata, M., T. Hori, T. Kiyohara, T. Nakashima, and T. Osaka. Impairment of thermoregulatory cooling behavior by single cortical spreading depression in the rat. Physiol. Behav. 30: 599-605, 1983[Medline].

37. Shibata, M., T. Hori, and T. Nagasaki. Effects of single cortical spreading depression on metabolic heat production in the rat. Physiol. Behav. 34: 563-567, 1985[Medline].

38. Stark, R. I., S. S. Daniel, M. K. Husain, A. B. Zubrow, and L. S. James. Effect of hypoxia on vasopressin concentrations in cerebrospinal fluid and plasma in sheep. Neuroendocrinology 38: 453-460, 1984[Medline].

39. Tamaki, Y., and T. Nakayama. Effects of air constituents on thermosensitivities of preoptic neurons: hypoxia versus hypercapnia. Pflügers Arch. 409: 1-6, 1987[Medline].

40. Valtin, H. The discovery of the Brattleboro rat, recommended nomenclature, and the question of proper controls. Ann. NY Acad. Sci. 394: 1-9, 1982.

41. Veale, W. L., N. W. Kasting, and K. E. Cooper. Arginine vasopressin and endogenous antipyresis: evidence and significance. Federation Proc. 40: 2750-2753, 1981[Medline].

42. Wang, B. C., W. D. Sundet, and K. L. Goetz. Vasopressin in plasma and cerebrospinal fluid of dogs during hypoxia or acidosis. Am. J. Physiol. 247 (Endocrinol. Metab. 10): E449-E455, 1984[Abstract/Free Full Text].

43. Winer, B. J. Multifactor experiments having repeated measurements on the same elements. In: Statistical Principles in Experimental Design. New York: McGraw-Hill, 1971, p. 514-603.

44. Wood, S. C. Interactions between hypoxia and hypothermia. Annu. Rev. Physiol. 53: 71-85, 1991[Medline].

This article has been cited by other articles:

K. C. Crisanti and J. E. Fewell
Aminophylline alters the core temperature response to acute hypoxemia in newborn and older guinea pigs
Am J Physiol Regulatory Integrative Comp Physiol, September 1, 1999; 277(3): R829 - R835.
[Abstract] [Full Text] [PDF]

K. C. Crisanti and J. E. Fewell
Naloxone does not alter the "regulated" decrease in core temperature during hypoxemia in guinea pigs
J Appl Physiol, September 1, 1998; 85(3): 1150 - 1159.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Alert me when this article is cited

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Google Scholar

Google Scholar

Articles by Rollins, E.-L. M.

Articles by Fewell, J. E.

Search for Related Content

PubMed

PubMed Citation

Articles by Rollins, E.-L. M.

Articles by Fewell, J. E.

				K. C. Crisanti and J. E. Fewell Naloxone does not alter the "regulated" decrease in core temperature during hypoxemia in guinea pigs J Appl Physiol, September 1, 1998; 85(3): 1150 - 1159. [Abstract] [Full Text] [PDF]