Field of the Invention

This invention relates to uses of adenosine and adenine nucleotides as anesthetic agents.

Relevant Art

A patient is protected from the pain and stress of surgery and similar procedures, by anesthesia to maintain physiological homeostasis.

Adenosine has a variety of extracellular effects. It is known to have potent vasodilating and hypotensive effects, but it has never been demonstrated that it has anesthetic activity with clinical use. Furthermore, the conventional wisdom is that neither adenosine nor adenosine triphosphate (hereinafter ATP) , an adenine nucleotide, circulating in the blood will cross the blood brain barrier. Therefore, despite known sedative activity of some synthetic adenosine analogues, neither adenosine nor ATP had been ever thought to be suitable as anesthetics.

A variety of drugs are used to provide anesthesia. Goodman and Gilman's The Pharmacological Basis of Therapeutics, 7th Ed., 1985, MacMillan, New York, Chapters 13 and 14 provide an overview of the field of anesthesiology as currently understood by those skilled in the art.

It has been reported that adenosine can be used in conjunction with a standard inhalational anesthetic to reduce the amount of anesthetic required, when adenosine is administered to produce hypotension. But others have never reported that adenosine or ATP could produce substantially acceptable anesthesia under normotensive conditions or could totally replace an inhalational anesthetic and still achieve substantially acceptable anesthesia.

Total replacement or reduction of inhalational agents or other agents is advantageous for several reasons. First, inhalational or other synthetic chemical anesthetics are toxic in large doses and produce severe cardio-respiratory and metabolic side effects. Secondly, the amount of anesthetic actually being used by the patient is subject to guesswork in the operating room.

Adenosine and ATP are endogenous compounds and therefore unlikely to produce toxic effects. Both Adenosine and ATP are known to be rapidly metabolized;

therefore when the infusion is stopped, recovery starts immediately and proceeds rapidly. Therefore, either adenosine or ATP would be ideal replacements for inhalational anesthetics, and replacements for opioid analgesics as well.

Applicant has found that under normotension, intravenously administered adenosine and ATP have potent analgesic effects, which together with the sedative effects and the inhibition of stress response effects, such as antihypertension and blood pressure control effects, make it a superior anesthetic agent.

Furthermore, when a subject anesthetized with adenosine or ATP and is then subjected to body temperature decrease, the decrease is not accompanied by shivering, cardiovascular distress, or pulmonary distress. This effect holds for drops in body temperature at least as large as 10°C to 20°C.

Adenosine and adenine nucleotides have also been discovered to provide excellent blood and tissue oxygenation. As such adenosine can be used to maintain donor organs for transplant in the best possible condition while still in the donor body and the period of time between removal from the donor body and implantation. Furthermore, the excellent blood and tissue oxygenation induced by adenosine can be used to

maintain the organ and the organ recipient in the best possible condition.

SUMMARY OF THE INVENTION

This invention provides a method of inducing anesthesia, hypothermia, and analgesia, and a method of treating stress and hypothermia by administering an amount of adenosine or adenine nucleotides to a patient in need of anesthesia or analgesia, or requiring induction of, or relief from, hypothermia. It also provides a method for preserving donor organs in vivo bv contacting them with adenosine or adenine nucleotides, as well as a method for preparing organ recipients for transplant.

An aspect of this invention is a method of anesthetizing an individual of a mammalian species comprising administering a continuous intravascular infusion of between lμg/kg/min and 5000 μg/kg/min of adenosine or an adenine nucleotide for the period that anesthesia is desired.

A further aspect of this invention is a method of creating subnormal body temperatures in individuals of mammalian species comprising: first administering a continuous intravascular infusion of between 1 μg/kg/min to 5000 μg/kg/min of adenosine, or an adenine nucleotide; second exposing the body of the mammal to a sub-body temperature ambient temperature; and allowing the body temperature of the mammal to fall.

Yet a further aspect of this invention is a method of relieving pain comprising: administering a continuous infusion of between 1 μg/kg/min and 5000 μg/kg/min of adenosine, or an adenine nucleotide for the period of time during which pain relief is desired.

Another aspect of this invention is a method of relieving stress, and stress response: administering a continuous infusion of between 1 μg/kg/min and 5000 μg/kg/min of adenosine or an adenine nucleotide for the period of time during which stress and stress response relief is desired.

Another aspect of this invention is a method of providing in vivo preservation of donor organs as well as organ transplant recipients by maintaining good tissue oxygenation to the patients and their organs comprising administering a continuous infusion of between 1 μg/kg/min and 5000 μg/kg/min of adenosine, or an adenine nucleotide for the period of pre and post organ transplantation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGURE 1 shows a chart comparing the activities of several different classes of anesthetics.

FIGURE 2 shows a graphical representation of the amount of anesthetic effect, measured as halothane MAC, versus the dosage of adenosine or ATP administered.

FIGURE 3 shows a graphical representation of the dose response curve of the anesthetic effect of ATP versus the nociceptive electrical stimulation (V) , and tail claim (ED50)

FIGURE 4 shows a graphical representation of the amount of anesthetic effect, measured as enflurane MAC, versus the dosage of ATP administered.

FIGURE 5 shows a graphical comparison of the effect of analgesia observed for morphine sulfate and adenosine.

FIGURE 6 shows a graphical comparison of the effect of stress on blood oxygen levels.

FIGURE 6a shows the effect of hemorrhage.

FIGURE 6b shows the effect of isoflurane.

FIGURE 6c shows the effect of ATP.

FIGURE 7 shows a graphical representation of the inhibition of stress response (Blood Pressure recording) to the nociceptive electrical stimulation.

FIGURE 8 shows a graphical representation of body temperature versus time for various doses of adenosine and ATP.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Definitions

As used herein "anesthesia" is defined as the final result of several interacting but independent effects. The first effect is sedation and/or sleep induction; the second is analgesia or pain relief; the third is stress reduction to preserve physiological homeostasis, most frequently seen as blood pressure modification during surgery; and finally, the fourth is usually considered to be muscle relaxation, particularly relaxation of skeletal muscle. At the present time, no single agent provides adequate levels of each and all of these four effects, so combinations of drugs must be used in cases like surgery. Anesthetic as used herein will refer to any single drug that gives rise to at least two of the four effects.

As used herein, the "adenine nucleotides" are only adenosine monophosphate, adenosine diphosphate, and adenosine triphosphate. In general, the preferred adenine nucleotide is adenosine triphosphate.

As used herein "surgery" and "surgical procedures" refer broadly to invasive discomfort-producing medical procedures. Included are such procedures as endoscopy, angiography, dental work, such as tooth extractions, as well as what is traditionally thought of a surgery, for

example appendectomies and the like. As used herein the terms encompass the presurgical phase and the post surgical phase as well, for example the emergency room, post-anesthesia care room, the intensive care unit, and the like, until the patient can rest comfortably without the supplemental administrations of analgesics being indicated.

As used herein "continuous infusion" refers to intravascular infusions, intrathecal infusions, and like methods of providing a continuous drug dosage over a period of time.

As used herein "stress" refers to the physiological changes that accompany trauma such as surgery. It includes release of catecholamines, induction of hypertension, and vasoconstriction.

Adenosine is known to have a short plasma half life. In order to achieve the process of this invention safely, a continuous infusion of adenosine or an adenine nucleotide must be used. An infusion of approximately 1 to 5500 μg of adenosine/kg bodyweight/min, hereinafter μg/kg/min, more preferably, 5 to 1000 μg/kg/min, even more preferably between 50 to 500 μg/kg/min, provides the effect of the invention.

The anesthetic effects of this invention are compared to standard anesthetic effects by comparing minimum alveolar concentration (hereinafter MAC) . A measure of potency of anesthetics has proven to be elusive. A first problem is only a relatively small amount of inhalational anesthetic gases is absorbed before the gas is exhaled. A second problem is that the point of action of the anesthetic is the brain, not the lungs, and the amount of anesthetic transported by blood to the brain, and the amount that actually enters brain tissue, is unknown resulting in an ill defined concentration of gas in brain tissue. Therefore, those skilled in the art of anesthesiology define one MAC of a gaseous anesthetic at 1 atmosphere of pressure (760 torrs) as that amount which produces immobility in 50 percent of patients or animals exposed to painful stimulus. The use of MAC provides a convenient means of comparing the effect of the standard gaseous anesthetic agents, halothane, enflurane, methoxyflurane, isoflurane, and nitrous oxide to the anesthetic effect of adenosine and adenine nucleotides.

The anesthetic and analgesic properties of adenosine and adenine nucleotides are more easily compared to the effective dose of opioid analgesics. There, a dosage of opioid sufficient to produce immobility in 50 percent of patients or animals exposed to painful stimuli is defined as the effective dose, (hereinafter ED 50)

Blood pressure can be lowered by administration of adenosine or adenine nucleotides, and other means, for example hemorrhage. The overall response to blood pressure lowering to a predetermined level by administration of purines and hemorrhage is quite different. In the case of hemorrhage, oxygen in all tissues and organs plunges, but in the case of purine infusion the levels actually increase. As a result, administration adenosine and adenine nucleotides can increase the oxygen content of tissues.

Referring to Figure 1 various anesthetics and anesthetic agents are compared for efficacy in producing sleep, inducing analgesia, reducing surgical stress and relaxing muscles. These are the four effects that anesthesiologists try to achieve during a surgical procedure. The chart confirms that no presently used agent is effective for all four effects. All known agents for stress relief are not included in the chart because most of these agents are normally considered to be cardiovascular medications, given primarily to treat cardiovascular disease, rather than anesthetic agents.

On the chart, a class of agents is rated for each of the four effects and graded on a scale of 0, indicating no effect, to 3, indicating a large effect.

It can be seen that sleep is best sustained by the inhalation agents: halothane, and the like; and induced by barbiturates: sodium pentothal, and the like, and propofol. Pain is most effectively relieved by the opioid analgesics: morphine, fentanyl, and the like. Muscle relaxation is induced by a paralytic agent, pancuronium, succinylcholine chloride, and the like. But each agent has two or more points of poor effectiveness, as shown by a 0 or 1 on the chart. As a result, in a surgical procedure an anesthesiologist must use several different agents to achieve successful anesthesia. In particular, no currently used anesthetic agent has much effectiveness against the stress induced by surgery.

Adenosine or adenine nucleotides, on the other hand are seen to provide excellent analgesia, and stress relief, good sedation induction, and maintenance, but only fair muscle relaxation.

An ideal anesthetic for surgical use would combine several effects in one medication. It would provide pain relief, sedation and sleep, and induce muscle relaxation. Typically today an anesthesiologist must relieve pain by an opioid or other analgesic, produce sleep by sodium pentothal or similar hypnotic, sustain sleep by an inhalational anesthetic and relax muscles by the use of succinyl choline chloride or the like.

Adenosine and adenine nucleotides induce sedation, maintain sleep, reduce stress of surgery, and relieve pain. In addition, adenosine can induce hypothermia and maintain tissue perfusion and oxygenation. Therefore, adenosine and adenine nucleotides come closer to being ideal anesthetics for surgical use.

Adenosine or adenine nucleotides may be the only agent required for certain uses, such as relief of chronic pain, or minor surgery where deep sleep is not necessary, but pain relief is. Major surgery may require the additional use of some inhalational or intravenous anesthetics and some muscle relaxant.

Dosaσe

In contrast to other conventional anesthetics, adenosine and adenine nucleotides are useful over a wide dosage range. Adenosine is active over a range of between 1.0 to 5000 μg/kg/min. In contrast, conventional anesthetic agents, for example, isoflurane have narrow effective ranges. The fatal to anesthetic ratio of isoflurane is 3.02 ± 0.13. Other reports indicate that isoflurane has about 1.88 times the safety range of halothane. When these ranges are stated simplistically, they suggest that if a patient is administered between two and five times the dose required for the onset of sleep, the patient will die. Of course,

the anesthesiologist will err on the side of too little, running the risk of under dosing the patient, which results in a subanesthetized patient during the surgical procedure.

One great advantage observed with adenosine is the wide margin for error. The lethal dose for adenosine is about 100 times the dose required for analgesia, and in the case of ATP is greater than 150 times the amount required for analgesia. In fact, in the case of ATP the ratio remains unknown since no experimental animals died even given enormous overdoses.

Analgesic Effects

The dose required to achieve pain relief equivalent to 1 mg morphine sulphate is about 40 μg for adenosine and about 30μg for ATP. It can be seen that adenosine triphosphate is slightly more active. The effective dosage range an infusion of between about l μg/kg/min to 5000 μg/kg/min, but preferably between about 50 μg/kg/min to about 500 μg/kg/min. It is, of course, realized that the dosages may be varied according to the patients age, sex, weight, and the condition being treated. All this is well within the skill of the anesthesiologist who will monitor the patient's vital signs and vary the dosage as required.

Cardiovascular Effects

Adenosine and ATP have both been found to inhibit the cardiovascular stress including the inhibition of catecholamine release, hypertension, and vasoconstriction, as well as improving cardiac function (after load reduction) stress response when used clinically as an adjunct to conventional anesthetic agents. It should be realized that the stress response reduction has always been noticed when adenosine is used in conjunction with inhalational anesthetics or other sleep inducer. Furthermore, administration of purines does not depress cardio-respiration.

Anesthetic Effects

The anesthetic effect of adenosine and adenine nucleotides is measured using New Zealand white rabbits having shaved tails. Intravenous drugs are introduced in the rabbits ears. The rabbits breathed halothane in 0 ₂ through a face mask. The rabbits can be intubated, but are usually observed to breathe spontaneously. MAC is determined by clamping the proximal one-third of the tail with a rubber shod hemostat. The anesthetic effect of adenosine is determined by reducing the amount of halothane from 1.00 MAC to 0.75 MAC to 0.50 MAC to 0.25 MAC to 0 MAC while increasing the infusion rate of adenosine at a level to achieve an observed 1.00 MAC of

anesthesia. Temperature of the rabbits is maintained at between 38.5°C and 39.5°C. By use of similar techniques the analgesic effects of adenosine can be compared to those of morphine. The dose response curve of the analgesic effects of adenosine and ATP can also be obtained by the method described above.

Hypothermic Effect

The rabbits are prepared as in testing for anesthetic effect. The rabbit's temperature is allowed to fall however. In a room having a temperature of approximately 22°C the rabbits body temperature will fall to about 31° to 32°C in about three hours. If the rabbit is cooled further with ice bags, a temperature of approximately 22° can be achieved in three hours.

Tissue Oxyσenation Effect

Oxygen perfusion is measured by using polarographic electrodes in the brain, liver, kidney, and muscle, as well as under the skin. Then oxygen concentration can be measured and compared among different methods during severs stressful conditions such as, hypotension.

Formulations

Adenosine or adenine nucleotides can be prepared for intravenous solution by conventional methods known in the art. Pharmaceutically acceptable excipient and adjuvants, for example, salts, sugars, pH modifiers, thickeners and the like as well as other pharmaceuticals with similar or different activities can be added to achieve a clinically acceptable dosage form. All these modifications are well within the scope of knowledge of one reasonably skilled in the art.

EXAMPLES

Adenosine triphosphate - Na ₂ was obtained from Kyowa Hakko, Japan. Enough ATP was dissolved in physiologic saline to make a 200 mg/ml solution. Adenosine solution was made dissolving adenosine (Sigma Co.) in physiological saline to make a 10 mg/ml solution, and adenosine solution (5.3 mg/ml in isotonic mannitol) was obtained from Astra Co.

EXAMPLE 1

This example shows the effects of intravenously administering adenosine and ATP on Halothane MAC and its reversal by aminophylline in rabbits.

Adenosine is known to produce a number of effects in the CNS including sedation, anticonvulsant and antinociceptive (analgesic) effects. We studied the effect of an administration of an intravenous infusion of adenosine and ATP on MAC on halothane in rabbits.

Anesthesia was induced in 23 unmedicated New Zealand white rabbits (4.5-5.5 Kg) with 3 to 4 percent halothane in 0 ₂ using face mask; the trachea was intubated with a pediatric endotracheal tube. Each animal breathed spontaneously throughout the study. Esophageal temperature was kept at 38°5-39.5°C. Endo-tidal halothane and C0 ₂ were monitored continuously. Two ear veins and an ear central artery were cannulated with 22 gauge plastic catheters for drug infusion, and direct blood pressure and gas monitoring. There were 4 groups: A (n=7) treated with phenylephrine to support blood pressure during ATP, B (n=7) ATP alone, C (n=5) adenosine alone, D (n=4) ATP combined with dipyridamole. MAC was determined using the standard procedure of clamping the proximal one-third of the shaved tail with a rubber shod hemostat closed to first ratchet.

Referring to Figure 2, the analgesic level of adenosine or ATP was estimated by, titrating the drug infusion rate step wise while decreasing the amount of halothane MAC from 1.0 - 0.75 - 0.25 - 0. Halothane MAC

values in all 4 groups averaged 1.62±0.56%, with no significant difference between them. Both drugs produced a potent analgesic action which was dose-related; this was potentiated by dipyrida ole in both pressure supported normotensive and hypotensive groups. At 5.52±0.79 mg/kg/min for ATP or 5.32±0.82 mg/kg/min for adenosine, halothane anesthesia could be entirely replaced. When maintained from 30 minutes to 1 hour, the animals were deeply sedated and become completely insensitive to any painful stimulus. The anesthetic response was for greater than 1 MAC. As the dose was increased the anesthetic effect became deeper and deeper.

Administration of aminophylline (50-100 mg IV) or naloxone (0.01-0.05 mg IV) rapidly reversed the anesthetic effect, and the animals resume normal activity within 5 minutes without any abnormal neuro-behavioral sign.

Referring to Figure 3, an ATP infusion is slowly increased. The amount of electrical stimulation required to elicit a response is noted. ATP shows selective responses. Two easily differentiated threshold responses are seen: one (A) is a response to arousal, and the second (B) is a purposeful escape movement in response to perceived pain.

Both ATP and adenosine alone had a potent anesthetic action which could totally replace halothane MAC. It is known that ATP rapidly degrades to adenosine; therefore, we infer that profound analgesia produced by ATP or adenosine appear to mediate central adenosine receptors since both drugs equally attained comparable effects of sedation, analgesia and anesthesia which were potentiated by dipyridamole, an adenosine uptake inhibitor, and reversed by aminophylline, and adenosine antagonist.

EXAMPLE 2

Adenosine reduces MAC requirements for halothane. High doses of enflurane (ENF) with N ₂ 0 attenuates responses to noxious stimuli, but at the cost of cardio- respiratory depression. In this example ATP is substituted for ENF. It provides sufficient anesthesia while avoiding the cost of cardio-respiratory depression. 6 intubated rabbits (4-5Kg) spontaneously breathing 60% N ₂ 0 in 0 ₂ were studied. Electrical stimulation in increasing voltage, as tolerated, up to 50v was applied. This allowed quantifiable, reproducible stimulation. Measurements were taken every 15 min. Purposeful escape movements were used as end-points. ENF concentrations of 0.5, 1.0, 1.5, 2.0, 2.5% were added to N ₂ 0 stepwise; responses and blood gases were recorded; in addition to electrical stimulation, the tail, ear and leg were clamped with a hemostat, and pinprick was applied to

reconfirm responses to nociception. When negative response to stimuli was achieved, the dose of ENF was decreased stepwise by 0.5% till positive response was shown; then, ATP infusion was titrated to replace the decreased ENF anesthesia till ATP could totally and effectively replace ENF (ATP initial dose: 5μg/kg/min) .

Referring to Figure 4 under 60% N ₂ 0, increasing doses of ENF up to 1.5% showed an elevated pain-threshold, but still responded positively to tail clamp. ENF, more than 2%, could completely inhibit such responses. At this dose, however, significant cardio-respiratory depression was shown (see Table 1) . Addition of increasing doses of ATP (5-70 μg/kg/min) allowed ENF to be replaced without diminishing the pain tolerance. Moreover, systemic blood pressure (SBP) and heart rate (HR) returned to control levels but analgesia persisted. Although Adenosine and ATP have extremely short plasma half lives, IV ATP may have intrinsic analgesic activity in the CNS since the selective analgesic effect persisted after the infusion had stopped; this effect may have been due to activation of central purinergic receptor mechanism, which once activated, has a long duration. This was seen by the observation of sustained analgesia after discontinuation of ATP which was partially reversed by IV aminophylline. This sustained analgesic property without cardio-respiratory depression may have marked clinical significance.

TABLE 1

RR: Respiratory Rate, 0 ₂ :100%, N ₂ 0:60%,

ENF: 2.0-2.5%, ATP: 70132(ug/kg/min) , MeanlSD

* p<0.05 vs CONTROL . (n=6)

E.XAMPLE 3

In this example the analgesic activity, the dose requirement and the potency ratio of adenosine and morphine sulfate are compared.

We evaluated 6 intubated rabbits (4-5 Kg) ; spontaneously breathing 60% N ₂ 0 in 0 ₂ . Two forms of noxious stimuli were evaluated: 1) Clamping the tail and the ear with a rubbershod hemostat, 2) Electrical impulses in increasing voltage, as tolerated, to a maximum of 40v; This allows quantifiable, reproducible stimulation. Responses assessed were: HR, SBP, respiratory rate (RR) neurobehavior, and purposeful

escape movements. After 20 min of 60% N ₂ 0, control responses to stimulation were recorded. Adenosine was infused peripherally, at increasing dosage until significant alterations in response to stimulation occurred. Normotension was maintained without pressure support. Duration and intensity of analgesia was evaluated every 15 min after termination of infusion. Aminophylline was given to reverse analgesic effects. Morphine sulfate was then titrated IV to max 2 mg/kg to attain surgical analgesia (ED 50) . No further doses were given if severe respiratory depression occurred.

Despite inhalation of 60% N ₂ 0, all animals responded with purposeful escape movements to tail and ear clamp, and electrical stimulation. Addition of Adenosine in doses of 188120 μg/kg/min completely suppressed the responses to both kinds of stimulation (ED 90) . No motor or cardio-respiratory depression occurred, and no ceiling effect was noted. Aminophylline (5-10 mg/kg) consistently reversed analgesia. With morphine sulfate to 2 mg/kg, no animal had complete suppression of all responses. Referring to Fig 4, a comparison of the effective analgesia of morphine sulfate and adenosine is shown. The effect of Morphine sulfate appears to approach an asymptotic limit, thereafter giving, no greater relief from pain (as measured by the voltage (V) of an electric stimulation) whereas adenosine provides more and more relief from pain. This study demonstrates

that IV Adenosine, in sub-hypotensive doses, significantly raised thresholds for pain. Prolonged analgesia may be mediated by Adenosine A, receptor mechanism as demonstrated by reversal of analgesia with Aminophylline. Adenosine appears to have an analgesic potency ratio of about 25:1 with Morphine Sulfate. Adenosine's property of sustained intense analgesia, absent cardio-respiratory depression, absence of "ceiling" effect, and easy reversibility may have substantial application in clinical anesthesia.

TABLE 2

n=6, MeanlSD, BP:Systolic BP, RR: espiratory Rate, * p<0.05 vs Control

EXAMPLE 4

This example shows a comparison of oxygen transport and regional tissue oxygenation during induced stress

responde caused by hypotension induced by hemorrhage, isoflurane, and adenosine triphosphate in dogs.

One of the most important concerns during hypotension the fear of impaired vital organ perfusion and oxygenation. We compared the changes in oxygen transport parameters and regional tissue oxygen tension of the parenchymal and non-parenchyma1 organ/tissues during graded arterial hypotension.

Twenty-three dogs (23.115kg) were anesthetized with pentobarbital (30 mg/kg IV) , intubated and mechanically ventilated with 40 percent 0 ₂ in nitrogen to maintain normocapnea under normothermia (38°C) . Arterial and pulmonary artery (Swan-Ganz) catheters were placed via a femoral cut down. A Clark-type polarographic P0 ₂ electrode with a tip diameter (3mm) was inserted under the dura and placed on the frontal cortex through a small burr hole. Another P0 ₂ sensor probe was placed on the surface of the liver, kidney, subcutaneous and muscle of the chest wall through a small skin incision. Referring to Figure 5, the dogs were divided into 3 groups: a) Hemorrhagic (n=7) , b) Isoflurane (n=8) , and c) ATP (n=8) . Mean arterial pressure (MAP) was lowered step wise from control (11914.5 mmHg) to 90, 70, 50 and then to 30 mmHg, each being maintained for 20 minutes. The following were measured and/or calculated: MAP, 0 ₂ consumption (V0 ₂ ) , 0 ₂ delivery (D0 ₂ ) and P0 ₂ of arterial (Pa0 ₂ ) and mixed venous

(Pv0 ₂ ) of the brain, (Pb0 ₂ ) , liver (P10 ₂ ) , kidney (Pk0 ₂ ) , subcutaneous (Psc0 ₂ ) and muscle (Pm0 ₂ ) of the chest wall. The data were analyzed using ANOVA with the Bonferroni t- test and unpaired t-test where appropriate, accepting p<0.05 as significant.

Results are shown in Figure 6a, 6b, and 6c. During the sequential hypotension, Pa0 ₂ remained unchanged. Due to autoregulation, cerebral cortical Pb0 ₂ was little affected in all groups. However, there were markedly different hemodynamic and tissue oxygen responses between the three different hypotensions. Hemorrhage caused intense peripheral vasoconstriction. Isoflurane blunted these peripheral vasoconstrictive responses. With higher dose, Isoflurane seriously depress D0 ₂ , resulting in a reduced 0 ₂ supply/demand ratio. While ATP maintained better balanced 0 ₂ transport profile which resulted in a positive 0 ₂ supply/demand ratio in all stages of hypotension favoring the tissue oxygenation preferentially to the vital organs.

Referring to Figure 7, the blood pressure is recorded as in Example 1, 2, or 3 as electrical stimulation is applied to the tail. When ATP is administered purposeful escape movements decrease. When enough ATP is infused no more purposeful escape movements or stress are seen as reflected by the blood pressure.

EXAMPLE 5

This example shows the effects of adenosine and adenosine triphosphate on hypothermia in rabbits.

Referring to Figure 8, the body temperature versus time plots are shown for right different experiments. In run 1 adenosine 500 μg/kg/min was administered intravenously to rabbits for six hours. The administration was then stopped and the rabbits body temperature was allowed to recover.

In run 2 ATP 500 μg/kg/min was administered intravenously for six hours. At that time the rabbits body temperature was 31.5°C. The animals body temperature was allowed to recover by applying external heating for four hours when (at the arrow) the external heating was removed and the body temperature allowed to fall. The animals body temperature again fell.

In run 3, ATP was administered intravenously. The rabbits body temperature stabilized after ten hours at 32.5°C.

In runs 4, 5, and 6, adenosine was administered to rabbits until the body temperature reached a constant value. In run 4, after five hours the rabbits body temperature stabilized at 30.5°C. In run 5, after five

hours the body temperature stabilized at 33°C. In run 6, after six hours the body temperature stabilized at 31.5°C.

In run 7, five unmedicated New Zealand rabbits were anesthetized with halothane in 0 ₂ using a face mask. The ear vein was cannulated with a 22 gauge plastic catheter for drug infusion. 500 μg/kg/min to 5500 μ/kg/min adenosine was administered IV. Body temperature was monitored through a rectal thermometer. The body temperature started at approximately 38.5°C. After the application of ice bags, the temperature dropped approximately 5.5°C/hr until a minimum body temperature of approximately 22°C was achieved. During the body temperature lowering no shivering or other apparent discomfort was observed. All five rabbits survived the temperature lowering.

The ice bags were removed and external heating applied. The body temperature of all rabbits returned to normal, and the rabbits were apparently normal.

In a comparison, in run 8 six rabbits were anesthetized with isoflurane and external cooling applied. At 34°C one rabbit expired due to ventricular fibrillation. At 25°C another expired due to pulmonary edema. All rabbits on isoflurane only were observed to shivered violently as body temperature was lowered.

EXAMPLE 6

In this example, intrathecal administration of adenosine is shown to be effective.

Anesthesia is induced in unmedicated New Zealand white rabbits (4-5 Kg) with 3-4% halothane in oxygen using a face mask. The trachea is intubated with a No. 3.5 pediatric endotracheal tube. All the animals breathe spontaneously throughout the study but they are mechanically ventilated when required. Rectal temperature are controlled at 38.5-39.5 °C. Expired halothane and carbon dioxide concentrations are monitored continuously. Two ear veins and an ear central artery are cannulated with 22 gauge plastic catheters for drug infusion and for blood gas monitoring. The groin is exposed and a cut-down performed on the femoral artery and vein. The femoral artery is cannulated and the catheter placed with its tip in the mid-thoracic aorta to measure central systemic blood pressures. Another central venous catheter is inserted through the femoral vein.

The animal is turned in prone position and the operative site prepared over the lower back. The skin is infiltrated with 2% lidocaine 3-4 cc. Following dissection through the paravertebral muscles, a

laminectomy is performed, a touhy needle is placed under direct vision into sub-arachnoid space and a microcatheter (22-32 gauge) is threaded through the needle advancing it gently so that its tip lays at the base of the skull. Clear CSF is aspirated to confirm sub-arachnoid placement. The laminectomy site is disinfected, and sutured to close the site. The catheter is secured with tape.

Noxious stimulation is provided by an electrode placed at the base of the tail for low-voltage electrical current stimulation delivered through a nerve stimulator. Other kind of stimulations will be in the form of pin prick with a 20 gauge needle, pinching the paw and tail clamping with a rubber-shod hemostat.

Continuous recording of cardio-respiratory parameters including the heart rate, arterial blood pressure, respiratory rate, the animal's physical movement, and any other behavioral changes are recorded. Samples of arterial and mixed venous blood are analyzed for pulmonary gas exchange and acid base status.

Several intrathecal dosage forms are evaluated: Lidocaine is given in 0.5 mg/kg increments; Fentanyl is given in 1 μg/kg increments; Adenosine is given as a fractionated dose as well as via a continuous infusion (10 mg/hr) based on the body weight of the rabbit.

Comparison of the various drugs show that intrathecal administration of adenosine is as effective as intrathecal fentanyl in reducing the response to the noxious stimulation.