Surgery: light – thermal – and electrical application – Light – thermal – and electrical application – Thermal applicators
Reexamination Certificate
2002-05-02
2004-03-09
Gibson, Roy D. (Department: 3739)
Surgery: light, thermal, and electrical application
Light, thermal, and electrical application
Thermal applicators
C607S106000, C607S113000
Reexamination Certificate
active
06702839
ABSTRACT:
INTRODUCTION
1. Technical Field
This invention relates to a method, apparatus and composition for selectively controlling the temperature of all or a portion of a patient's body by lowering, maintaining or raising the temperature of a body fluid or tissue to affect the temperature of all or part of the patient's body, while reducing shivering that typically accompanies such temperature control. More particularly, the invention relates to a heat exchange device in combination with an anti-shivering mechanism to control the temperature of all of a portion of a patient's body while reducing shivering. The invention also relates to novel compositions that are useful for reducing shivering.
2. Background
The “set point temperature” is the temperature that the body attempts to maintain through the thermoregulatory responses. Under ordinary circumstances, thermoregulatory mechanisms within the human body which include sweating and vasodilation to enhance heat loss, arterio venous (“AV”) shunting and vasoconstriction to enhance retaining heat, and shivering to enhance increased generation of body heat, serve to maintain the body at a near constant set point temperature of about 37° C. (98.6° F.), often referred to as “normothermic”. However, sometimes the body sets a different set point temperature, for example a patient with a fever has an elevated set point temperature, and these mechanisms can serve to maintain an elevated temperature. In the case of a fever, the set point temperature can be higher than normothermic.
There is a temperature slightly below the set point temperature where the body senses that the body temperature is too low and begins to shiver. This temperature is sometimes referred to as the shivering threshold. As with the set point temperature, the shivering threshold is not an absolute temperature but varies between individuals and within the same individual depending on his or her condition.
As a result of the thermoregulatory mechanisms, any heat lost to the environment is precisely balanced by heat produced within the body. Accordingly, attempts to control the body temperature below the set point temperature often produce shivering in the patient, as this is the main method of generating additional metabolic heat. Shivering can increase heat production by 200-500% and thus presents a serious obstacle when attempts are made to reduce a patient's body temperature.
The thermoregulatory mechanisms provide a formidable defense when attempts are made to lower the body temperature below the set point temperature, for example, when one attempts to induce an artificially low body temperature (a condition known as hypothermia) by lowering the normothermic 37° C. to a lower temperature state or when one attempts to maintain normothermia by lowering an elevated body temperature to normothermic 37° C. Since there are numerous therapeutic reasons for both inducing hypothermia or inducing normothermia in a patient suffering from an elevated temperature, the thermoregulatory mechanisms must be taken into consideration when designing a therapeutic regimen for controlling the temperature of all or a portion of a patient's body. Indeed, when the patient has a set point temperature that is above normothermic, for example when the patient has a fever, the shivering threshold may actually be above normothermic as well, and thus even an attempt to maintain a patient's temperature to normothermia may result in shivering. In addition, even when the thermoregulatory mechanisms have been overcome, the body temperature may continue to drop, possibly below the desired threshold. This “overshooting” phenomenon can lead to complications. Accordingly, any therapeutic regimen for controlling body temperature preferably does so at a carefully monitored and controlled rate.
It has also been found that in rewarming a patient, either after therapeutic hypothermia or a patient suffering from accidental hypothermia, a very gradual and controlled rewarming rate is desirable. The dramatic generation of metabolic heat due to shivering, particularly in addition to heat added by other means, can result in rapid and uncontrolled rewarming. Therefore therapeutic rewarming at a carefully monitored and controlled rate also requires control over shivering.
Hypothermia may be induced to minimize damage to the brain when a patient has suffered a head injury or stroke, or to minimize damage to heart and brain tissue when a patient has undergone cardiac arrest. It may sometimes also be desirable to induce hypothermia during surgery, especially neurosurgery, once again to minimize tissue damage.
Early techniques involved application of cold to the skin surface or cooling the inspired air, alone or in combination with a compound to inhibit the thermoregulatory center such as chlorpromazine (Ripstein, et al.,
Surgery
(35)1:98-103 (1954)). More recently, in situ blood temperature modification using a heat exchange catheter was described in Ginsburg, U.S. Pat. No. 5,486,208 and Ginsburg, WP 98/268831, the disclosures of which are incorporated herein by reference. This in situ procedure lowers the body temperature much faster and maintains the temperature at that lower level more precisely than the cooled skin surface or cooled breathing air methods described above.
There are also drugs which are capable of assisting in lowering body temperature. However, many require toxic doses in order to achieve the desired hypothermic state. Temperature lowering was also allegedly achieved with chlorpromazine, when administered in combination with a refrigeration blanket (Ripstein, et al, supra), and when administered alone (Chai, et al.,
Br. J. Pharmac
. 57:43-49 (1976)). However, in both these instances, temperature variation after the chlorpromazine was administered was achieved by external cooling or exposure alone and without any significant control of the degree or rate of body cooling. More recently, hypothermia was allegedly induced in rats with a combination of a &kgr; opioid receptor agonist and a dopamine receptor blocker or agonist (Adler, et al., U.S. Pat. No. 4,758,562). It has been shown that the &agr;
2
-adrenoreceptor agonists dexmedetomidine and clonidine are able to lower the shivering threshold (Talke, et al.,
Anesthesiology
87(4):835-841, 1997). In this study, patients at a normal temperature were warmed until sweating then cooled until shivering occurred, as the &agr;
2
-adrenoreceptor agonist was administered. Evaluation of the ability of these agonists and a novel agonist to reduce core temperature were later described in Millan, et al.,
The Journal of Pharmacology and Experimental Therapeutics
295(3):1192-1205, 2000. However, in both these studies, as with chlorpromazine, temperature variation after the &agr;
2
-adrenoreceptor agonist was administered was achieved with only minor control of the degree or rate of body cooling.
However, in spite of these advances, there continues to be a need to develop a method of safely and temporarily inactivating the shivering response while inducing hypothermia or otherwise reducing the body's temperature below its set point temperature for an extended period of time, or while gently and slowly raising the body's temperature from a hypothermic state.
SUMMARY
The present invention pertains to a method for controlling the temperature of all or a portion of a patient's body to a temperature below its set point temperature, while reducing shivering, comprising the steps of: (a) sensing the temperature of all or a portion of the patient's body; (b) generating a signal based upon the sensed temperature; (c) controlling the temperature of all or a portion of the patient's body based upon the signal; and (d) administering an agent selected from the group consisting of &agr;2-adrenoreceptor agonists, non-opiod analgesic monoamine uptake inhibitors, neuropeptides, nefopam and an anticonvulsant drug to the patient.
In many ways, the muscular activity of shivering, which is a high frequency, random-like muscular contra
Dae Michael W.
Keller Wade A.
Machold Timothy R.
Buyan Robert D.
Radiant Medical Inc.
Stout, Uxa Buyan & Mullins, LLP
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