Hyperthermia - Therapeutic Fever

“I would cure all diseases if I only could produce fever.” Parmenides, Greek physician and philosopher, 510 BC

Fever and heat therapy have been recognized for their beneficial effects on health since antiquity. Traditionally there have been two forms of hyperthermia—whole body and localized applications. We are now discussing the modern innovations to both approaches of hyperthermia, as applied in the treatment of cancer. Fever turns out to be one of the missing links in understanding cancer. Most cancer patients have a lower core temperature and cannot mount a fever. Thus they are unable to activate their immune system.

  • Hyperthermia in the Treatment of Cancer

    Hyperthermia in the Gorter Model – A Significant Part of the Cancer Treatment

    We know scientifically that fever is a protective mechanism. When body temperature reaches 101.3° F (38.5° C) the immune system shifts into a state of alarm. At this temperature, the level of immune chemicals in the bloodstream doubles and immune defenses throughout the body increase. Within six hours, almost every major defense within the immune system doubles its efforts. This process appears to be dormant in many cancer patients, who typically report never having experienced a fever. To reactivate the immune system in these patients, the Gorter Model uses a process of controlled fever referred to in the scientific literature as “fever-range, total-body hyperthermia”—a form of treatment in which the entire body is heated to a moderate fever temperature of approximately 101.3 F (38.5 C). As a result, the immune system is activated in the same way as a natural fever would activate immune response, for example to an infection. This approach is necessary to raise the body to a therapeutic fever range, unlike traditional methods such as sauna methods and hot tub, which do not affect core temperature or achieve temperatures that are as high as the temperature range that occurs during a fever. In the Gorter Model, total-body hyperthermia is provided to about 70% of all patients.   Local hyperthermia is another approach used in the Gorter Model. Localized heat is applied to the tumor tissue; a “region” or area of the body is selectively heated, again so that only the cancer cells increase in temperature. The local heating increases the temperature within the the malignant cells to 42 C (107.6 F) so that they die, due to the increased intra-cellular lactic acid production.Only the cancer cells are increased in temperature which leads directly to cell death (necrosis). The localized high temperature and the resulting cancer cell death also activates the immune system. The surrounding healthy cells are not affected. Local hyperthermia is used with approximately 99% of patients.

  • Fever: Friend or Foe?

    In our culture, there is a pervasive fear of fever.

    (NSAIDS—non-steroidal, anti-inflammatory drugs). The medicine represents hope and recovery. Giving medication implies a cure. (And so does the advertising.)   The message is: If you can just reduce the fever, the disease will go away.     So the caretaker feels empowered by giving fever-suppressing medication. There is the belief that reducing the fever is a way of fighting the illness.   Ironically, the fear of fever is misplaced. Unless the fever is too high (104 °F (40.0 °C) or above over weeks at a time, no harm occurs. Fever signals the immune system to mount an increased defense and sets the process of healing in motion. In fact, fever is the natural response of all mammals to infection or illness. This is true for cats and dogs, elephants and tigers, horses and humans. Research has made it clear that fever is not the enemy; it is the friend of healing. This scientific rationale, supported by thousands of research studies, provides the basis for hyperthermia treatment at the Medical Center Cologne and other medical centers in Europe, Japan, and world-wide.

  • The Role of Fever in Immunity

    Fever is the necessary signal that ramps up the immune response.

    Fever is a basic, protective response to infection, in almost all animals. The U.S. National Library of Medicine affirms this, defining as :

    “An abnormal elevation of body temperature, usually as a result of a pathologic process [ie infection].  However, lay people have assumed that fever was the cause of illness—not realizing that fever is the body’s primary response in fighting infection.”

  • A Century of Research on Fever

    A number of researchers have tracked this issue in large clinical trials over the past 100 years, starting with published reports in 1854 that many cancer patients have a “remarkable disease-free history.” Several later studies confirmed this, reporting that people who developed cancer were rarely ill before their disease. If it seems surprising that this premise would have gone unrecognized for 150 years, consider the fact that scurvy among seaman caused by lack of vitamin C was not acknowledged for more than 100 after it was first confirmed by a ship’s physician.   The doctor’s recommendations were adopted 105 years later when another naval physician reported a similar finding. In a similar pattern, studies on the importance of fever in a strong immune defense against cancer were published in the medical literature in 1854, 1910, 1934, and 1936, each study involved hundreds of patients. Researchers consistently found increased cancer risk for patients who had no history of infectious illness or fever. The majority of more recent studies have corroborated these findings:

    • German research published in 1983 found that cancer risk more than doubled in patients who had not experienced major infectious diseases (2.6 times greater risk). Cancer risk was more than five times higher in patients who had never experience the common cold (5.7 odds ratio), and there was a 15-fold increase for those who had never experienced fever (15.1 odds ratio).
    • A study of skin cancer patients, published in Melanoma Research in 1992 reviewed the medical histories of 500 comparable patients, with and without cancer. Researchers found that the patients who had experienced infections accompanied by fever had a much lower incidence of malignant melanoma.
    • Research published in the journal Cancer in 1992 evaluated the medical histories of more than 200 patients with brain tumors, who were compared with over 400 similar but non-cancerous patients. Those who had experienced infections and colds had a 70% lower risk of cancer.

    One of the most insightful looks at the role of fever has come from a research team from the National Institutes of Health.    The researchers performed an in-depth review of the medical literature on cancer risk. They reported that risk appears to be increased in individuals who have experienced fewer infections. They noted “an inverse correlation between the incidence of infectious diseases and cancer risk.

    ” In other words, people who have not experience common childhood illness and fever seem to have a greater risk of cancer. Averting fever by the frequent use of aspirin or antibiotics may actually impair immune function. The NIH team concluded that, “the occurrence of fever in childhood or adulthood may protect against the later onset of malignant disease.”

    They also pointed out that “spontaneous remissions are often preceded by feverish infections.”[vi,vii] Their final report includes hundreds of references from the medical and research literature.[vi]

  • How Fever Activates Immune Function

    As described in detail earlier in this chapter, fever is actually the signal that mounts immune activity in response to infection, illness, injury, or malignancy. At 101.3° F (38.5° C) the immune system doubles its functions, in response to impulses from deep within the brain stem.   This increase in body temperature has been shown to call up various aspects of the immune function, including chemical messengers such as interleukin that call the immune system into action,  dendritic cells that identify the infection or malignancy, heat shock proteins which activate white cells, , and T-cells to destroy viruses and cancer cells.[iii,iv]

  • The Role of Fever in Immune Development

    In a newborn the immune system is immature and underdeveloped. For example, protective antibodies are not made by the infant’s body, and the baby relies on those transmitted before birth by the mother to her infant through the placenta. These maternal antibodies become depleted by the time the baby is about 6 months old. At this point, the immune system of the child must learn how to respond to invasive infections such as bacteria, viruses, and parasites and to threats from within the body such as abnormal and cancerous cells. Like any other organ system, the immune system must develop and mature if the child is to remain healthy.   On average, each newborn develops about seven viral infections in its first year of life. Researchers now view fever as a “necessary attempt by nature” to support immune system development and have confirmed that it is the process that activates the immune response.ii,iii,iv Cohort studies have also shown that a child needs at least 4 to 5 episodes of high fever before age 6 to develop an adept immune system.   The development of immunity can be compared with the maturation of the muscles and skeleton, which only develop correctly if they are used all the time, and experience periodic exertion from activity and play. That is why we encourage children to participate in sports. A child who is bed-bound or wheel-chair bound does not have the opportunity to develop a proper skeleton and musculature as a result of disuse.

    The immune system can only develop fully if it is put under “stress” by defending the child against invading microbes such as viruses and bacteria. When a child experiences any type of infection, the immune system must augment its defense mechanisms and step up its activities and metabolism. In childhood, fever is important because it plays a role in immune development and maturation so the system can function properly life-long.   A number of researchers have suggested that averting childhood infections and fever through inoculations for benign illnesses such as chicken pox and rubella may be a factor in increased vulnerability to cancer in adulthood.

    • A British study published in 1977 of 300 women with ovarian cancer found lower incidence of measles, mumps and rubella compared to non-cancerous patients.
    • Another study published in The Lancet in 1985 of 500 patients reported that approximately 6% of cancer patients had not develop measles in childhood compared with less than 1% of noncancerous participants in the study.
    • A third study in the American Journal of Epidemiology (1986) reported that children with leukemia had experienced fewer infections in their first year of infancy, suggesting the importance of stimulating the immune system early in life.
  • Effects of Fever Suppression

    Absence of fever in cancer patients —In clinical cases evaluated at the Medical Center Cologne, the vast majority of cancer patients report that they are never sick and they never missed a day at work. Typically, they may have had a few days when they experienced a sore throat, a cold, or a cough, but it was never accompanied by fever. When fever did develop, it was suppressed with aspirin, Tylenol, or antibiotics. Most cancer patients also have a reduced core body temperature and lack of circadian temperature rhythm.[xxi ] These are indications of the inability to raise temperature to a level necessary to activate the immune system.[xxi] It is possible that we have unknowingly conditioned the immune system not to respond, through our use of fever suppressants with our children.   Interrupting the fever mechanism —Surprisingly, the immune system can be trained to turn on or off in response to repeated cues, for example in response to certain medications. This trained or “conditioned” response was demonstrated in the work of Dr. Robert Ader and colleagues, published over a period of 25 years. Researchers found that the immune system could actually be deactivated through “classical conditioning.”   Applying this finding to the use of fever suppressing medications with children, the implication is that over time the fever response can be permanently inactivated by the frequent use of medication. Childhood fevers are also prevented when vaccines are used to avoid common childhood infections. From that point on, whenever the child develops a fever, the fever process is aborted.   Suppressing the immune response —In time, the body becomes conditioned to suppress fever at the slightest hint of a fever. Since fever is the cue that activates many of the key defenses of the immune system, this also means that immune response is cut short and never activated.

    Loss of defenses against cancer —We now know that our bodies develop cancer cells every day of our lives. When we have periodic bouts of cold or flu, if we allow our bodies to experience a fever, that provides an additional opportunity for clearing malignancies and l ingering infections. If the immune system is never activated, we have lost these opportunities to destroy cancer cells while their number is still small.   Increased risk of chronic infection —Suppressing fever may also enable bacterial and viral infections to become chronic. Without fever, some of the infectious cells escape destruction, linger, and start increasing in number. Note that although we think of antibiotics as our primary protection, it is actually the immune system which protects us. The antibiotics simply lower the infectious load so the immune system can handle it more easily.   Infections linked to cancer —Specific types of chronic infection have been linked to the localized development of cancer, including human papilloma virus, viral hepatitis, and H. pylori bacteria. In the peer-reviewed literature, more than 20,000 articles address the link between cancer and these three infectious agents.

    • Chronic human papilloma virus infection is implicated in about 40% to 80% ofall cervical cancers.
    • Various forms of hepatitis viral infections are associated with the development of liver cancer.
    • H. pylori bacterial infections have been identified as a causal factor in an estimated 40% to 80% of gastric cancers.

    Allergies, asthma, and cancer —Among children who never developed a high fever, about 30% develop food allergies, hay fever, and contact dermatitis (atopic dermatitis). In children who experienced episodes of childhood fever, only 5% develop these allergic reactions. Overuse of fever-suppressing medications has been found to increase the risk of allergies and autoimmune conditions.[xx]   Increased incidence of asthma —A recent study on the effects of Tylenol exposure in childhood published in the British journal Lancet in 2008 reported on the health of 205,487 children ages 6 to 7 years old, from 31 countries.    The study found that exposure to Tylenol (acetaminophen) during intrauterine fetal development or during the first year of infancy was associated with an increased risk of asthma symptoms. The risk was “dose-dependant”—the more frequent the Tylenol use, the greater the likelihood of asthma. Tylenol use, both in the first year of life and in children aged 6 to 7 years is also associated with an increased risk of symptoms of rhinoconjunctivitis and eczema. This data suggests that by suppressing fever, the immune system becomes compromised and less functional.

Patient's Experience with Hyperthermia

  • References

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