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Cancer Adjuvant Therapy

When t-butylhydroperoxide, a free-radical generator and oxidant, is used to oxidize red blood cells, it results in rupturing of the cells and darkening of the hemoglobin. An extract of aged garlic, added to the red blood cell suspension prior to the addition of the oxidant, minimized oxidation and cell rupture (Lin 1989). Since many cancer therapies produce free radicals in an attempt to kill cancer cells, researchers concluded that garlic could offer significant protection against treatment-induced tissue damage. Comment: Please consult the protocol Cancer: Should Patients Take Dietary Supplements to read about the appropriateness of antioxidant therapy during conventional cancer treatment.

Another benefit of garlic to the cancer patients is its effect on enhancing immune function. Here are a few of the numerous studies relating to garlic's effect on immune cells:

• Garlic stimulates proliferation of lymphocytes, those cells comprising 25% of total white blood cells that carry out the principal responsibilities of the immune system (Colic et al. 2000).
• Garlic quickens macrophage phagocytosis, a process by which microorganisms and cellular debris are engulfed and destroyed (Lau et al. 1991).
• Fraction 4 (F4), a protein isolated from aged garlic extract, enhanced the cytotoxicity of human lymphocytes. Although F4 alone increased cytotoxicity, the effect was amplified when F4 was combined with suboptimal doses of interleukin-2. F4 is an efficient immune potentiator and may be used for immune therapy (Morioka et al. 1993).

T-helper/T-suppressor ratios converted to normal among a small group of AIDS patients supplementing with garlic. Thrombocytopenia (a reduction in platelet count) is often therapy-resistant in individuals with AIDS. Yet, platelet numbers have been reported to increase, sometimes greater than 100,000, during 4 months of garlic supplementation. Although AIDS is not cancer, this feared disease has forced researchers and clinicians to look closely at the immune system (Abdullah et al. 1989).

Research suggests that garlic preparations are not equal in pharmacologic value. While raw garlic juice, heated garlic juice, dehydrated garlic powder, and aged garlic extract all significantly enhanced natural killer cell numbers and activity, only aged garlic extract and heated garlic juice inhibited the growth of tumor cells in mice (Kasuga et al. 2001).

Dr. Abdullah evaluated the percentage of tumor kill using raw and aged (Kyolic brand) garlic. Raw garlic killed 139% of tumor cells compared to an untreated group, while Kyolic killed 159% (Abdullah et al. 1988). Note: Defining the most efficacious type of garlic is confounding. Some physicians and clinicians report greater gains from odorous garlic supplementation. If garlic is part of your nutritional program, experiment with different varieties, assessing both subjective and objective improvements. It is highly possible that different metabolic types respond differently to various forms of garlic.

A good source of supplemental garlic is PureGar Caps. PureGar Caps contain the highest available potency (9 mg) of the active allicin compound, deemed by some as the yardstick for measuring the worth of garlic. Use 4 capsules, 2-4 times daily, with meals. If Kyolic aged garlic is the selection, use one 1000-mg caplet daily with meals. PureGar can cause a temporary gastric burning and pungent odor, whereas Kyolic aged garlic extract is free of these effects. No serious side effects have been reported.

Evaluating hundreds of garlic users, however, it should be noted that garlic thins the blood, and for some individuals (particularly those using anticoagulants) it is essential to abstain from or to watchfully monitor supplementation coagulation status.

Therapeutic factors contained in garlic include magnesium, selenium, 17 amino acids, 33 sulfur compounds, and vitamins B1, A, and C, as well as germanium. Germanium has been shown to induce production of interferon, enhance natural killer cell activity, and activate macrophage activity in experimental animals (Aso 1985).

Glutamine--increases NK cell activity, decreases PGE2 synthesis, inhibits tumor growth, stabilizes weight loss, and reduces incidence of stomatitis and infection
Tumors typically have high concentrations of glutamine; thus, physicians have been reluctant to add supplemental glutamine to a cancer protocol. However, oral glutamine (1 gram per kg of body weight a day administered to rats) upregulated tissue glutathione (a powerful antioxidant) by 25% and increased natural killer cell activity 2.5-fold. PGE2 synthesis (a pro-inflammatory prostaglandin that fuels tumor growth) decreased and tumors were inhibited by 40% (Klimberg et al. 1996a).

When glutamine accompanied either chemotherapy or radiotherapy, it protected the host and actually increased the selectivity of therapy for the tumor. This was evidenced among a group of rats (receiving either methotrexate, cyclophosphamide, or cisplatin) whose tumor reduction nearly doubled with glutamine supplementation (Klimberg et al. 1992, 1996b).

Researchers also observed that glutamine decreased progression of tumor formation in rats implanted with mammary tumors, suggesting oral glutamine may be useful as a chemopreventive in breast cancer (Feng et al. 1997). Oral glutamine maintained lymphocyte numbers and protected the gut of esophageal cancer patients during radio/chemotherapies (Yoshida et al. 1998).

Glutamine typically stabilizes weight loss by preserving intestinal function and allowing better nutrient absorption. Subsequently, glutamine prolongs survival by slowing down catabolicwasting, a disorder characterized by weight loss, diminished muscle mass, and loss of body fat. Fewer incidences of stomatitis (a generalized inflammation of the oral mucosa) and bouts of infection help reduce the number of days spent in a hospital (Anderson et al. 1998). Harvard University research showed that glutamine supplementation decreased medical expenses of leukemia patients undergoing bone marrow transplants by $21,095 per patient (MacBurney et al. 1994). (The retail cost of glutamine is $10.00 per day.)

A suggested glutamine dosage is 2 or more grams a day taken on an empty stomach. Glutamine is regarded as nontoxic, but cancer patients contemplating higher dosages should do so only after consulting with a health care provider.

Inositol hexaphosphate (IP-6)--activates natural killer cells, promotes differentiation, supports p53 activity, and normalizes the cell cycle by modifying signal transduction pathways
IP-6, a promising anticancer compound sold as a nutritional supplement, is a combination of inositol (a B vitamin) and phytic acid, also known as inositol hexaphosphate. According to Dr. A. Shamsuddin, M.D., Ph.D., who introduced IP-6 after more than 15 years of research, it works by enhancing the body's ability to defend itself against cancer, making it of equal importance as either a cancer preventive or therapeutic agent.

Inositol hexaphosphate is a sugar, very much like glucose, except it has six phosphates attached to its molecules. Every animal and plant species tested had varying levels of IP-6, but the highest amounts were found in rice, about 2% by weight: 100 grams of rice provide approximately 2 grams of IP-6, but even that amount is not readily available. Since the body is dependent upon digestive enzymes to break it down, only a meager amount is actually absorbed from foodstuffs. Thus, IP-6 in encapsulated or bulk forms should be of special interest to cancer patients and those desiring protection against cancer.

The following chemotherapeutic properties are assigned to the immune modulator:

• IP-6 activates natural killer cells, cells that work without antibody participation (Baten et al. 1989).
• IP-6 decreases cellular proliferation (Sakamoto et al. 1993; Shamsuddin et al. 1989b). Illustrative of its potential, IP-6 reduced large intestinal cancer (by regulating cell proliferation) in F344 rats even when the treatment was begun 5 months after carcinogenic induction (Shamsuddin et al. 1989a).
• IP-6 promotes differentiation (“normalization”) of cancer cells, that is, an unspecialized, atypical cell structure assumes the likeness of the tissue of origin, indicating the virulence of the malignancy is waning (Yang et al. 1995). IP-6 was shown to inhibit growth and induce differentiation in HT-29 human colon cancer cells, making it valuable as an adjunctive treatment in colon cancer. IP-6 also strongly inhibited growth and induced differentiation in human prostate cancer cells (PC-3) in both in vitro and in vivo studies (Shamsuddin et al. 1995).
• IP-6 has been effective against every cancer cell tested (Shamsuddin et al. 1997; Grases et al. 2002).
• After inducing cancer in laboratory animals, IP-6 administered either orally or by injection at the site of the tumor, or intraperitoneally, resulted in tumors two-thirds smaller than the controls. As tumors reduced in size, survival rate increased (Shamsuddin et al. 1989a).
• IP-6 increases expression of the tumor suppressor gene p53 by up to 17-fold. p53 acts on cells under stress, such as those with DNA damage, reducing proliferation and encouraging apoptosis. When cancer arises, a mutation in p53 is commonly involved. Lastly, since loss of p53 function increases cancer cells' resistance to chemotherapeutic agents, the stimulating action of IP-6 on p53 makes it an attractive adjuvant chemotherapeutic agent (Shamsuddin et al. 1997; Saied et al. 1998).

Toxicity studies (dating back to 1958) showed that a daily dose of 9 grams of IP-6 for 3 years resulted in side effects, including lesser incidences of kidney stones and fatty liver, as well as lower cholesterol levels. It is important to note that IP-6 does not kill cancer cells, as most anticancer agents do; thus, hair loss and immune suppression do not occur. A suggested dosage of 1-3 grams a day is adequate for most individuals. For those requiring larger doses, a powder is available (1 scoop twice daily is equivalent to 16 capsules, supplying about 6.4 grams of IP-6).

Lactoferrin--is immunoregulatory, inhibits angiogenesis, and binds iron
Perhaps one of the most promising therapeutic uses of lactoferrin, a milk protein with bacteriostatic properties, may be as a nontoxic, anticancer agent. Lactoferrin, a minor fraction of whey, results in a significant reduction in the incidence of esophageal, lung, bladder, and colon cancer in laboratory rats (Ushida et al. 1999; Masuda et al. 2000; Tsuda et al. 2002).

Since evidence indicates milk products protect against colon cancer, researchers speculate that bovine lactoferrin, a natural ingredient in milk, may be the chemoprotective agent (Tsuda et al. 2000b). Rats treated with a carcinogen and supplemented with 2% bovine lactoferrin for 36 weeks had a reduced incidence of colon cancer (27% of that observed in a control group; rats receiving 0.2% bovine lactoferrin reduced incidence to 46%). A remarkable 43% reduction in spontaneous lung metastasis (compared to controls) occurred after implanting colon carcinoma 26 (Co 26 Lu) in lactoferrin-treated laboratory animals (Tsuda et al. 2000a).

In addition to inhibiting angiogenesis (the vascular network that sustains the tumor), lactoferrin maintains the integrity of the immune system (Yoo et al. 1997; Tsuda et al. 2002). Typically, bovine lactoferrin prompts an increase in the number of natural killer cells, as well as the cytotoxicity of white blood cells (Tsuda et al. 2000a). The antibiotic, anti-inflammatory, and immune-modulating properties of lactoferrin appear active against the gastritis-, ulcer-, and cancer-inducing bacterium Helicobacter pylori (Dial et al. 2002).

Lactoferrin, a natural iron-binding protein, scavenges free radicals in fluids and inflamed areas, suppressing free radical mediated damage. It decreases the availability of iron in neoplastic cells, depriving them of an iron supply (Khan et al. 2001; Weinberg 2001).

The suggested dosage is 300-900 mg a day of the superior apolactoferrin (iron-depleted) form of lactoferrin. Lactoferrin is a natural component of cows' and human mothers' milk, but is also found in the milk of sheep, goats, and pigs.

Melatonin--is an immune modulator that increases the survival time of most cancer patients
Some cancer patients are now taking melatonin, an immune-modulating neurohormone, as part of a comprehensive, nontoxic cancer treatment. The cone-shaped pineal body, a small but crucial gland located in the brain, produces melatonin, a hormone that influences sexual maturation but also appears to play an important role in cancer.

Melatonin supplementation appears to restore circadian rhythms, which diminish or disappear with age. When melatonin's circadian rhythm is abolished, the aging process is accelerated, life span is shortened, and an increase in spontaneous tumors occurs (Maestroni 1999). It has been shown that when the defense system is compromised due to disrupted rhythms, tumors grow two to three times faster (Filipski et al. 2002).

Melatonin also protects and restores normal blood-cell production caused by the toxicity of conventional treatments; a profile shared with the FDA-approved drugs Neupogen, a granulocyte colony-stimulating factor (G-CSF), and Leukine, a granulocyte-macrophage colony-stimulating factor (GM-CSF). A combination of melatonin and low-dose interleukin 2 (IL-2) neutralizes treatment-induced lymphocytopenia, a decrease in the numbers of lymphocytes in the peripheral circulation of cancer patients (Lissoni et al. 1993).

Researchers found the best way to amplify the antitumoral activity of low dose IL-2 is by not coadministering another cytokine but rather cosupplementing with the immune-modulating neurohormone melatonin (Lissoni et al. 1994a). This is hopeful news for a subset of cancer patients, because melatonin has been shown to cause tumor regression in neoplasms nonresponsive to IL-2 (Maestroni 1999).

The Division of Radiation Oncology of the San Gerardo Hospital (Milan) developed the following protocol for 80 patients with advanced metastatic tumors (Lissoni et al. 1994a). The patients were randomized to receive 3 million IU of IL-2, 6 days a week, for 4 weeks or IL-2 plus 40 mg a day of melatonin. A complete response was achieved in 3 of 41 patients treated with IL-2 plus melatonin and in none of the patients receiving only IL-2. A partial response occurred in 8 of 41 patients treated with IL-2 plus melatonin and in 1 of 39 patients treated with IL-2. Tumor regression rate was significantly higher in patients using IL-2 and melatonin compared to those receiving IL-2 (11/41 versus 1/39). The survival rate at 1 year was higher in patients treated with IL-2 and melatonin than in the IL-2 group (19/41 versus 6/39). Lymphocytic populations were consistently higher when melatonin accompanied the treatment and thrombocytopenia (a decrease in the number of circulating platelets) occurred less frequently.

For patients with bloodborne cancers, an IL-2/melatonin combination is also promising. Twelve patients (nonresponsive to standard therapies) evaluated the efficacy and tolerability of a combination of low-dose IL-2 plus melatonin in advanced malignancies of the blood, including non-Hodgkin's lymphoma, Hodgkin's disease, acute myelogenous leukemia, multiple myeloma, and chronic myelomonocytic leukemia. IL-2 was given 6 days a week for 4 weeks, along with oral melatonin (20 mg a day). Cancer was stabilized and did not progress in 8 of 12 (67%) participants for an average duration of 21 months. An additional benefit accrued as the melatonin/IL-2 therapy was well-tolerated (Lissoni et al. 2000).

Nonresectable brain metastasis remains an untreatable disease. Because of melatonin's cytostatic action (the ability to suppress the growth of cells) and its anticonvulsant activity, the pineal hormone may prove effective in the treatment of brain metastasis. In a study to test the theory, 50 patients with inoperable brain metastasis were given supportive care or supportive care plus 20 mg of melatonin nightly. Freedom from brain tumor progression and survival rates at 1 year were higher in patients who were treated with melatonin compared to those who received only supportive care (Lissoni et al. 1994b, 1996). Even when melatonin was unable to stop the progression of advanced, metastatic disease, it improved the performance status of patients (see Table 2).

Low melatonin levels play a role in escalating rates of breast cancer. As melatonin levels decrease, the secretion of estrogen increases. Nighttime production of melatonin inhibits the body's secretion of estrogen and decreases the proliferation of human breast cancer cells. Conversely, exposure to light during the night decreases melatonin production and increases cumulative lifetime estrogen levels, a sequence that may increase the risk of breast cancer.

In fact, two current studies show that women who work night shifts may increase their risk of breast cancer up to 60%. Blind women have a significantly lower risk (36% less) of breast cancer than normally sighted women because of consistently higher levels of melatonin (Kliukiene et al. 2001). Women, who are classed as only visually impaired, realize no protective effects in regard to breast cancer.