Plant Based Radiation Protection: Tulsi

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Plant Based Radiation Protection: Tulsi

It's a radioactive world

Radioactivity is a natural part of our environment and everyone is continually exposed to ionizing radiation from a vast array of natural sources such as the sun and radioactive elements within the earth. However, since Henri Becquerel and Madame Curie first described radioactivity at the turn of last century, humans have continued to concentrate natural radiation sources and use them for medical diagnosis and therapy, food preservation, power generation and the production of nuclear weapons.

Concentrated sources of ionizing radiation are relatively new on earth, yet all living systems have had to deal with low levels of radiation. Thus, many plants contain a range of protective phytochemicals and this protection may be conferred to animals that eat them. Perhaps the most potent plants in this regard are the 'adaptogens' such as tulsi (Ocimum sanctum or holy basil), which confer protection against a wide range of environmental stressors. Tulsi has been celebrated within Ayurveda for generations as an 'elixir of life', yet it seems likely that the use of tusi and other adaptogenic herbs will become even more important as the extent of global toxicity becomes apparent.   

Baby teeth and radiation leaks

Over the past half century, humanity's use of radioactive material has led to widespread contamination of our environment. The global spread of radioactivity first came to light in the late 1950s and early 1960s when a citizen science, 'Baby Tooth Survey', collected tens of thousands of baby teeth from around the world. This survey, led by Dr Louise Reiss and scientists from Washington University, revealed that levels of strontium-90 in baby teeth increased more than 50 times after the commencement of nuclear weapons testing. This finding led to the recognition that nuclear material released in one region can be distributed globally and was instrumental in pressuring the US, UK and Russian governments to sign the 1963 treaty banning above-ground nuclear testing.  

Despite the abolition of above-ground nuclear tests, human-induced radioactive contamination of the earth has continued. The production of radioactive waste from nuclear power generation, use of depleted uranium in armaments and industry, and the unintentional release of radioactive material from accidents at facilities such as Three Mile Island, Chernobyl and Fukushima, have all contributed to an increase in human radiation exposure. The use of radiation in medicine has also increased sixfold since 1980 [1] and there is an ever present threat of radiological or nuclear terrorism, or further catastrophic accidents that could place innumerable human lives in peril.

Radiation and random cellular events

Radioactivity is highly toxic to living tissues and may exacerbate the adverse effects of exposure to other chemical toxins and pre-existing disease. Radiation also has cumulative effects and is of greater risk to children and the unborn fetus, as well as having impacts on reproductive capacity, so that effects can be felt for generations.

The adverse effects of radiation are primarily due to the ionization of biological molecules and generation of free radicals and reactive oxygen species. These chemical species are unstable and damage cells due to uncontrolled reactions with fats, proteins and DNA.

While random cellular events induced by radiation are credited with the creation of superheros such as the Hulk and Spiderman, in real life such events are highly damaging to living cells and are more likely to induce cancer than confer superpowers. Tissues that have a high cell turnover such as the skin, gut, blood and immune system are particular susceptible to radiation-induced cellular damage, which manifest as burns, radiation sickness and cancer, such as the leukemia that killed Madame Curie.

Chemical radio-protection

While it is impossible to totally avoid exposure to radioactivity, there are chemical agents that can help to cope with, or counter, its effects. The use of radio-protective chemicals has been explored since the 1940s in order to protect against the effects of nuclear weapons and radiological/nuclear terrorism. Radio-protectants are also sought to protect nuclear industry workers and astronauts from radiation exposure, and protect normal tissues from the effects of radiotherapy.

Chemical radio-protectants are based on the finding that antioxidants present at the time of irradiation help scavenge free radicals before significant cellular damage occurs. It has also been found that chemical agents given after radiation exposure may assist in DNA repair, reduce inflammation and persistent radiation-induced oxidative stress and facilitate death (apoptosis) of damaged cells.

Currently, amifostine is the only approved radio-protectant drug and this is rarely used due to significant side effects. There are however, many natural compounds with radio-protective activity. Such compounds include sulfhydryl-containing compounds and anti-oxidant nutrients such as vitamins C and E, beta-carotene, N-acetyl cysteine and selenium, along with a range of phytochemicals found in plants such as Ginkgo biloba, Vitis vinifera (grape seed), Camellia sinensis (tea), Curcuma longa (turmeric), and Ocimum sanctum (tulsi or holy basil) [2].

Tulsi – general adaptogen and radio-protector

Of the plants with radio-protective properties, tulsi is the most studied. Considered the most potent adaptogen within Ayurvedic medicine, tulsi is revered within India as being without equal for its medicinal and spiritual properties. Tulsi is also known to have potent antioxidant and anti-inflammatory activity and is recommended to be taken regularly to help the body adapt to a variety of stressors.

Various laboratory and animal studies have found that tulsi's radio-protective effects include reducing the oxidative and chromosomal damage induced by gamma radiation and radioactive iodine [3-10]. This has led to research to develop radio-protective medicines from tulsi and phase II human trials are currently underway at the Defense Research and Development Organization in India [11].

The radio-protective effects of tulsi are, at least partly, attributed to its content of the water-soluble flavonoids, orientin and vicenin. Low doses of these flavonoids have been shown to protect against radiation-induced cellular damage in animal and human cells through increased anti-oxidant enzymes activity and free radical scavenging and reduced lipid peroxidation [4, 12-16].

The finding that water-based tulsi extracts enhance survival of mice exposed to whole-body gamma radiation and are more radio-protective than alcoholic extracts [17], suggests that the radio-protective properties of tulsi are available when tulsi is taken as a tea. Regular consumption of tulsi tea may therefore increase resistance to the harmful effects of ionizing radiation, in addition to being recommended as a good strategy to promote longevity and enhance physical and mental health.

Exposure metrics  

Knowing your radiation exposure can be difficult because radiation is invisible and exposure is cumulative and may occur through multiple routes including ingestion, inhalation, absorption and injection. There are also many uncertainties in estimating human exposure globally and despite more than 50 years passing since the Baby Tooth Survey held governments to account, there are currently no programs to monitor global human exposure to radiation.

In light of many recent and ongoing world events, there is a growing need for a coordinated effort to monitor global toxicity due to radioactive contamination and other industrial wastes. The need for human biomonitoring may be realized through the power of the internet and the emergence of innovative personal devices such as the airqualityegg.com and mylapka.com that provide ongoing measures of human exposures.

We may therefore be at the brink of a new era of citizen science where open-source, peer-2-peer platforms such as habitatmap.org allow citizens from around the world to collaborate on mapping global toxicity. Such initiatives may also serve to engage the world's brightest minds in developing measures aimed at mitigation and remediation measures.

In the meantime, we must all accept that the world is increasingly contaminated and try to take steps to limit our exposure and ensure our body's cellular defenses are well supported. This involves adopting healthy and sustainable lifestyle practices that include daily consumption of herbs such as tulsi and phytochemically rich plants to provide our cells with an ongoing supply of radio-protective phytonutrients.

While it is important to try to reduce exposure to environmental toxins, it may be just as important to reduce toxic stress. Therefore, any toxin reduction strategy should include not getting too caught up in Armageddon scenarios and focusing on positive attitudes and actions that will mitigate the effects of toxic mental and environmental stress rather than exacerbate them.

REFERENCES

1.         Mettler, F.A., Brenner, D., Coleman, C.N., Kaminski, J.M., Kennedy, A.R., Wagner, L.K., , Can Radiation Risks to Patients Be Reduced Without Reducing Radiation Exposure? The Status of Chemical Radioprotectants. American Journal of Roentgenology, 2011. 196: p. 616-618.

2.         Weiss, J.F., Landauer, M.R., , History and development of radiation-protective agents. Int. J. Radiat. Biol, 2009. 85(7): p. 539-573.

3.         Uma Devi, P., et al., In vivo radioprotection by ocimum flavonoids: Survival. Radiation Research, 1999. 151(1): p. 74-78.

4.         Uma Devi, P., K.S. Bisht, and M. Vinitha, A comparative study of radioprotection by Ocimum favonoids and synthetic aminothiol protectors in the mouse. British Journal of Radiology, 1998. 71(JULY): p. 782-784.

5.         Ganasoundari, A., P. Uma Devi, and M.N.A. Rao, Protection against radiation-induced chromosome damage in mouse marrow by Ocimum sanctum. Mutation Research - Fundamental and Molecular Mechanisms of Mutagenesis, 1997. 373(2): p. 271-276.

6.         Nayak and P. Uma Devi, Protection of mouse bone marrow against radiation-induced chromosome damage and stem cell death by the Ocimum flavonoids orientin and vicenin. Radiation Research, 2005. 163(2): p. 165-171.

7.         Joseph, L.J., et al., Radioprotective effect of ocimum sanctum and amifostine on the salivary gland of rats after therapeutic radioiodine exposure. Cancer Biotherapy and Radiopharmaceuticals, 2011. 26(6): p. 737-743.

8.         Bhartiya, U.S., et al., Protective effect of Ocimum sanctum L after high-dose 131iodine exposure in mice: An in vivo study. Indian Journal of Experimental Biology, 2006. 44(8): p. 647-652.

9.         Monga, J., et al., Antimelanoma and radioprotective activity of alcoholic aqueous extract of different species of Ocimum in C 57BL mice. Pharmaceutical Biology, 2011. 49(4): p. 428-436.

10.       Singh, N., Verma, P., Pandey, B.R., Bhalla, M., Therapeutic Potential of Ocimum sanctum in Prevention and Treatment of Cancer and Exposure to Radiation: An Overview. International Journal of Pharmaceutical Sciences and Drug Research, 2012. 4(2): p. 97-104.

11.       John, P., Wonder drug from tulsi extract may be your answer to cancer, in The Times of India2012: Ahmedabad.

12.       Uma Devi, P. and A. Ganasoundari, Modulation of glutathione and antioxidant enzymes by Ocimum sanctum and its role in protection against radiation injury. Indian Journal of Experimental Biology, 1999. 37(3): p. 262-268.

13.       Uma Devi, P., et al., Radiation protection by the Ocimum flavonoids orientin and vicenin: Mechanisms of action. Radiation Research, 2000. 154(4): p. 455-460.

14.       Vrinda B, U.D.P., Radiation protection of human lymphocyte chromosomes in vitro by orientin and vicenin. Mutat Res, 2001. 498(1-2): p. 39-46.

15.       Reshma, K., et al., Radioprotective effects of ocimum flavonoids on leukocyte oxidants and antioxidants in oral cancer. Indian Journal of Clinical Biochemistry, 2008. 23(2): p. 171-175.

16.       Reshma, K., et al., Effect of ocimum flavonoids as a radioprotector on the erythrocyte antioxidants in oral cancer. Indian Journal of Clinical Biochemistry, 2005. 20(1): p. 160-164.

17.       Devi, P.U. and A. Ganasoundari, Radioprotective effect of leaf extract of Indian medicinal plant Ocimum sanctum. Indian Journal of Experimental Biology, 1995. 33(3): p. 205-208.

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