We’ve heard that the shortening of telomeres may cause cancer, which may also be attributed to the accumulation of waste products due to aging in our mitochondria. While we can take active steps to minimize our risk of cancer, such as avoiding smoking, managing our stress levels, eating properly and getting quality sleep, the evidence suggests that if we live long enough, we will develop cancer – probably.
This blog post puts forward the notion that isotopic carbon 14 may also be a cause of cancer. The Washington Nuclear Museum published data advancing that carbon 14 can be inhaled, come from drinking water or from contaminated food, though it is also known to be found naturally in nature and said to behave just like carbon 12.
Data on Carbon in nature
Carbon 12 makes up 99 % of the total carbon on earth, Carbon 13 makes up 1 % and Carbon 14 (14C) exists only in trace amounts, perhaps only 1 or 1.5 atoms out of every 1012. 14C has a half-life of 5730 years, after which it spontaneously changes to Nitrogen. This is the key attribute leading to the idea that it may be dangerous. Carbon and Nitrogen atoms have very different properties. DNA is delicate, and quite loaded with carbon, as expected by anyone who has taking organic chemistry.
Carbon in humans: Simple math
Nucleotides have a triphosphate, sugar and a base, such as: A, T, C, G, U, etc. To keep the calculation simple, we assume there are 15 carbons per nucleotide.
We have three billion base pairs of nucleotides in each cell nucleus (3×109), while only one percent of DNA in a mature cell has a functional role – thus prone to a mutation with consequences. Finally, let’s assume a human adult has 25 trillion cells (25×1012).
The calculation is static and excludes the carbon we breathe, the carbon in our mitochondria and the carbon in our proteins and enzymes. It is a gross over simplification, though reasonably valid for our purposes – because we are under-reporting the real amount.
15 * 3 x 109 * 25 x 1012 * 0.01 = 1,125 x 1022
Per nucleotide in DNA Cells with DNA 1% of DNA total
This accounts for all forms of Carbon. We can now isolate and account for 14C and account for the rare occurrence, averaging one every 5730 years. For simplicity, we use a 70 year old individual.
1,125 x 1022 / 1012 = 1,125 x 1010 * 0.01 = 1.,125×108
total C./adult trace amounts total Carbon-14 70/5730 years
That’s 112 500 000 occurrences, – with only one possibly leading to impaired and dangerously mutated DNA.
Note: We are making the assumption that a Carbon atom switching to a Nitrogen atom within our DNA is bad news, whether chemically or due to any radioactivity. One Concordia Ph.D. teachers expressed their opinion that it would, in fact, be bad news, though quick to add that it would be rare.
The numbers and compelling and seemingly conclusive: this occurs in the human body. Would it lead to a genetic mutation or would the body have defensive mechanisms and repair mechanisms to neutralize the threat, is it even accurate to call this a threat? The real answer is that, in the larger scheme of things, it’s very low on the list of carcinogenic agents. Perhaps it might surprise you that the number of single-point mutations resulting from the afternoon Montreal sunlight is significantly higher than this risk, with dozens of point mutations on every square Centimer of skin every second  – and this is something we can act on: use sunscreen. We are seemingly at the mercy of pure luck and chance with 14C.
I particularly like the statistic that 99% of lung cancers in the USA are smokers, and 99% of smokers never develop lung cancer, though I am at a loss to recall the source of the quote.
 Ending Aging, Aubrey de Grey.
Idea and written by: Mark Balchunas, BSc at Concordia