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March 14th is known as Pi Day, a day that celebrates the mathematical constant π (pi), which is approximately 3.14. Pi Day has become an annual event that celebrates not only pi but also other interesting numbers that have significance in mathematics and science. This paper explores the history and significance of Pi Day and other interesting numbers that have captured the imagination of mathematicians and scientists around the world.

Pi Day

Pi Day is celebrated on March 14th, as the first three digits of pi are 3.14. The day was first celebrated in 1988 by physicist Larry Shaw at the Exploratorium in San Francisco. Since then, Pi Day has become an annual event celebrated by math enthusiasts around the world [1]. On Pi Day, people celebrate by reciting the digits of pi, holding pie-eating contests, and engaging in other math-related activities.

Significance of pi

Pi is a mathematical constant that represents the ratio of the circumference of a circle to its diameter. It is an irrational number, meaning that it cannot be expressed as a finite decimal or fraction. Pi is an essential concept in mathematics and has numerous applications in physics, engineering, and other sciences [2]. The discovery and calculation of pi have been a significant milestone in the development of mathematics throughout history.

Other interesting numbers

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Pi is not the only number that has captured the imagination of mathematicians and scientists. Here are some other interesting numbers:

e: Euler’s number, also known as the natural logarithm, is a mathematical constant that is approximately equal to 2.718. It is used in calculus, probability, and other fields of mathematics and science [3].
Golden ratio: The golden ratio is a mathematical concept that describes the ratio of two quantities in which the ratio of the larger quantity to the smaller quantity is the same as the ratio of the sum of the quantities to the larger quantity. It is approximately equal to 1.618 and is often found in nature, art, and architecture [4].
Avogadro’s number: Avogadro’s number is a constant that represents the number of particles (atoms or molecules) in one mole of a substance. It is approximately equal to 6.022 x 10^23 and is used in chemistry and physics [5].
The Fibonacci sequence: The Fibonacci sequence is a series of numbers in which each number is the sum of the two preceding numbers. The sequence starts with 0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, and so on. The Fibonacci sequence appears in various natural phenomena, such as the arrangement of leaves on a stem and the growth patterns of seashells [6].

Conclusion

In conclusion, Pi Day and other interesting numbers have significant meaning and applications in mathematics and science. Pi is an essential concept that represents the ratio of a circle’s circumference to its diameter and has numerous applications in various fields. Other interesting numbers, such as e, the golden ratio, Avogadro’s number, and the Fibonacci sequence, have also played critical roles in the development of mathematics and science.

Source List:

“Celebrating Pi Day,” Exploratorium, accessed March 14, 2023, https://www.exploratorium.edu/pi
“Pi,” Wolfram MathWorld, accessed March 14, 2023, https://mathworld.wolfram.com/Pi.html
“e,” Wolfram MathWorld, accessed March 14, 2023, https://mathworld.wolfram.com/e.html
“The Golden Ratio,” Wolfram MathWorld, accessed March 14, 2023, https://mathworld.wolfram.com/GoldenRatio.html
“Avogadro’s Number,” Encyclopedia Britannica, accessed March 14, 2023, https://www.britannica.com/science/Avogadros-number
“Fibonacci Numbers and Nature,” The Fibonacci Association, accessed March 14, 2023, https://www.fibonacciassociation.org/Fibonacci-number-in-nature.html

Aging Is Like Burning Disks
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Why do we age? What is it that makes us age and grow saggy? How can we bring our youthful glow into adulthood and beyond? These are the questions that most women ask themselves. Joking, scientists and men alike ask the same questions. And you might find your answer in telomeres.

Brief Intro to Telomeres

Human cells divide at an average of 50-60 times in one lifespan. Every time they divide, the cell’s DNA has to be replicated. That way, a new chromosome can form and be used in the newly duplicated cell. However every time a cell duplicates, it comes at a cost. That is, the chromosomes get shorter and shorter. If they get short enough, the chromosomes can have their twining undone and our genetic data gets corrupted. Eventually, that cell dies.

Fortunately, chromosomes are like shoelaces with plastic caps. These plastic caps are what keep the shoelaces from getting undone. Chromosomes have their own plastic caps too. They are called telomeres. They are the extra DNA strands that a chromosome can afford to lose. They are what keep chromosomes from getting corrupt. So why are we not immortal? This is what an article from the University of Utah has to say about telomeres and division:

Yet, each time a cell divides, the telomeres get shorter. When they get too short, the cell no longer can divide and becomes inactive or “senescent” or dies. This process is associated with aging, cancer and a higher risk of death. So telomeres also have been compared with a bomb fuse.

They help to preserve genetic data when cells replicate in order to have fully functional healthy cells. RNA molecules are necessary in the process of copying DNA strands. Telomeres get shorter each time because these small RNA pieces need room on top of newly formed chromosomes.

Without telomeres, the ends of chromosomes would look like broken DNA, and the cell would try to fix something that wasn’t broken. That also would make them stop dividing and eventually die.

Telomerase, Cancer, and Aging

So is there something that keeps telomeres from disappearing? Actually there is an enzyme called telomerase. They fit on top of telomeres and are more prevalent in the younger years, however they also eventually disappear.

This is not the case for cancerous cells. Cancer cells activate the telomerase enzymes once the telomeres get dangerously short. This keeps the cancer cell’s DNA intact and allows them to multiply like mad dogs. In fact, measuring telomerase may be a new way to detect new cancer threats. If we learn how to stop telomerase from being activated, we may be able to make cancer cells experience aging just like healthy cells.

In one experiment, researchers blocked telomerase activity in human breast and prostate cancer cells growing in the laboratory, prompting the tumor cells to die. But there are risks.

Shorter telomeres are related to shorter lives. Unfortunately, there is no strong evidence yet that shows that telomerase can make cells immortal and prevent aging. There is also no strong evidence that raising telomerase levels would also trigger cancerous cells to form.

Laboratory tests have shown though that telomerase was able to keep human cells divide far beyond the average limit without becoming cancerous. If researched further, we can have a future where human cells can be mass produced for transplantation, especially in key roles such as cells that produce insulin for diabetes patients.

Sources:

Genetic Science Learning Center. “Are Telomeres the Key to Aging and Cancer?.” Learn.Genetics 12 March 2013 http://learn.genetics.utah.edu/content/begin/traits/telomeres/