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- Challenges and Chances: A Review of the 1st Stem Cell Community Day
- Summertime, and the Livin’ Is Easy…
- Follow-on-Biologics – More than Simple Generics
- Bacteria Versus Body Cells: A 1:1 Tie
- Behind the Crime Scene: How Biological Traces Can Help to Convict Offenders
- Every 3 Seconds Someone in the World Is Affected by Alzheimer's
- HIV – It’s Still Not Under Control…
- How Many Will Be Convicted This Time?
- Malaria – the Battle is Not Lost
- Physicians on Standby: The Annual Flu Season Can Be Serious
- At the Forefront in Fighting Cancer
- Molecular Motors: Think Small and yet Smaller Again…
- Liquid Biopsy: Novel Methods May Ease Cancer Detection and Therapy
- They Are Invisible, Sneaky and Disgusting – But Today It’s Their Special Day!
- How Many Cells Are in Your Body? Probably More Than You Think!
- What You Need to Know about Antibiotic Resistance – Findings, Facts and Good Intentions
- Why Do Old Men Have Big Ears?
- The Condemned Live Longer: A Potential Paradigm Shift in Genetics
- From Research to Commerce
- Chronobiology – How the Cold Seasons Influence Our Biorhythms
- Taskforce Microbots: Targeted Treatment from Inside the Body
- Eyes on Cancer Therapy
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Chronobiology – How the Cold Seasons Influence Our Biorhythms
生命科学の探究
- 実験室の日常
- エッセー
- 医療
Image source: Walter Schießwohl
We wake up when it’s still dark… Through the day we try to catch a fleeting glimpse of sunlight and in the evening, we leave work at dusk...Autumn and winter are the dark seasons. The lack of light influences our mood, our vital parameters and our internal biorhythms.
Like all living beings, from bacteria through plants and animals, humans follow internal rhythms and cycles throughout their whole lives. We have a central clock which coordinates key bodily functions including our sleep-wake cycle, our heart rate and the body’s temperature. Cycles of activity or hormone release are also influenced by our internal periodic control system. Although most biorhythms follow daily cycles, shorter and longer intervals also occur. Some rhythms for example are based upon lunar phases or, as described here in detail, upon the changing seasons. The field of science which studies these rhythms is called chronobiology.Biorhythms are internal responses to environmental stimuli. The major factor in this process is sun light which is primarily responsible for regulating the body’s internal clock. But how does this work?It is a complex interaction between the brain and the individual cells within our body. Special receptors in our eyes respond to light intensity and transfer this information via the optic nerve to specific nerve cells within the brain’s core. This small and central part of the brain is called the suprachiasmatic nucleus and it performs the role of the body’s master clock. It communicates with other parts of the brain and regulates light dependent hormone release. This, in turn, stimulates millions of organ and tissue specific “clocks” within individual cells.
How does winter influence our biorhythms? In a nutshell, it’s because of the absence of sunlight during this time of the year. The most extreme situation is found around the polar areas where the sun does not appear at all for 6 months. However, even in other regions which are far enough from the equator to have seasons, the days get shorter from autumn through to winter.The low light levels cause a higher release of melatonin, the so-called sleeping hormone. Additionally, less activity hormones are produced because melatonin also decreases action within the thyroid gland. Therefore, people often feel more tired and listless in autumn and winter. Recent studies also suggest that increased melanin can affect levels of aggression through stimulating the production of the precursors of the sex hormones androgen and estrogen.
Every year many people suffer from seasonal affective disorder (SAD) or the “winter-blues”. One reason is the low concentration of the light-dependent happiness hormone, serotonin, during the dark months.However, not everything functions badly during the colder seasons. Studies using mice have revealed, for example, that their immune systems actually become stronger with the shortening of the days in autumn. This could also apply to humans since many regulatory cycles are similar within different mammal species. Another quite surprising finding in chronobiology is that the performance of our brain is also seasonally dependent and that it actually functions more effectively in winter. In studies, participants had to solve cognitive challenges at different times of the year whilst scientists simultaneously analyzed the location and the intensity of brain activity. Although, the quality of solving the challenges was consistent for each participant throughout the whole year, brain activity, in contrast, changed with the seasons. In winter, smaller amounts of effort were required from the brain to achieve the same quality of results as in the summer. The brain simply functions more efficiently in winter.
We wake up when it’s still dark… Through the day we try to catch a fleeting glimpse of sunlight and in the evening, we leave work at dusk...Autumn and winter are the dark seasons. The lack of light influences our mood, our vital parameters and our internal biorhythms.
An internal clock
Like all living beings, from bacteria through plants and animals, humans follow internal rhythms and cycles throughout their whole lives. We have a central clock which coordinates key bodily functions including our sleep-wake cycle, our heart rate and the body’s temperature. Cycles of activity or hormone release are also influenced by our internal periodic control system. Although most biorhythms follow daily cycles, shorter and longer intervals also occur. Some rhythms for example are based upon lunar phases or, as described here in detail, upon the changing seasons. The field of science which studies these rhythms is called chronobiology.Biorhythms are internal responses to environmental stimuli. The major factor in this process is sun light which is primarily responsible for regulating the body’s internal clock. But how does this work?It is a complex interaction between the brain and the individual cells within our body. Special receptors in our eyes respond to light intensity and transfer this information via the optic nerve to specific nerve cells within the brain’s core. This small and central part of the brain is called the suprachiasmatic nucleus and it performs the role of the body’s master clock. It communicates with other parts of the brain and regulates light dependent hormone release. This, in turn, stimulates millions of organ and tissue specific “clocks” within individual cells.
Darkness triggers…
How does winter influence our biorhythms? In a nutshell, it’s because of the absence of sunlight during this time of the year. The most extreme situation is found around the polar areas where the sun does not appear at all for 6 months. However, even in other regions which are far enough from the equator to have seasons, the days get shorter from autumn through to winter.The low light levels cause a higher release of melatonin, the so-called sleeping hormone. Additionally, less activity hormones are produced because melatonin also decreases action within the thyroid gland. Therefore, people often feel more tired and listless in autumn and winter. Recent studies also suggest that increased melanin can affect levels of aggression through stimulating the production of the precursors of the sex hormones androgen and estrogen.
Body functions adapt to winter
Every year many people suffer from seasonal affective disorder (SAD) or the “winter-blues”. One reason is the low concentration of the light-dependent happiness hormone, serotonin, during the dark months.However, not everything functions badly during the colder seasons. Studies using mice have revealed, for example, that their immune systems actually become stronger with the shortening of the days in autumn. This could also apply to humans since many regulatory cycles are similar within different mammal species. Another quite surprising finding in chronobiology is that the performance of our brain is also seasonally dependent and that it actually functions more effectively in winter. In studies, participants had to solve cognitive challenges at different times of the year whilst scientists simultaneously analyzed the location and the intensity of brain activity. Although, the quality of solving the challenges was consistent for each participant throughout the whole year, brain activity, in contrast, changed with the seasons. In winter, smaller amounts of effort were required from the brain to achieve the same quality of results as in the summer. The brain simply functions more efficiently in winter.
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