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Circadian Rhythms and Gene Regulation02:19

Circadian Rhythms and Gene Regulation

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The biological clock is involved in many aspects of regulating complex physiology in all animals. It was in 1935 when German zoologists, Hans Kalmus and Erwin Bünning, discovered the existence of circadian rhythm in Drosophila melanogaster. However, the internal molecular mechanisms behind the circadian clock remained a mystery until 1984, when Jeffrey C. Hall, Michael Rosbash, and Michael W. Young discovered the expression of the Per gene oscillating over a 24-hour cycle. In subsequent...
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Biological Clocks and Seasonal Responses02:45

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The circadian—or biological—clock is an intrinsic, timekeeping, molecular mechanism that allows plants to coordinate physiological activities over 24-hour cycles called circadian rhythms. Photoperiodism is a collective term for the biological responses of plants to variations in the relative lengths of dark and light periods. The period of light-exposure is called the photoperiod.
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Understanding Sleep01:11

Understanding Sleep

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Sleep, an essential biological state, involves significant reductions in physical activity, sensory awareness, and interaction with the environment. This complex physiological process is primarily regulated by specific brain regions, notably the hypothalamus and pons, which govern the sleep-wake cycle or circadian rhythm.
The circadian rhythm, a nearly 24-hour cycle, is deeply influenced by environmental light cues. Light exposure directly affects the hypothalamus, which in turn regulates...
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Sleep-Wake Cycles01:24

Sleep-Wake Cycles

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Sleep is an essential physiological process vital to maintaining overall well-being. The reticular activating system (RAS), a network of neurons in the brainstem, regulates wakefulness and sleep. While it may seem passive, sleep consists of distinct cycles, each with its unique characteristics and functions. Two key sleep phases are non-rapid eye movement (NREM) and  rapid eye movement (REM).
NREM Sleep
NREM sleep comprises four progressive stages that seamlessly merge:
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The Pineal Gland01:02

The Pineal Gland

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The pineal gland, a diminutive endocrine structure named for its pinecone-shaped appearance, is situated atop the third ventricle within the diencephalon region of the forebrain. This gland, composed of secretory cells known as pinealocytes arranged in compact cords and clusters around dense particles of calcium salts, plays a pivotal role in hormonal regulation.
The primary secretion of the pineal gland is the hormone melatonin, derived from serotonin. The concentration of melatonin in the...
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Chronopharmacokinetics: Circadian Rhythms and Influence on Drug Response01:15

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Circadian rhythms are cyclic changes that are crucial in plasma drug concentrations. Various standard circadian parameters, including core body temperature, heart rate, and other cardiovascular factors, directly impact disease states and the therapeutic response to drug therapy.
The time of drug administration is an important factor to consider, as it can influence the toxic dose of a drug. For example, a study conducted by Prins et al. in 1997 examined the effects of the timing of...
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Related Experiment Video

Updated: Feb 19, 2026

Parallel Measurement of Circadian Clock Gene Expression and Hormone Secretion in Human Primary Cell Cultures
06:53

Parallel Measurement of Circadian Clock Gene Expression and Hormone Secretion in Human Primary Cell Cultures

Published on: November 11, 2016

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Dissipative structures and biological rhythms.

Albert Goldbeter1

  • 1Unité de Chronobiologie théorique, Service de Chimie physique et Biologie théorique, Faculté des Sciences, Université Libre de Bruxelles (ULB), Campus Plaine, CP 231, B-1050 Brussels, Belgium.

Chaos (Woodbury, N.Y.)
|November 3, 2017
PubMed
Summary
This summary is machine-generated.

Biological rhythms, from cellular to organismal levels, are crucial for physiological functions. Their disruption can lead to various disorders, highlighting their importance in health and disease.

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Area of Science:

  • Biological rhythms and oscillations
  • Systems biology
  • Physiology and pathophysiology

Background:

  • Biological systems exhibit sustained oscillations across all organizational levels.
  • These rhythms span diverse periods and mechanisms, influencing key physiological functions.
  • Dysfunction of biological rhythms is linked to numerous physiological disorders.

Purpose of the Study:

  • To review cellular and supracellular biological rhythms.
  • To trace the historical development of biological rhythm studies alongside chemical oscillations.
  • To present the roles of biological rhythms in physiological control and associated pathologies.

Main Methods:

  • Literature review of biological rhythms.
  • Analysis of historical perspectives on oscillations.
  • Compilation of examples of cellular and supracellular rhythms.
  • Discussion of Prigogine's dissipative structures concept.

Main Results:

  • Overview of diverse biological rhythms including neural, cardiac, metabolic, and circadian rhythms.
  • Examples range from glycolysis oscillations to cell cycle dynamics and transcription factor oscillations (NF-κB, p53).
  • Two tables categorize rhythms by period, physiological roles, and pathophysiology.

Conclusions:

  • Biological rhythms are fundamental to life, controlling essential functions.
  • Understanding these rhythms is vital for comprehending health and disease.
  • Prigogine's dissipative structures offer a unifying framework for diverse biological oscillations.