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Related Concept Videos

Cardiac Cycle01:29

Cardiac Cycle

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The cardiac cycle refers to the sequence of events that occur in the heart from the beginning of one heartbeat to the next. It's characterized by alternating periods of contraction (systole) and relaxation (diastole) of the heart muscles.
During the cardiac cycle, blood flow through the heart is regulated entirely by changing pressure gradients. This sequence of events begins with the heart in a state of total relaxation, known as mid-to-late diastole, during which blood passively flows from...
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The Cardiac Cycle01:13

The Cardiac Cycle

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The heart beats rhythmically in a sequence called the cardiac cycle—a rapid coordination of contraction (systole) and relaxation (diastole).
The Process
Electrical signals—sent from the sinoatrial (SA) node in the right atrial wall to the atrioventricular (AV) node between the right atrium and right ventricle—cause both atria to simultaneously contract. When the signal reaches the AV node, it pauses for approximately a tenth of a second, allowing the atria to contract and...
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Physiology of the Heart: The Cardiac Cycle01:18

Physiology of the Heart: The Cardiac Cycle

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The cardiac cycle describes the events from one heartbeat to the next. It includes three main phases: diastole, atrial systole, and ventricular systole, all driven by changes in chamber pressures and the function of heart valves.
Diastole: The Relaxation Phase
During diastole, all four heart chambers relax. The atrioventricular (AV) valves open, and the semilunar valves close. This phase sees the lowest chamber pressures, promoting ventricular filling. Venous blood enters the heart through the...
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Overview of the Cardiovascular System01:14

Overview of the Cardiovascular System

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The cardiovascular system is a vital transportation system in the body. It comprises the heart and blood vessels and facilitates the exchange of gases, nutrients, and waste products.
Heart
The heart is the central pump of the cardiovascular system that circulates blood throughout the body. It comprises two atria receiving the blood and two ventricles pumping blood out of the heart. Their rhythmic contractions, called heartbeats, ensure that blood flow remains continuous.
Blood Vessels
Blood...
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Anatomy of the Circulatory System02:03

Anatomy of the Circulatory System

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The human circulatory system consists of blood, blood vessels that carry blood away from the heart, around the body, and back to the heart, and the heart itself, which acts as a central pump. The systemic circuit supplies blood to the whole body, the coronary circuit supplies blood to the heart, and the pulmonary circuit supplies blood flow between the heart and lungs.
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Correlation between ECG and Cardiac Cycle01:25

Correlation between ECG and Cardiac Cycle

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The electrical signals recorded on an electrocardiogram (ECG) occur before the mechanical processes of contraction and relaxation during the cardiac cycle.
A cardiac action potential originates in the SA node and spreads throughout the atria and the AV node in approximately 0.03 seconds. This results in the P wave in an ECG and triggers atrial contraction. The action potential is then briefly slowed at the AV node, allowing the atria to contract and fill the ventricles with blood before...
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Assessing Cerebral Autoregulation via Oscillatory Lower Body Negative Pressure and Projection Pursuit Regression
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Decadal Cycles in the Human Cardiovascular System.

Franz Halberg1, Germaine Cornelissen1, Robert B Sothern1

  • 1Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN 55455, US.

World Heart Journal
|May 27, 2014
PubMed
Summary
This summary is machine-generated.

Long-term self-monitoring reveals decadal cycles in blood pressure and heart rate, termed "Aeolian" components. These cycles may aid in diagnosing vascular variability anomalies and predicting hypertension risk.

Keywords:
blood pressurecardiovascular systemcircadecadalscircaundecennianscosmosheart rate

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Area of Science:

  • Chronobiology and Cardiovascular Physiology
  • Non-linear time series analysis of physiological data

Background:

  • Physiological self-surveillance, including around-the-clock monitoring for decades, has revealed complex temporal patterns.
  • Previous research has identified various physiological and environmental cycles, some with non-stationary characteristics.

Purpose of the Study:

  • To document the presence and characteristics of long-term (decadal) cycles in systolic and diastolic blood pressure and heart rate.
  • To explore the potential of these 'Aeolian' cycles in the diagnosis of Vascular Variability Anomalies (VVAs) and cardiovascular risk assessment.

Main Methods:

  • Longitudinal physiologic self-surveillance data from seven authors, including around-the-clock monitoring.
  • Non-linear estimation of period uncertainties (τs) and comparison of 95% confidence intervals (CIs) to assess cycle congruence.
  • Analysis of selective assortment among individuals, variables, and cycle characteristics (mean, circadian amplitude, acrophase).

Main Results:

  • Documented the presence of decadal (around 10-year) and longer 'Aeolian' cycles in blood pressure and heart rate.
  • Found congruence between components with periods clustering around 10 years.
  • Observed selective assortment in cycle characteristics across individuals and variables.

Conclusions:

  • Decadal and longer physiological cycles are present in self-monitoring individuals and may be significant for understanding vascular variability.
  • These 'Aeolian' cycles, particularly overswings, show potential as biomarkers for predicting hypertension and cardiovascular events.
  • Around-the-clock monitoring is crucial for establishing reference values for differential diagnosis of circadian versus circadecadal overswings and guiding treatment.