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関連する概念動画

Breathing01:05

Breathing

The process of breathing, inhaling and exhaling, involves the coordinated movement of the chest wall, the lungs, and the muscles that move them. Two muscle groups with important roles in breathing are the diaphragm, located directly below the lungs, and the intercostal muscles, which lie between the ribs. When the diaphragm contracts, it moves downward, increasing the volume of the thoracic cavity and creating more room for the lungs to expand. When the intercostal muscles contract, the ribs...
Pressure Relationships in Thoracic Cavity01:24

Pressure Relationships in Thoracic Cavity

Breathing, otherwise known as pulmonary ventilation, is the process of air movement into and out of the lungs. The main mechanisms propelling pulmonary ventilation are atmospheric pressure (Patm), intra-pulmonary (Ppul ) or intra-alveolar pressure (Palv) within the alveoli, and intrapleural pressure (Pip) within the pleural cavity.
Breathing Mechanisms
Both intra-alveolar and intrapleural pressures rely on specific lung properties. The ability to breathe—allowing air to enter the lungs during...
Pulmonary Cycle: Exhalation01:17

Pulmonary Cycle: Exhalation

In terms of human respiration, the act of expelling air, known as exhalation (or expiration), operates on the principle of pressure gradients. During expiration, the pressure within the lungs exceeds that of the surrounding atmosphere. Under normal conditions, quiet breathing involves passive exhalation and is free of muscular contractions. This is because the exhalation process is driven by the natural elastic recoil of the lungs and chest wall, both of which have an inherent tendency to...
Factors Affecting Pulmonary Ventilation01:19

Factors Affecting Pulmonary Ventilation

Besides the pressure difference between the external environment and the lungs, the airflow rate and ease of pulmonary ventilation are also influenced by three other factors: surface tension of the fluid in the alveoli, compliance of the lungs, and airway resistance.
Alveolar Surface Tension
The alveolar fluid lines the luminal surface of the alveoli and exerts a force called surface tension. This force is caused by the polar water molecules in the liquid being more strongly attracted to each...
Physical Principles Governing Gas Exchange01:16

Physical Principles Governing Gas Exchange

Gas behavior plays a vital role in understanding bodily processes such as external and internal respiration. External respiration involves the diffusion of oxygen into the blood and carbon dioxide out of it in the lungs. In contrast, internal respiration happens in body tissues, where these gases move in opposite directions.
Gas Laws Governing Respiration
The behavior of gases is guided by Dalton's Law of partial pressures and Henry's Law.
Dalton's Law asserts that the total pressure exerted by...
Application of Integration: Problem Solving01:30

Application of Integration: Problem Solving

The process of breathing involves the periodic intake and expulsion of air, known as the respiratory cycle, which typically lasts about five seconds. Modeling the volume of air inhaled into the lungs as a function of time provides insight into both the dynamics and efficiency of pulmonary ventilation. This volume is determined by integrating the airflow rate over time, which captures the cumulative effect of air entering the lungs.Sinusoidal Model of AirflowAirflow during respiration is not...

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関連する実験動画

Updated: Jul 9, 2026

Combining Volumetric Capnography And Barometric Plethysmography To Measure The Lung Structure-function Relationship
08:25

Combining Volumetric Capnography And Barometric Plethysmography To Measure The Lung Structure-function Relationship

Published on: January 8, 2019

生理学:膨張する肺の動的不安定性.

Adriano M Alencar1, Stephen P Arold, Sergey V Buldyrev

  • 1Department of Biomedical Engineering, Boston University, Boston, Massachusetts 02215, USA. adriano@bu.edu

Nature
|June 21, 2002
PubMed
まとめ

肺の呼吸道は,喘息などの病気で崩壊することがあります. これをモデル化すると,負の弾性抵抗を引き起こす"雪崩ショック"が明らかになり,ガスの交換条件の障害に対する肺の深層空調の理解が向上します.

科学分野:

  • 肺医学は肺を治療する薬です.
  • バイオフィジックス 生物物理学
  • 流体力学 流体力学

背景:

  • 喘息のような肺疾患は,呼吸器の流れを制限し,呼吸道崩壊とガス交換の妨げにつながります.
  • 肺の膨張のメカニズムを理解することは,特に崩壊した領域では,呼吸器の健康にとって非常に重要です.

研究 の 目的:

  • インスピレーション中に肺の領域が崩壊した時のインフレのダイナミクスをモデル化するために.
  • 動的圧力不安定の現象とその肺力学との関係について調査する.
  • 肺の深い領域の換気とその呼吸器疾患への影響についての洞察を提供するためです.

主な方法:

  • 肺の膨張のモデルを開発した. 雪崩が二叉の呼吸道ネットワークを通して広がる.
  • 動的圧力不安定のカスケードを分析し",雪崩ショック"と名付けた.
  • これらの不安定性,特に負の弾性抵抗の熱力学的影響を調査した.

主要な成果:

  • 肺の崩壊した領域の膨張は,呼吸道ネットワークの雪崩としてモデル化することができます.
  • 雪崩の衝撃は,動的圧力不安定をもたらし,負の弾性抵抗として表れます.
  • この負の弾性抵抗は,雪崩モデルによって説明される明らかな熱力学的パラドックスである.

さらに関連する動画

Microtensiometer for Confocal Microscopy Visualization of Dynamic Interfaces
08:05

Microtensiometer for Confocal Microscopy Visualization of Dynamic Interfaces

Published on: September 9, 2022

Dual Test Gas Pulmonary Diffusing Capacity Measurement During Exercise in Humans Using the Single-Breath Method
08:44

Dual Test Gas Pulmonary Diffusing Capacity Measurement During Exercise in Humans Using the Single-Breath Method

Published on: February 2, 2024

関連する実験動画

Last Updated: Jul 9, 2026

Combining Volumetric Capnography And Barometric Plethysmography To Measure The Lung Structure-function Relationship
08:25

Combining Volumetric Capnography And Barometric Plethysmography To Measure The Lung Structure-function Relationship

Published on: January 8, 2019

Microtensiometer for Confocal Microscopy Visualization of Dynamic Interfaces
08:05

Microtensiometer for Confocal Microscopy Visualization of Dynamic Interfaces

Published on: September 9, 2022

Dual Test Gas Pulmonary Diffusing Capacity Measurement During Exercise in Humans Using the Single-Breath Method
08:44

Dual Test Gas Pulmonary Diffusing Capacity Measurement During Exercise in Humans Using the Single-Breath Method

Published on: February 2, 2024

結論:

  • 雪崩模型は,崩壊した地域における肺膨張の動態に関する新しい説明を提供します.
  • 負の弾性抵抗を理解することで,肺の深部部における換気に関する新しい洞察が得られます.
  • 発見は,重度の喘息などのガスの交換が損なわれる疾患の治療に役立つかもしれない.