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Feedback Regulation of Calcium Concentration01:27

Feedback Regulation of Calcium Concentration

3.5K
Calcium is an essential signaling molecule required for various cellular functions. Calcium pumps and ion channels on cell and organellar membranes, such as those on the endoplasmic reticulum (ER), regulate calcium concentrations inside the cell. They remain closed, keeping the cytosolic calcium levels low at a resting state.
Various transmembrane receptors, such as G protein-coupled receptors (GPCRs), elicit a response to extracellular signals by increasing cytosolic calcium. Activated GPCRs...
3.5K
Tension Response at Adherens Junctions01:26

Tension Response at Adherens Junctions

2.8K
The adherens junctions that anchor cells together are multi-protein complexes that dynamically adapt to mechanical stimuli such as tensile forces and shear stress. Mechanosensory proteins in these junctions can sense such mechanical stimuli and undergo a shift in their conformation, resulting in an altered function — a process called mechanotransduction.
α-Catenin as a Mechanosensory Protein
The α-catenin of adherens junctions is an allosteric protein with three VH (vinculin...
2.8K
Cell-matrix's Response to Mechanical Forces01:13

Cell-matrix's Response to Mechanical Forces

2.7K
In animal cells, the extracellular matrix allows cells within tissues to withstand external stresses and transmits signals from the outside of the cell to the inside. The extracellular matrix is extensive, and its composition varies between different types of tissues. For example, the reticular fibers and ground substance make up the ECM in loose connective tissue, while collagen and bone minerals make up the ECM of bone tissue. 
Anchoring junctions mechanically attach a cell to the...
2.7K
Generation of Action Potential in Skeletal Muscles01:24

Generation of Action Potential in Skeletal Muscles

5.6K
Every cell in the body maintains a membrane potential due to an uneven distribution of positive and negative charges across its plasma membrane. The membrane potential is measured in millivolts and quantifies the difference in charge across the membrane.
Like neurons, muscle cells are also regarded as excitable due to their capacity to change in response to stimuli, primarily due to voltage-gated ion channels embedded in their plasma membranes, which get activated by alterations in the...
5.6K
Motor Unit Stimulation01:20

Motor Unit Stimulation

1.9K
When the neuron of a motor unit fires an action potential, it triggers a series of events, leading to a twitch contraction in the muscle fibers. The process of excitation-contraction coupling is crucial in relaying the action potential to the muscle fibers.
The latent period of contraction marks the onset of excitation-contraction coupling, when the action potential propagates across the sarcolemma, preparing the muscle fibers for contraction. As the fibers enter the contraction phase, the...
1.9K
Cell Signaling Feedback Loops01:07

Cell Signaling Feedback Loops

6.6K
Positive and negative feedback loops are crucial for regulating biological signaling systems. These feedback loops are processes that connect output signals to their inputs.
Negative feedback loops
Most signaling systems have negative feedback loops that can perform different functions such as output limiter, and adaptation.
Output limiter
Upon receiving an input signal, the cellular response rapidly increases until a threshold is reached. Beyond this threshold, a negative feedback loop...
6.6K

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Updated: Sep 9, 2025

A Simplified System for Evaluating Cell Mechanosensing and Durotaxis In Vitro
09:50

A Simplified System for Evaluating Cell Mechanosensing and Durotaxis In Vitro

Published on: August 27, 2015

8.3K

生物学的組織における機械的フィードバックによる刺激性ダイナミクス

Fernanda Pérez-Verdugo1, Samuel Banks1,2, Shiladitya Banerjee1

  • 1Department of Physics, Carnegie Mellon University, Pittsburgh, PA, USA.

Communications physics
|September 2, 2025
PubMed
まとめ
この要約は機械生成です。

細胞のメカニズムと組織の幾何学は 生物学的システムにおける 脈動的な活動を誘導します 理論的枠組みは,細胞の伸縮と収縮が多細胞組織における波の伝播と活動パルスをどのように制御するかを明らかにしています.

さらに関連する動画

The Mechanics of Poro-Elastic Contractile Actomyosin Networks As a Model System of the Cell Cytoskeleton
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The Mechanics of Poro-Elastic Contractile Actomyosin Networks As a Model System of the Cell Cytoskeleton

Published on: March 10, 2023

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Single Cell Durotaxis Assay for Assessing Mechanical Control of Cellular Movement and Related Signaling Events
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Single Cell Durotaxis Assay for Assessing Mechanical Control of Cellular Movement and Related Signaling Events

Published on: August 27, 2019

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関連する実験動画

Last Updated: Sep 9, 2025

A Simplified System for Evaluating Cell Mechanosensing and Durotaxis In Vitro
09:50

A Simplified System for Evaluating Cell Mechanosensing and Durotaxis In Vitro

Published on: August 27, 2015

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The Mechanics of Poro-Elastic Contractile Actomyosin Networks As a Model System of the Cell Cytoskeleton
08:50

The Mechanics of Poro-Elastic Contractile Actomyosin Networks As a Model System of the Cell Cytoskeleton

Published on: March 10, 2023

856
Single Cell Durotaxis Assay for Assessing Mechanical Control of Cellular Movement and Related Signaling Events
08:30

Single Cell Durotaxis Assay for Assessing Mechanical Control of Cellular Movement and Related Signaling Events

Published on: August 27, 2019

8.1K

科学分野:

  • バイオ物理学
  • 細胞メカニズム
  • 理論生物学

背景:

  • 脈動的な活動パターンは,機械化学的フィードバックによって駆動される生物学的システムで一般的です.
  • 信号伝播に対する細胞力学と幾何学の影響は十分に理解されていません.

研究 の 目的:

  • 刺激可能な多細胞組織におけるパルサチル活動のメカニカル起源と調節を説明する理論的枠組みを提示する.
  • 組織レベルでの活動パターンを支配する細胞力学と幾何学の役割を調査する.

主な方法:

  • 多細胞組織における脈動性活性に関する理論的枠組みを開発した.
  • 細胞レベルの機械的フィードバックをモデル化 (ストレッチで活性化された収縮性,活性要素の不活性化).
  • 機械的な時間スケールと組織幾何学に基づいて 伝播パルスと波の間の移行を分析した.

主要な成果:

  • 細胞レベルでの 単純な機械的なフィードバックメカニズムは 静止状態,長距離波の伝播,移動する活動パルスのような 組織レベルの現象を生成することができます
  • パルスから波の伝播への移行は,細胞の機械的応答時間スケールと組織幾何学的障害の相互作用によって決定されます.
  • 細胞包装の幾何学は組織の興奮性と空間的活動伝播を根本的に影響する.

結論:

  • 細胞の力学と幾何学は,多細胞組織における脈動性の活動パターンの決定的要素である.
  • 理論的枠組みは,生物学的波とパルスの調節に関する洞察を提供します.
  • 発見は,組織レベルでの興奮性と信号ダイナミクスにおける細胞パッキングの重要性を強調しています.