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関連する概念動画

Overview of the Vascular System01:20

Overview of the Vascular System

2.7K
The vascular system comprises an extensive network of arteries, capillaries, and veins. The vascular system can be broadly divided into the blood and lymphatic systems. Typically, blood vessels can be categorized into three histological regions: tunica intima, tunica media, and tunica adventitia. The tunica intima consists of a single layer of endothelial cells attached to the basal lamina. Underlying the basal lamina is a connective tissue layer and an elastic lamina that gives stability and...
2.7K
Mechanism of Angiogenesis01:10

Mechanism of Angiogenesis

5.4K
Blood vessel formation starts early during embryonic development, around day 7. In the extraembryonic yolk sac, mesodermal precursor cells called hemangioblast proliferate and differentiate into angioblast. Angioblasts express vascular endothelial growth factor receptor 2 or VEGFR2, which binds VEGF-A, a proangiogenic factor, guiding blood vessel formation. VEGF signaling promotes angioblasts to form a blood island in the developing embryo. Angioblasts further differentiate, giving rise to...
5.4K
Development of Blood Vessels01:07

Development of Blood Vessels

549
The development of the vascular system in a fetus is a complex and intricate process that begins as early as 15 to 16 days post-conception. This process starts outside the embryo, specifically in the mesoderm of the yolk sac, chorion, and connecting stalk. Approximately two days later, the formation of blood vessels occurs within the embryo itself.
The initial formation of this system is facilitated by the small amount of yolk present in the ovum and yolk sac. Blood vessels originate from...
549
Phylogenetic Trees03:21

Phylogenetic Trees

45.3K
Phylogenetic trees come in many forms. It matters in which sequence the organisms are arranged from the bottom to the top of the tree, but the branches can rotate at their nodes without altering the information. The lines connecting individual nodes can be straight, angled, or even curved.
45.3K
Xylem and Transpiration-driven Transport of Resources02:03

Xylem and Transpiration-driven Transport of Resources

23.5K
The xylem of vascular plants distributes water and dissolved minerals that are taken up by the roots to the rest of the plant. The cells that transport xylem sap are dead upon maturity, and the movement of xylem sap is a passive process.
23.5K
Regulation of Angiogenesis and Blood Supply01:24

Regulation of Angiogenesis and Blood Supply

2.5K
Rapidly dividing tumors, embryos, and wounded tissues require more oxygen than usual, lowering the oxygen concentration in the blood. At low oxygen or hypoxic conditions, an oxygen-sensitive transcription factor called the hypoxia-inducible factor 1 or HIF1 is activated. HIF1 is a dimeric protein of alpha (ɑ) and beta (β) subunits.  Under optimal oxygen conditions, HIF1β is present in the nucleus while HIF1ɑ remains in the cytosol. HIF1ɑ is hydroxylated by prolyl...
2.5K

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関連する実験動画

Updated: Jun 15, 2025

Using High Resolution Computed Tomography to Visualize the Three Dimensional Structure and Function of Plant Vasculature
11:49

Using High Resolution Computed Tomography to Visualize the Three Dimensional Structure and Function of Plant Vasculature

Published on: April 5, 2013

21.0K

血管樹を高速で合成する

Yan Yan Shery Huang1,2, Lining Arnold Ju3,4

  • 1Department of Engineering, University of Cambridge, Cambridge, UK.

Science (New York, N.Y.)
|June 12, 2025
PubMed
まとめ

新しい計算アルゴリズムは 複雑な人工血管ネットワークを 素早く作り出すことができます このバイオコンピューティングの突破は 研究開発のための複雑な生物学的構造の設計を加速します

科学分野:

  • バイオコンピューティング
  • コンピュータ生物学
  • バイオエンジニアリング

背景:

  • 人工血管構造は 組織工学と再生医療に不可欠です
  • これらの構造を設計する現在の方法は 時間がかかり 複雑である可能性があります

研究 の 目的:

  • 人工血管構造をレンダリングするための新しい計算アルゴリズムの開発と評価.
  • 新しいアルゴリズムで達成可能なスピードと複雑さを評価する.

主な方法:

  • 特殊な計算アルゴリズムの開発
  • アルゴリズムを使って 複雑な人工血管ネットワークを作ります
  • レンダリング時間と構造的複雑性の分析

主要な成果:

  • 計算アルゴリズムは 複雑な人工血管構造を成功裏に表現しました
  • レンダリングは数分で完了した.
  • このアルゴリズムは 複雑なデザインを生み出すのに 高い信頼性を示しました

結論:

  • 複雑な人工血管構造を設計するのに必要な時間を大幅に短縮します

さらに関連する動画

Author Spotlight: Improving Reproducibility in Vascular Organoids Using ROCK Inhibitors and Microwell Confinement
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Author Spotlight: Improving Reproducibility in Vascular Organoids Using ROCK Inhibitors and Microwell Confinement

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Stepwise Cell Seeding on Tessellated Scaffolds to Study Sprouting Blood Vessels
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Stepwise Cell Seeding on Tessellated Scaffolds to Study Sprouting Blood Vessels

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関連する実験動画

Last Updated: Jun 15, 2025

Using High Resolution Computed Tomography to Visualize the Three Dimensional Structure and Function of Plant Vasculature
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Using High Resolution Computed Tomography to Visualize the Three Dimensional Structure and Function of Plant Vasculature

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Author Spotlight: Improving Reproducibility in Vascular Organoids Using ROCK Inhibitors and Microwell Confinement
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Author Spotlight: Improving Reproducibility in Vascular Organoids Using ROCK Inhibitors and Microwell Confinement

Published on: December 13, 2024

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Stepwise Cell Seeding on Tessellated Scaffolds to Study Sprouting Blood Vessels
07:49

Stepwise Cell Seeding on Tessellated Scaffolds to Study Sprouting Blood Vessels

Published on: January 14, 2021

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  • この進歩は 組織工学や関連分野の研究を加速させる可能性を秘めています