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Coagulation01:06

Coagulation

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Colloidal solids are solid particles suspended in solution. They are usually negatively charged, attracting a compact primary layer of positively charged ions, which attract more counterions to form an electrical double layer. Electrostatic repulsion between the charged double layers prevents the particles from colliding, stabilizing the colloids. These solids are often undesirable because they can contain toxins that are difficult to remove. Coagulation is a technique that helps aggregate and...
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Coagulation01:09

Coagulation

8.4K
The coagulation phase is a critical part of the body's process to prevent blood loss following injury to blood vessels. It involves chemical reactions that form a clot to seal the injured area. The clotting process begins shortly after injury, within 15-20 seconds for severe damage and 1-2 minutes for minor injuries.
During the coagulation phase, clotting factors, or procoagulants, play a vital role in initiating and progressing the coagulation cascade. This cascade is a series of reactions...
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Related Experiment Video

Updated: May 3, 2026

Multimodal Optical Microscopy Methods Reveal Polyp Tissue Morphology and Structure in Caribbean Reef Building Corals
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Multimodal Optical Microscopy Methods Reveal Polyp Tissue Morphology and Structure in Caribbean Reef Building Corals

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Building like a Coral-Parallelized, Multiscale Biofabrication.

Asma Rehman1, Marta Peña Fernández2, Kristina K Beck3

  • 1Institute of Materials Science and Engineering, Clausthal University of Technology, Clausthal-Zellerfeld, Germany.

Advanced Materials (Deerfield Beach, Fla.)
|February 25, 2026
PubMed
Summary
This summary is machine-generated.

Corals build strong, sustainable skeletal materials in challenging environments, offering blueprints for advanced biomaterials and biofabrication. Understanding coral biomineralization can inspire energy-efficient, self-organizing manufacturing for engineering and biomedical applications.

Keywords:
aragonitebiomineralizationcalcificationcold‐water coralsscleractinian coralsstructural materialssustainable manufacturing

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Area of Science:

  • Marine Biology
  • Material Science
  • Biomineralization

Background:

  • Scleractinian corals create vital ecosystems and engineer remarkable skeletal materials.
  • Coral skeletons exhibit exceptional mechanical properties, biocompatibility, and sustainable synthesis, even in low-energy conditions.
  • Understanding coral biomineralization is key to unlocking innovative material science applications.

Purpose of the Study:

  • To synthesize current knowledge on coral biomineralization processes.
  • To explore the two main viewpoints: biologically controlled versus physicochemical controlled biomineralization.
  • To recast coral growth as a multiscale biofabrication process for next-generation materials.

Main Methods:

  • Literature review and synthesis of existing research on coral biomineralization.
  • Analysis of coral skeletal material properties and synthesis conditions.
  • Conceptual framework development for coral growth as biofabrication.

Main Results:

  • Coral biomineralization involves complex processes with ongoing debate between biological and physicochemical control.
  • Coral growth can be viewed as a multiscale, parallelized biofabrication process.
  • Sustainable, energy-efficient manufacturing principles can be derived from coral skeletal formation.

Conclusions:

  • Coral skeletal material science offers blueprints for transformative innovations in biomedical and engineering fields.
  • Insights into coral growth can drive the development of sustainable, self-organizing, and energy-efficient manufacturing.
  • The study provides pathways for developing next-generation materials inspired by nature, addressing the question: "How to build like a coral?"