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Protein Networks02:26

Protein Networks

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An organism can have thousands of different proteins, and these proteins must cooperate to ensure the health of an organism. Proteins bind to other proteins and form complexes to carry out their functions. Many proteins interact with multiple other proteins creating a complex network of protein interactions.
These interactions can be represented through maps depicting protein-protein interaction networks, represented as nodes and edges. Nodes are circles that are representative of a protein,...
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Protein Networks02:26

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Network Covalent Solids02:18

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Network covalent solids contain a three-dimensional network of covalently bonded atoms as found in the crystal structures of nonmetals like diamond, graphite, silicon, and some covalent compounds, such as silicon dioxide (sand) and silicon carbide (carborundum, the abrasive on sandpaper). Many minerals have networks of covalent bonds.
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Olefin Metathesis Polymerization: Ring-Opening Metathesis Polymerization (ROMP)01:16

Olefin Metathesis Polymerization: Ring-Opening Metathesis Polymerization (ROMP)

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Ring-opening metathesis polymerization or ROMP involves strained cycloalkenes as starting materials. The mechanism of ROMP proceeds by reacting cycloalkene with Grubbs catalyst to give metallacyclobutane intermediate which undergoes a ring-opening reaction to form new carbene. The new carbene reacts with another molecule of cycloalkene. Repetition of these steps leads to the formation of an unsaturated open-chain polymer product. All these steps are reversible, however, relieving the ring...
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Actin Polymerization01:42

Actin Polymerization

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Actin polymerization occurs through the head-to-tail association of binding sites on monomeric actin or G-actin to form filamentous or F-actin. The polymerization can be divided into three phases ̶  nucleation, elongation, and steady-state phase.
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Step-Growth Polymerization: Overview01:03

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Step-growth or condensation polymerization is a stepwise reaction of bi or multifunctional monomers to form long-chain polymers. As all the monomers are reactive, most of the monomers are consumed at the early stages of the reaction to form small chains of reactive oligomers, which then combine to form long polymer chains in the late stages. Hence, the reaction has to proceed for a long time to achieve high molecular weight polymers.
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Related Experiment Video

Updated: Feb 10, 2026

Preparation of Chitosan-based Injectable Hydrogels and Its Application in 3D Cell Culture
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Preparation of Chitosan-based Injectable Hydrogels and Its Application in 3D Cell Culture

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Electroconductive 3D polymeric network production by using polyaniline/chitosan-based hydrogel.

Celil Ulutürk1, Neslihan Alemdar1

  • 1Marmara University, Department of Chemical Engineering, 34722, Istanbul, Turkey.

Carbohydrate Polymers
|May 19, 2018
PubMed
Summary
This summary is machine-generated.

Researchers developed a novel polyaniline/chitosan electroconductive hydrogel using photocrosslinking. The highest conductivity was achieved with a 0.32 M aniline concentration, showing promise for biosensor applications.

Keywords:
ChitosanElectroconductive hydrogelPhotocrosslinkingPolyaniline

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Area of Science:

  • Materials Science
  • Biomedical Engineering
  • Polymer Chemistry

Background:

  • Chitosan (CTS) is a biocompatible polymer with potential in biomedical applications.
  • Electroconductive hydrogels are desirable for advanced applications like biosensors.
  • Developing efficient methods for creating such hydrogels is crucial.

Purpose of the Study:

  • To synthesize and characterize a novel polyaniline/chitosan (PANI/CTS)-based electroconductive hydrogel.
  • To investigate the effect of aniline concentration on the hydrogel's conductivity.
  • To evaluate the potential of the fabricated hydrogel for biomedical applications, particularly biosensors.

Main Methods:

  • Grafting glycidyl methacrylate (GMA) onto chitosan (CTS) to form CTS-g-GMA.
  • Photocrosslinking CTS-g-GMA with poly(ethylene glycol)diacrylate (PEGDA) to create a 3D network.
  • Infiltrating the network with aniline solutions of varying concentrations (0.08, 0.16, 0.32 M) to form the electroconductive semi-interpenetrating network.
  • Characterization using FT-IR, XRD, SEM, TGA, and cytotoxicity tests.
  • Measuring electrical conductivity via the four-point probe technique.

Main Results:

  • A novel electroconductive hydrogel [(CTS-g-GMA)-PEGDA]-PANI was successfully fabricated.
  • The hydrogel with the highest aniline concentration (0.32 M) exhibited the highest conductivity (7437 × 10⁻³ S/cm).
  • Characterization confirmed the successful formation and structure of the PANI/CTS-based hydrogel.

Conclusions:

  • The fabricated polyaniline/chitosan electroconductive hydrogel demonstrates excellent conductivity.
  • The material shows significant potential for future biomedical applications, especially in the development of biosensors.
  • The photocrosslinking method provides an effective route for creating advanced electroconductive hydrogels.