High-biocompatibility fiber
A biocompatible, fiber technology, applied in the field of highly biocompatible fibers, can solve the problems of poor biocompatibility, surgical failure, fibrous hyperplasia and adhesion, etc.
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Embodiment 1
[0061] Fabrication of Highly Biocompatible Fibers
[0062] (1) The fiber substrate was ultrasonically cleaned in distilled water and absolute ethanol for 10 minutes to remove oil and dust on the surface of the substrate, and then dried with nitrogen.
[0063] (2) place the dried fiber base material in a vacuum chamber, and evacuate so that the vacuum degree of the vacuum chamber reaches 3×10 -4 Pa, argon gas is introduced, and the partial pressure of argon gas is 0.5Pa.
[0064] Turn on the power, apply a power of 100w, generate plasma, and sputter the surface of the fiber substrate for 10 minutes to remove oxides on the surface of the substrate, thereby increasing the adhesion between the substrate and the coating. Heat the vacuum chamber to 400°C, and then pass the reaction gas TiCl into the vacuum chamber 4 , the air pressure is 1.0Pa, the coating time is 10 minutes, and it is released after cooling.
[0065] (3) Place the titanium-plated fiber substrate in a physical va...
Embodiment 2
[0067] Manufacture of nerve guides
[0068] (1) The nerve guide was ultrasonically cleaned in distilled water and absolute ethanol for 10 minutes to remove oil and dust on the surface of the nerve guide, and then blown dry with nitrogen.
[0069] (2) Place the dried nerve guide into a vacuum chamber, and evacuate so that the vacuum degree of the vacuum chamber reaches 5×10 -4 Pa, argon gas is introduced, and the partial pressure of argon gas is 0.8Pa.
[0070] Turn on the power supply, apply a power of 100w, generate plasma, and sputter the surface of the nerve guide for 10 minutes to remove oxides on the surface of the nerve guide, thereby increasing the adhesion between the nerve guide and the coating. Heat the vacuum chamber to 400°C, and then pass the reaction gas TiCl into the vacuum chamber 4 , the air pressure is 1.2Pa, the coating time is 15 minutes, and it is released after cooling.
[0071] (3) Place the titanium-plated nerve guide in the physical vapor deposition...
Embodiment 3
[0073] Manufacturing Surgical Meshes
[0074] (1) The fiber-woven surgical patch was ultrasonically cleaned in distilled water and absolute ethanol for 10 minutes to remove oil and dust on the surface of the surgical patch, and then dried.
[0075] (2) Place the dried surgical patch in a vacuum chamber and evacuate to make the vacuum of the vacuum chamber reach 6×10 -4 Pa, argon gas is introduced, and the partial pressure of argon gas is 1.0Pa.
[0076] Turn on the power, apply a power of 100w, generate plasma, and sputter the surface of the surgical patch for 10 minutes to remove oxides on the surface of the surgical patch, thereby increasing the adhesion between the surgical patch and the coating. Heat the vacuum chamber to 400°C, and then pass the reaction gas TiCl into the vacuum chamber 4 , the air pressure is 1.0Pa, the coating time is 10 minutes, and it is released after cooling.
[0077] (3) The titanium-plated surgical patch was placed in a physical vapor depositio...
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