CN114699566A - Preparation method of absorbable ligation clip - Google Patents

Abstract

The absorbable ligature clamp consists of one flexible inner layer and one strong and tough outer layer of integral injection structure of triblock copolymer of lactide, glycolide and polyglycol. The flexible inner layer copolymer material comprises, by weight, 40-70% of lactide, 10-50% of glycolide and 10-30% of polyethylene glycol, and the high-hardness and high-toughness outer layer copolymer material comprises, by weight, 50-90% of lactide, 10-50% of glycolide and 0-10% of polyethylene glycol. The triblock copolymer of lactide, glycolide and polyethylene glycol has a Ubbelohde viscosity of 1.0-5.0. In the copolymer, lactide is used as a substrate material, glycolide contains hydrophilic groups to provide good hydrophilicity for the copolymer, the polyethylene glycol block can provide hydrophilicity and flexibility for the copolymer, and the complete degradation time of the absorbable ligature clamp is less than 12 weeks.

Description

Preparation method of absorbable ligature clamp

Technical Field

The invention relates to a preparation method of an absorbable ligation clip for clamping and closing blood vessels or tissues, belonging to the field of medical instruments.

Background

At present, in surgical operation, a metal clip or a clip made of non-absorbable material is often adopted for ligating tubular tissues in a human body, so as to play a role in stopping bleeding or sealing. Metal clips, such as titanium clips, are not degraded and absorbed by human bodies, are retained in the bodies for a long time, and can stimulate tissues to generate inflammation; meanwhile, the metal clip can be developed in the X-ray examination, which causes misjudgment of doctors. The clip made of non-absorbable polymer material does not affect the examination of X-rays, but is not absorbed in the human body, and causes stimulation to tissues. Absorbable hemostatic ligating clips have appeared in the 80's of the 20 th century. Compared with metal clips and non-absorbable polymer clips, the absorbable clips have the advantages that the absorbable clips can be absorbed by human bodies within a certain time range, long-term foreign body stimulation on human body tissues is avoided, complications are few, the X-ray examination is not influenced, and the like.

The absorbable ligature clamps on the market at present are mainly divided into two types according to the structure, one type is an integral closed clamp, for example, the absorbable clamps produced by the American medical apparatus and instruments limited and the Nakout technologies limited in Sichuan are single-layer absorbable blood vessel ligature clamps, the adopted materials are high molecular weight poly (p-dioxanone), the structure is V-shaped, and the locking hook is arranged at the locking part. The integrated clamp has the advantages of single structure, simple injection molding and processing and strong clamping force; the defect is that the integrated clamp is difficult to simultaneously realize the dual requirements of softness without damaging tissues and high rigidity and clamping and closing force; one is a double layer clip with a relatively soft inner layer of low molecular weight polydioxanone material and a more rigid outer layer of polyglycolide, such as an absorbable clip manufactured by Korea medical and Hangzhou san Stone technologies, Inc. The double-layer clamp can realize the advantage that the inner layer is softer and has little damage to tissues, but the V-shaped design and the clamping and closing force are not as same as those of an integral clamp, and the injection molding and the assembly are more complicated. In addition, when the vascular clamp is used for closing blood vessels or tissues in a body, the self-healing time of the blood vessels or the tissues is generally 2-3 weeks, so that the ideal ligation clamp can be rapidly degraded in the body after better mechanical properties are kept within 2-3 weeks. However, the degradation time of the absorbable ligature clamp is more than 180 days after the absorbable ligature clamp is implanted into a body.

The invention patent No. CN201210556673.6, which is an invention of modifying a high molecular copolymer, endows an injection molding material with a balance point of flexibility and clamping force, but the flexibility and the clamping force are opposite, and certain clamping force is inevitably sacrificed when the flexibility is improved. The invention patent No. 201711155807.2 discloses a method for preparing reinforced absorbable ligature clamp, which adds nano-short fiber on the base material of ligature clamp to provide rigidity and clamping force of ligature clamp, but sacrifices flexibility and may damage the clamped blood vessel or tissue.

Disclosure of Invention

The invention aims to provide an integrated double-layer absorbable ligation clip which is strong in clipping force, small in damage to blood vessels or tissues and fast in degradation and absorption in vivo.

The invention is realized by adopting the following technical scheme:

a preparation method of an absorbable ligature clamp comprises a flexible inner layer (figure 2) and a strong and tough outer layer (figure 1), wherein the inner layer and the outer layer are of an integral injection molding structure, and injection molding materials of the inner layer and the outer layer are triblock copolymers of lactide, glycolide and polyethylene glycol. The flexible inner layer copolymer material comprises, by weight, 40-70% of lactide, 10-50% of glycolide and 10-30% of polyethylene glycol, and the high-hardness and high-toughness outer layer copolymer material comprises, by weight, 50-90% of lactide, 10-50% of glycolide and 0-10% of polyethylene glycol. The triblock copolymer of lactide, glycolide and polyethylene glycol has a Ubbelohde viscosity of 1.0-5.0. In the copolymer, lactide is used as a substrate material, glycolide contains hydrophilic groups to provide good hydrophilicity for the copolymer, the polyethylene glycol block can provide hydrophilicity and flexibility for the copolymer, and the complete degradation time of the absorbable ligature clamp is less than 12 weeks; the high-hardness and high-toughness outer layer of the ligation clip can provide higher clamping force for the ligation clip, and the inner layer with certain flexibility is in direct contact with blood vessels or tissues, so that the injury to the blood vessels or the tissues during clamping is avoided. The absorbable ligature clamp has the advantages of good biocompatibility, controllable degradation time, good clamping performance, small damage to blood vessels or tissues and the like.

Preferably, the triblock copolymer of lactide, glycolide and polyethylene glycol with high hardness and high toughness has a Ubbelohde viscosity of 3.0-5.0;

preferably, in the triblock copolymer of lactide, glycolide and polyethylene glycol with high hardness and high toughness, the proportion of lactide is 60-80%, the proportion of glycolide is 20-25% and the proportion of polyethylene glycol is 0-5%;

more preferably, in the triblock copolymer of lactide, glycolide and polyethylene glycol with high hardness and high toughness, the molecular weight of the polyethylene glycol is 10000-20000;

preferably, the triblock copolymer of lactide, glycolide and polyethylene glycol with the flexibility characteristic has a Ubbelohde viscosity of 1.0-3.0;

preferably, in the triblock copolymer of lactide, glycolide and polyethylene glycol with the flexibility characteristic, the proportion of lactide is 40-60%, the proportion of glycolide is 10-50% and the proportion of polyethylene glycol is 20-30%;

further preferably, in the triblock copolymer of lactide, glycolide and polyethylene glycol with flexibility, the molecular weight of polyethylene glycol is 2000-10000;

preferably, when the triblock copolymer of lactide, glycolide and polyethylene glycol is subjected to twin-screw extrusion granulation, the extrusion temperature of the high-hardness and high-toughness triblock copolymer is 170-180 ℃;

preferably, when the triblock copolymer of lactide, glycolide and polyethylene glycol is subjected to twin-screw extrusion granulation, the extrusion temperature of the flexible triblock copolymer is 150-160 ℃;

preferably, when the triblock copolymer of lactide, glycolide and polyethylene glycol is subjected to injection molding by a double-color injection molding machine, the three-section injection molding temperature of high-hardness and high-toughness triblock copolymer granules is 185-190 ℃, 180-185 ℃ and 175-180 ℃; the three-section injection molding temperature of the flexible triblock copolymer is 170-175 ℃, 165-170 ℃ and 160-165 ℃ respectively;

compared with the prior art, the invention endows the absorbable ligature clamp with different product characteristics of the inner layer and the outer layer through the integrated injection molding technology of the double-color injection molding machine. The inner layer is a flexible triblock copolymer, and when the ligation clip clamps and closes a blood vessel or a tissue, the inner layer with certain flexibility can reduce the damage of the ligation clip to the blood vessel or the tissue; the outer layer of the ligating clip is made of a high-hardness high-toughness triblock copolymer, and the ligating clip can have a larger closing force when used for clamping blood vessels or tissues, so that the clamping effect on the blood vessels or the tissues is improved, and the ligating clip is prevented from shifting or falling off. And the three-block copolymer base materials with the two characteristics are the same, and the combination is firm during injection molding. In addition, glycolide and polyethylene glycol in the inner-layer triblock copolymer and the outer-layer triblock copolymer are hydrophilic blocks and contain a large number of hydrophilic groups, so that the rapid degradation of the ligation clip can be accelerated. Through an in vitro simulation degradation test and a rabbit implantation test, the absorbable ligature clamp can maintain the mechanical clamping force required for clamping and closing blood vessels or tissues within 4 weeks; the complete degradation time in vivo is less than 12 weeks.

The absorbable ligature clamp disclosed by the invention has the advantages of good biocompatibility, controllable degradation time, good clamping performance, small damage to blood vessels or tissues and the like.

Description of the drawings:

FIG. 1 is a schematic view of an absorbable ligature clip;

fig. 2 is a schematic view of an absorbable ligature clip.

Detailed description of the invention

Firstly, preparing high-hardness and high-toughness copolymer

Weighing 72% of lactide, 25% of glycolide and 3% of polyethylene glycol in mass ratio, adding the weighed materials into a three-mouth reaction bottle, and adding a stannous octoate catalyst, wherein the mass ratio of the catalyst is 0.03%. Connecting one end of a three-mouth reaction bottle with a vacuum pump, connecting one end of the three-mouth reaction bottle with a nitrogen bottle, heating to 60 ℃, repeatedly vacuumizing and filling nitrogen for circulation to remove air and moisture in the reaction bottle, then sealing the reaction bottle under vacuum, reacting for 8 hours at 160 ℃ to obtain triblock copolymer coarse bodies of lactide, glycolide and polyethylene glycol, dissolving the triblock copolymer in acetone, repeatedly precipitating and purifying by using ethanol, and drying to obtain the purified high-hardness high-toughness copolymer. And (3) dissolving the copolymer in trichloromethane, and testing the viscosity of the copolymer by using an Ubbelohde viscometer, wherein the preferred viscosity of the copolymer is within 3.5-4.0.

② preparing copolymer with certain flexibility

Weighing 45% of lactide, 30% of glycolide and 600025% of polyethylene glycol in mass ratio, adding the weighed materials into a three-mouth reaction bottle, and adding a stannous octoate catalyst, wherein the mass ratio of the catalyst is 0.03%. Connecting one end of a three-mouth reaction bottle with a vacuum pump, connecting one end of the three-mouth reaction bottle with a nitrogen bottle, heating to 60 ℃, repeatedly vacuumizing and filling nitrogen for circulation to remove air and moisture in the reaction bottle, then sealing the reaction bottle under vacuum, reacting for 8 hours at 150 ℃ to obtain triblock copolymer coarse bodies of lactide, glycolide and polyethylene glycol, dissolving the triblock copolymer in acetone, repeatedly precipitating and purifying by using ethanol, and drying to obtain the purified high-hardness high-toughness copolymer. And (3) dissolving the copolymer in trichloromethane, and testing the viscosity of the copolymer by using an Ubbelohde viscometer, wherein the preferred viscosity of the copolymer is within 1.5-2.0.

And (3) hardness testing: the two copolymers were separately melt-tabletted and the hardness was measured with a Vickers hardness tester.

High hardness, high toughness triblock copolymer hardness: 95.4HV

Hardness of triblock copolymer of certain flexibility: 58.5HV

Processing of injection moulding granular material

And respectively putting the high-hardness high-toughness triblock copolymer and a triblock copolymer with certain flexibility into a double-screw extruder, and carrying out melt extrusion and shearing granulation to obtain the injection molding granules.

The extrusion temperature of the high-hardness high-toughness triblock copolymer is set to be 175 ℃;

the flexible triblock copolymer extrusion temperature was set at 155 ℃;

four two-color injection molding

A reasonably designed double-color injection mold is selected, a corresponding double-color injection molding machine is selected, the two copolymer granules are respectively added into a hopper of the double-color injection molding machine, and appropriate injection molding parameters are selected for injection molding.

The main injection molding parameters are as follows:

performance test

Example 2

Preparing a high-hardness high-toughness copolymer: the mass ratio of lactide to glycolide is 70 percent, the mass ratio of glycolide is 25 percent, and the mass ratio of polyethylene glycol is 5 percent

Preparing a copolymer with certain flexibility: weighing 40% of lactide, 30% of glycolide and 600030% of polyethylene glycol according to mass ratio

Processing of injection moulding granular material

And respectively putting the high-hardness high-toughness triblock copolymer and a triblock copolymer with certain flexibility into a double-screw extruder, and carrying out melt extrusion and shearing granulation to obtain the injection molding granules.

The extrusion temperature of the high-hardness and high-toughness triblock copolymer is set to be 170 ℃;

the flexible triblock copolymer extrusion temperature was set at 150 ℃;

four two-color injection molding

A reasonably designed double-color injection mold is selected, a corresponding double-color injection molding machine is selected, the two copolymer granules are respectively added into a hopper of the double-color injection molding machine, and proper injection molding parameters are selected for injection molding.

The main injection molding parameters are as follows:

the foregoing is illustrative of the principles of the present invention and it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. A preparation method of an absorbable ligature clamp is characterized in that: the absorbable ligature clamp consists of a flexible inner layer and a strong and tough outer layer, the inner layer and the outer layer are of an integral injection molding structure, injection molding materials of the inner layer and the outer layer are triblock copolymers of lactide, glycolide and polyethylene glycol, the flexible inner layer copolymer comprises 40-70% of lactide, 10-50% of glycolide and 10-30% of polyethylene glycol, the high-hardness and high-toughness outer layer copolymer comprises 50-90% of lactide, 10-50% of glycolide and 0-10% of polyethylene glycol, and the triblock copolymer of the lactide, the glycolide and the polyethylene glycol has a Ubbelohde viscosity of 1.0-5.0.

2. The method of claim 1, wherein the method comprises the steps of: : the absorbable ligature clip has a complete degradation time of less than 12 weeks.

3. The method of claim 1, wherein the absorbable ligature clip is prepared by: : the molecular weight range of the polyethylene glycol is 2000-20000.

4. The method of claim 1, wherein the absorbable ligature clip is prepared by: : the Vickers hardness range of the inner flexible layer of the absorbable ligation clip is 40-80 HV, and the Vickers hardness of the outer high-hardness and high-toughness layer is 80-200 HV.

5. The method of claim 1, wherein the absorbable ligature clip is prepared by: : the absorbable ligature clamp is formed by integrally injection molding two copolymers through a double-color injection molding machine.

6. The method of claim 1, wherein the absorbable ligature clip is prepared by: the triblock copolymer of lactide, glycolide and polyethylene glycol is prepared by the following method: weighing lactide, glycolide and polyethylene glycol in a certain proportion, adding the lactide, glycolide and polyethylene glycol into a three-mouth reaction bottle, adding an organic tin or zinc oxide catalyst, connecting one end of the three-mouth reaction bottle with a vacuum pump and the other end with a nitrogen bottle, heating to 60-70 ℃, repeatedly vacuumizing and filling nitrogen for circulation to remove air and moisture in the reaction bottle, sealing the reaction bottle under vacuum, reacting for 5-8 hours at 140-180 ℃, purifying and drying reactants to obtain the triblock copolymer of lactide, glycolide and polyethylene glycol,

and adding the triblock copolymer into a double-screw extruder for granulation, wherein the screw rotating speed is 50-70 r/min, and the extrusion temperature is 150-190 ℃.

7. The method of claim 1, wherein the absorbable ligature clip is prepared by: the integrated injection molding processing steps of the double-color injection molding machine are as follows: designing two pairs of molds, wherein one half of the two pairs of molds are arranged on a fixed mold fixing plate of a double-color mold injection molding machine, namely one side with an injection molding sprue, and the other half of the two pairs of molds are arranged on a movable mold rotary plate, namely one side ejected by the molds, adding high-hardness and high-toughness triblock copolymer granules and flexible triblock copolymer granules into a hopper of the double-color injection molding machine respectively, after the injection molding of the high-hardness and high-toughness triblock copolymer granules is finished, opening the fixed mold and the movable mold under the tension of the injection molding machine, rotating the movable mold 180 degrees, not ejecting the movable mold containing an injection molding product, closing the molds, performing the injection molding of the flexible triblock copolymer granules, after heat preservation and cooling, opening the fixed mold and the movable mold, ejecting the product at the side of the movable mold, namely preparing the absorbable ligature clamp, wherein the injection molding temperature is 150-190 ℃, and the injection pressure is 80-130 Bar.

8. An absorbable ligature clamp, comprising: the absorbable ligature clamp consists of a flexible inner layer (2) and a strong and tough outer layer (1), wherein the inner layer and the outer layer are of an integral injection molding structure.

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