CN113499471A

CN113499471A - Self-degradable medical aerogel particles and preparation process thereof

Info

Publication number: CN113499471A
Application number: CN202110574925.7A
Authority: CN
Inventors: 李伟; 谭建华; 张星
Original assignee: Shenzhen Tak Up Photoelectric Materials Co ltd
Current assignee: Shenzhen Tak Up Photoelectric Materials Co ltd
Priority date: 2021-05-26
Filing date: 2021-05-26
Publication date: 2021-10-15

Abstract

The invention discloses self-degradable medical aerogel particles and a preparation process thereof, belongs to the technical field of aerogels, and comprises aerogel particles, wherein the aerogel particles are polymer matrixes prepared from polyacrylamide, and the polymer matrixes comprise the following components in parts by weight: polyacrylamide, organic acid compound, additive, accelerant and solvent. According to the invention, during production, the moisture in the pores is subjected to sublimation drying through low-temperature freezing, so that the collapse of a pore structure due to rapid dehydration is avoided, the aerogel is integrally crushed and granulated in a frozen state through ultrasonic waves after being processed, the collapse of the aerogel structure is avoided from influencing the mixed use of the load, the application range of organic crosslinking in the medical aspect is improved through the non-toxicity of the water sample sodium, the wound can be coated through the mixed material with sodium alginate, and the use of the load in the aspects of drug delivery and controllable release is realized through multiple micropores.

Description

Self-degradable medical aerogel particles and preparation process thereof

Technical Field

The invention belongs to the technical field of aerogel, and particularly relates to self-degradable medical aerogel particles and a preparation process thereof.

Background

Aerogel is a kind of nano-porous solid material with three-dimensional network structure, and the pores and network structure of the solid matrix are filled with gas (usually air). Because of the excellent characteristics of large specific surface area, high porosity, low volume density, heat conductivity coefficient and the like, the aerogel has huge potential application in various fields such as heat insulation, catalysis, energy, adsorption, aerospace and the like. The aerogel is divided into inorganic aerogel and organic aerogel, compares in breakable inorganic aerogel, and organic aerogel has the better advantage of mechanical properties, the pliability.

Chinese patent document CN107531493B discloses an aerogel having as high and permanent hydrophobicity as possible and reduced flammability, and chinese patent document CN110903511A discloses a flexible flame retardant polyimide aerogel and a preparation method thereof, the polyimide aerogel preparation method is simple and convenient, the cost is low, the prepared aerogel has low density and high porosity, but the porous interface of the polyimide aerogel is not applicable to medical treatment, and the toxicity of the raw material phenols limits the applicable range of organic crosslinking, so that the effects of fine pore size and light weight of the aerogel are not applicable to medical treatment.

Disclosure of Invention

The invention aims to: the self-degradable medical aerogel particles and the preparation process are provided for solving the problems that the porous interface of the medical aerogel particles cannot be applied to the medical direction, the application range of organic crosslinking is limited by the toxicity of raw materials of phenols, and the fine pore size and light weight of the aerogel cannot be applied to the medical aspect.

In order to achieve the purpose, the invention adopts the following technical scheme:

self-degrading medical aerogel particles comprising aerogel particles, said aerogel particles being a polymer matrix prepared by polyacrylamide, said polymer matrix consisting of, by weight: polyacrylamide, organic acid compound, additive, accelerant and solvent.

As a further description of the above technical solution:

the organic acid compound is sodium salicylate, and the accelerant is citric acid gel.

As a further description of the above technical solution:

the additive is one or more of ethylene glycol, glycerol, polydactylene glycol, formamide and dimethylformamide.

As a further description of the above technical solution:

the solvent is ethanol, and the concentration of the ethanol is 80-95.

As a further description of the above technical solution:

the aerogel particles also comprise medical dressing mixed with the loaded filling particles, the loaded filling particles are sodium alginate, and the volume ratio of the loaded particles is 0.3.

As a further description of the above technical solution:

the preparation method of the medical dressing specifically comprises the following steps: s1, adding medical ethanol into the prepared aerogel particles and sodium alginate fibers, and placing the mixture into a mixer for centrifugal mixing to obtain the hemostatic dressing;

s2, after fully mixing, coating the mixed hemostatic dressing on the surface of the medical bandage, and then performing bandage dressing hemostasis.

A preparation process of self-degradable medical aerogel particles specifically comprises the following steps:

s1, preparing a precursor mixed solvent, namely adding polyacrylamide with a formula amount into deionized water with a required amount, adding sodium salicylate after fully dissolving and mixing, fully stirring and mixing to obtain the mixed solvent, and taking the sodium salicylate and the polyacrylamide as precursors;

s2, adding an additive into the mixed solvent after stirring and mixing, heating to a temperature of 45-60 ℃ which is convenient to control, performing magnetic stirring and mixing, after the additive is fully mixed and the surface of the additive does not flocculate, adding a gel accelerator with a formula amount into a mixing kettle through an additive pump, fully stirring and mixing the mixture in a stirring kettle to obtain a polymer aqueous solution, adding the polymer aqueous solution into a low-temperature sealing mould, adjusting the temperature of the sealing mould to be 45-60 ℃, and performing cyclic heating for 36-48h to obtain wet gel;

s3, replacing the solvent, namely, wholly adding the obtained wet gel and the mold into an autoclave, adding an exchange solvent into the mold, pressurizing and heating the autoclave for replacement, and partially replacing deionized water in pores after replacing for a certain time;

s4, cooling and drying in the environment, introducing a super-cooled liquid nitrogen solution into the high-pressure kettle, pressurizing at the same time, freezing and sublimating the residual refrigerating fluid in the pores, and freeze-drying for 3-15 hours;

and S5, granulating and packaging, taking out the prepared aerogel from the die, performing ultrasonic crushing granulation under the unfrozen state, filling the obtained aerogel into a packaging bag after granulation, and freezing for later use.

As a further description of the above technical solution:

the freezing temperature in the S4 is controlled to be-110 to-80 ℃.

As a further description of the above technical solution:

and the pressure of the high-pressure kettle in the S4 is 6.5-13 Mpa.

As a further description of the above technical solution:

and the packaging bag in the S5 is an aluminum foil heat insulation bag.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

in the invention, by adopting polyacrylamide and water-like sodium salt for mixing and using citric acid as a gel promoter, meanwhile, by adding alcohols or amide compounds, acid and alcohol are subjected to esterification reaction to form a high molecular polymer, expansion foaming is generated along with volatilization of ethanol, the process is favorable for forming porous and loose multiple holes, and simultaneously, the water in the pore space is sublimated and dried by low-temperature freezing during production, so that the collapse of the pore structure due to rapid dehydration is avoided, and the aerogel is integrally crushed and granulated in a frozen state by ultrasonic after being processed, so that the phenomenon that the collapse of the aerogel structure influences the load mixing use is avoided, the non-toxicity of the water-like sodium salt improves the application range of organic crosslinking in the aspect of medical treatment, and the wound can be coated by the mixed material of the water-like sodium salt and the sodium alginate, meanwhile, the microporous loading method can be used for drug delivery and controllable release.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

The embodiment provides a technical scheme: self-degrading medical aerogel particles comprising aerogel particles, said aerogel particles being a polymer matrix prepared by polyacrylamide, said polymer matrix consisting of, by weight: the preparation method comprises the following steps of preparing a medical dressing, wherein the medical dressing comprises polyacrylamide, an organic acid compound, an additive, an accelerant and a solvent, the organic acid compound is sodium salicylate, the accelerant is a citric acid gel, the additive is one or a composition of ethylene glycol, glycerol, polydactylene glycol, formamide and dimethylformamide, the solvent is ethanol, the concentration of the ethanol is 80-95, the aerogel particles further comprise the medical dressing mixed with loaded filling particles, the loaded filling particles are sodium alginate, and the volume ratio of the loaded particles is 0.3, and the preparation method of the medical dressing specifically comprises the following steps: adding medical ethanol into prepared aerogel particles and sodium alginate fibers, then placing the mixed materials into a mixer to centrifugally mix the materials to prepare the hemostatic dressing, S2, fully mixing the materials, coating the hemostatic dressing on the surface of a medical bandage with the mixed materials to perform bandage dressing hemostasis, and forming a high polymer through esterification reaction of citric acid, glycol, glycerol, polyvidone, formamide and dimethylformamide by using a citric acid gel, wherein the gel expands and foams along with volatilization of ethanol, so that a porous and loose porous aerogel is formed.

Example 2

Self-degrading medical aerogel particles comprising aerogel particles, said aerogel particles being a polymer matrix prepared by polyacrylamide, said polymer matrix consisting of, by weight: polyacrylamide, an organic acid compound, an additive, an accelerant and a solvent, wherein the organic acid compound is sodium salicylate, the accelerant is a citric acid gel, the additive is one or a composition of ethylene glycol, glycerol, polydactylene glycol, formamide and dimethylformamide, the solvent is ethanol, the concentration of the ethanol is 80-95, the aerogel particles further comprise a medical dressing mixed with loaded filling particles, the loaded filling particles are sodium alginate, the volume ratio of the loaded particles is 0.3, and the preparation process of the self-degradable medical aerogel particles specifically comprises the following steps: s1, preparing a precursor mixed solvent, namely adding polyacrylamide with a formula amount into deionized water with a required amount, adding sodium salicylate after fully dissolving and mixing, fully stirring and mixing to obtain the mixed solvent, and taking the sodium salicylate and the polyacrylamide as precursors; s2, adding an additive into the mixed solvent after stirring and mixing, heating to a temperature of 45-60 ℃ which is convenient to control, performing magnetic stirring and mixing, after the additive is fully mixed and the surface of the additive does not flocculate, adding a gel accelerator with a formula amount into a mixing kettle through an additive pump, fully stirring and mixing the mixture in a stirring kettle to obtain a polymer aqueous solution, adding the polymer aqueous solution into a low-temperature sealing mould, adjusting the temperature of the sealing mould to be 45-60 ℃, and performing cyclic heating for 36-48h to obtain wet gel; s3, replacing the solvent, namely, wholly adding the obtained wet gel and the mold into an autoclave, adding an exchange solvent into the mold, pressurizing and heating the autoclave for replacement, and partially replacing deionized water in pores after replacing for a certain time; s4, cooling and drying in the environment, introducing a super-cooled liquid nitrogen solution into the high-pressure kettle, pressurizing at the same time, freezing and sublimating the residual refrigerating fluid in the pores, and freeze-drying for 3-15 hours; s5, granulating and packaging, performing ultrasonic crushing and granulation on the prepared aerogel taken out of the die in an unfrozen packaged state, filling the obtained aerogel into a packaging bag after granulation, and freezing for later use, wherein the pressurization of the high-pressure kettle in the S4 is 6.5-13Mpa, the packaging bag in the S5 is an aluminum foil heat insulation bag, the influence of external temperature change on the shape of aerogel particles is avoided by selecting the aluminum foil heat insulation bag, and the preferred embodiment is to control the freezing temperature in the S4 to be-110 ℃.

Example 3

Self-degrading medical aerogel particles comprising aerogel particles, said aerogel particles being a polymer matrix prepared by polyacrylamide, said polymer matrix consisting of, by weight: polyacrylamide, an organic acid compound, an additive, an accelerant and a solvent, wherein the organic acid compound is sodium salicylate, the accelerant is a citric acid gel, the additive is one or a composition of ethylene glycol, glycerol, polydactylene glycol, formamide and dimethylformamide, the solvent is ethanol, the concentration of the ethanol is 80-95, the aerogel particles further comprise a medical dressing mixed with loaded filling particles, the loaded filling particles are sodium alginate, the volume ratio of the loaded particles is 0.3, and the preparation process of the self-degradable medical aerogel particles specifically comprises the following steps: s1, preparing a precursor mixed solvent, namely adding polyacrylamide with a formula amount into deionized water with a required amount, adding sodium salicylate after fully dissolving and mixing, fully stirring and mixing to obtain the mixed solvent, and taking the sodium salicylate and the polyacrylamide as precursors; s2, adding an additive into the mixed solvent after stirring and mixing, heating to a temperature of 45-60 ℃ which is convenient to control, performing magnetic stirring and mixing, after the additive is fully mixed and the surface of the additive does not flocculate, adding a gel accelerator with a formula amount into a mixing kettle through an additive pump, fully stirring and mixing the mixture in a stirring kettle to obtain a polymer aqueous solution, adding the polymer aqueous solution into a low-temperature sealing mould, adjusting the temperature of the sealing mould to be 45-60 ℃, and performing cyclic heating for 36-48h to obtain wet gel; s3, replacing the solvent, namely, wholly adding the obtained wet gel and the mold into an autoclave, adding an exchange solvent into the mold, pressurizing and heating the autoclave for replacement, and partially replacing deionized water in pores after replacing for a certain time; s4, cooling and drying in the environment, introducing a super-cooled liquid nitrogen solution into the high-pressure kettle, pressurizing at the same time, freezing and sublimating the residual refrigerating fluid in the pores, and freeze-drying for 3-15 hours; s5, granulating and packaging, performing ultrasonic crushing and granulation on the prepared aerogel taken out of the die in an unfrozen packaged state, filling the obtained aerogel into a packaging bag after granulation, and freezing for later use, wherein the pressurization of the high-pressure kettle in the S4 is 6.5-13Mpa, the packaging bag in the S5 is an aluminum foil heat insulation bag, the influence of external temperature change on the shape of aerogel particles is avoided by selecting the aluminum foil heat insulation bag, and the preferred embodiment is to control the freezing temperature in the S4 to be-80 ℃.

Example 4

Self-degrading medical aerogel particles comprising aerogel particles, said aerogel particles being a polymer matrix prepared by polyacrylamide, said polymer matrix consisting of, by weight: polyacrylamide, an organic acid compound, an additive, an accelerant and a solvent, wherein the organic acid compound is sodium salicylate, the accelerant is a citric acid gel, the additive is one or a composition of ethylene glycol, glycerol, polydactylene glycol, formamide and dimethylformamide, the solvent is ethanol, the concentration of the ethanol is 80-95, the aerogel particles further comprise a medical dressing mixed with loaded filling particles, the loaded filling particles are sodium alginate, the volume ratio of the loaded particles is 0.3, and the preparation process of the self-degradable medical aerogel particles specifically comprises the following steps: s1, preparing a precursor mixed solvent, namely adding polyacrylamide with a formula amount into deionized water with a required amount, adding sodium salicylate after fully dissolving and mixing, fully stirring and mixing to obtain the mixed solvent, and taking the sodium salicylate and the polyacrylamide as precursors; s2, adding an additive into the mixed solvent after stirring and mixing, heating to a temperature of 45-60 ℃ which is convenient to control, performing magnetic stirring and mixing, after the additive is fully mixed and the surface of the additive does not flocculate, adding a gel accelerator with a formula amount into a mixing kettle through an additive pump, fully stirring and mixing the mixture in a stirring kettle to obtain a polymer aqueous solution, adding the polymer aqueous solution into a low-temperature sealing mould, adjusting the temperature of the sealing mould to be 45-60 ℃, and performing cyclic heating for 36-48h to obtain wet gel; s3, replacing the solvent, namely, wholly adding the obtained wet gel and the mold into an autoclave, adding an exchange solvent into the mold, pressurizing and heating the autoclave for replacement, and partially replacing deionized water in pores after replacing for a certain time; s4, cooling and drying in the environment, introducing a super-cooled liquid nitrogen solution into the high-pressure kettle, pressurizing at the same time, freezing and sublimating the residual refrigerating fluid in the pores, and freeze-drying for 3-15 hours; s5, granulating and packaging, performing ultrasonic crushing and granulation on the prepared aerogel taken out of the die in an unfrozen packaged state, filling the obtained aerogel into a packaging bag after granulation, and freezing for later use, wherein the pressurization of the high-pressure kettle in the S4 is 6.5-13Mpa, the packaging bag in the S5 is an aluminum foil heat insulation bag, the influence of external temperature change on the shape of aerogel particles is avoided by selecting the aluminum foil heat insulation bag, and the preferred embodiment is to control the freezing temperature in the S4 to be-90 ℃.

Under the same process conditions, by controlling the freezing temperature during cooling and drying, the samples prepared in examples 2-4 were subjected to performance inspection by observing the surface pore size, and the data of commercially available silica aerogel was used as a comparative example, to obtain the data shown in Table 1,

as can be seen from the above table, in example 4, the freezing temperature is-90 ℃, and the collapse of the aerogel pores can be avoided during the freezing sublimation treatment, so as to ensure the uniform pore size of the whole aerogel, which is a preferred embodiment of the present invention.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. Self-degrading medical aerogel particles, comprising aerogel particles, wherein said aerogel particles are a polymer matrix prepared from polyacrylamide, and wherein said polymer matrix consists of the following components in parts by weight: polyacrylamide, organic acid compound, additive, accelerant and solvent.

2. The self-degrading medical aerogel particles of claim 2, wherein the organic acid compound is sodium salicylate and the accelerator is citric acid gelling agent.

3. The self-degrading medical aerogel particles of claim 1, wherein the additive is one or more of ethylene glycol, glycerol, polydactylene glycol, formamide, and dimethylformamide.

4. The self-degrading medical aerogel particles of claim 1, wherein the solvent is ethanol, and the concentration of ethanol is 80-95.

5. The self-degrading medical aerogel particles of any of claims 1-4, wherein the aerogel particles further comprise a medical dressing mixed with loaded packing particles, and the loaded packing particles are sodium alginate, and the loaded particle volume ratio is 0.3.

6. The self-degrading medical aerogel particles according to claim 5, wherein the method for preparing the medical dressing specifically comprises the following steps: s1, adding medical ethanol into the prepared aerogel particles and sodium alginate fibers, and placing the mixture into a mixer for centrifugal mixing to obtain the hemostatic dressing;

7. The process for the preparation of self-degrading medical aerogel particles according to any of claims 1 to 4, comprising in particular the following steps:

s2, adding an additive into the mixed solvent after stirring and mixing, heating to a controlled temperature, mixing, adding a gel accelerator after uniformly mixing, placing into a stirring kettle, fully stirring and mixing to obtain a polymer aqueous solution, adding into a low-temperature sealed mold, adjusting the temperature of the sealed mold to be 45-60 ℃, and circularly heating for 36-48h to obtain wet gel;

8. The process for preparing self-degradable medical aerogel particles according to claim 7, wherein the freezing temperature in S4 is controlled to be-110 to-80 ℃.

9. The process for preparing self-degradable medical aerogel particles according to claim 7, wherein the autoclave pressure in S4 is 6.5-13 MPa.

10. The process for preparing self-degradable medical aerogel particles according to claim 7, wherein the packaging bag in S5 is an aluminum foil heat insulation bag.