WO2023016142A1

WO2023016142A1 - Noctilucent energy-storing and long-acting photodynamic antibacterial fabric and preparation method therefor

Info

Publication number: WO2023016142A1
Application number: PCT/CN2022/103821
Authority: WO
Inventors: 王清清; 张嘉雯; 张欣欣; 刘兴谱; 魏取福
Original assignee: 江南大学
Priority date: 2021-08-09
Filing date: 2022-07-05
Publication date: 2023-02-16
Also published as: CN113787786A; CN113787786B

Abstract

Disclosed in the present invention is a noctilucent energy-storing and long-acting photodynamic antibacterial fabric, which is obtained by sequentially coating the surface of a functional fabric with a noctilucent coating and a photosensitizer coating. A noctilucent powder is used as a material for storing solar energy. The noctilucent powder is coated on a textile by means of blade coating, so as to absorb and store ultraviolet light and visible light from sunlight; after a light source is cut off, the stored energy is released in the form of fluorescence; and the emitted fluorescence is absorbed by a photosensitizer, such that the antibacterial effect is enhanced under illumination, reactive oxygen substances are continuously generated in a darkroom in an aerobic environment, and the aim of a synergistic antibacterial effect is achieved. The upper layer and lower layer of a non-woven cloth are combined by means of pattern embossing, such that good breathability and hygroscopicity are achieved. In the present invention, since the base material is a common non-woven fabric, the non-woven fabric can be applied to people's daily products, specifically outdoor products such as tents, and the antibacterial effect in a darkroom is achieved. In addition, the conspicuousness of outdoor products can be realized due to the color being changeable.

Description

A luminous energy storage long-lasting photodynamic antibacterial fabric and its preparation method

technical field

The invention belongs to the field of luminous antibacterial fabrics, in particular to a luminous energy storage long-acting photodynamic antibacterial fabric and a preparation method thereof.

Background technique

As we all know, microorganisms, especially bacteria and molds, are very easy to multiply on various fabrics. Among them, various outdoor products are often used in the wild, and it is very easy to breed bacteria. In addition to causing diseases to the human body, the infection of microorganisms can also cause diseases such as stench, Mildew, deterioration and many other adverse consequences. With the further improvement of people's living standards and hygiene awareness, more and more young people and families choose to carry out activities in the wild when traveling. People's demand for various outdoor sports products has surged. While pursuing the beauty and comfort of the products, they have put forward higher requirements for their health care functions. The production of outdoor products such as tents with antibacterial functions is to protect people from or reduce them. One of the effective ways of bacterial invasion, so tents with antibacterial function are more and more popular, and have huge development potential and application market.

The method of directly coating and reinforcing the surface of the fabric with antibacterial agents is often used in the market to make the fabric have an antibacterial effect, and there are many kinds of antibacterial agents. Antibacterial materials are usually metal ions, antibiotics, etc. However, metal ions have certain toxic and side effects on the human body, and the extensive use of antibiotics can easily lead to drug resistance of bacteria, and photodynamic antibacterial can solve the above problems well. It is efficient and fast, can be used locally, and is not easy to produce drug resistance, etc. The advantages. However, a necessary condition for photosensitive antibacterial agents is light. When the light source is cut off, the photosensitizer cannot produce reactive oxygen species (ROS), which makes the antibacterial performance of light-driven antibacterial materials worse, making it unable to function in darkrooms, and the application scenarios are limited. .

Contents of the invention

Technical problem: Aiming at the deficiencies of the existing technology, the present invention provides a luminous energy storage long-lasting photodynamic antibacterial fabric and its preparation method, which solves the problem of easy breeding and reproduction of microorganisms on the surface of the fabric fabric, and the common problem of fabrics loaded with photosensitive antibacterial agents in darkrooms. Difficult to produce technical problems of antimicrobial effect in the environment.

Technical solutions:

The invention provides a luminous energy storage long-lasting photodynamic antibacterial fabric, which is characterized in that it includes a woven cotton or non-woven fabric substrate, and the substrate is coated with luminous powder/photosensitizer to form luminous The antibacterial substrate, the luminous powder is rare earth strontium aluminate luminous powder, and the photosensitizer is rose bengal photosensitizer.

The woven cotton base material is made of natural cotton fiber, and the cotton thread is woven through weaving technology; the non-woven fabric base material is polypropylene, and the fiber formed by high-temperature melt spinning is used as the raw material. Under the clamping and traction of high-speed hot air flow, it is stretched, thinned and sprayed, and self-adhesive with residual heat to form a network structure fiber aggregate.

Wherein, the microporous structure of the woven cotton base material and the fiber diameter of the non-woven fabric base material are 2-5 μm and the arrangement is disorderly and disorderly, having a three-dimensional microporous structure.

The present invention also provides a method for preparing a luminous energy storage long-lasting photodynamic antibacterial fabric, which includes weaving woven cotton or non-woven fabric substrates, preparing luminous powder/photosensitizer coatings, and forming interlayer structures. Proceed as follows:

(1) Weaving of woven cotton cloth or non-woven fabric substrate: use woven/melt-blown method to manufacture cotton cloth or non-woven fabric;

(2) Preparation of luminous powder/photosensitizer coating:

(2.1) Preliminary treatment of the coating: Cut the cotton cloth or non-woven fabric into a square cloth with a size of 20cm×15cm, 20cm is the warp direction, 15cm is the weft direction, the thickness of the fabric is 0.16m; the luminous powder content is 75%; the beaker After adding 15g of luminous powder and 5g of transparent nylon glue, add 4mL of deionized water with a pipette gun, and stir with a glass rod until it is evenly observed with the naked eye;

(2.2) Scrape-coat the mixture treated in step (2.1) onto a woven cotton or non-woven fabric substrate by screen printing, and put it in an oven at 130°C for 3 minutes to dry;

(2.3) After adding 6g of PVA-SbQ to the beaker, measure 60mL of deionized water with a graduated cylinder, stir with a glass rod until the PVA-SbQ is fully dissolved in water, weigh 0.06g of Rose Bengal and add it to the solution, stir evenly, and let it stand Precipitate for 5 minutes, take all the evenly dispersed Rose Bengal solution in the upper layer and add it to the container, soak the woven cotton cloth or non-woven fabric substrate treated in step (2.2) for 10 minutes, take it out, and put the side without luminous coating close to the aluminum foil paper , put it in a 60°C oven and bake until the luminous powder coating surface is dry, then take it out and turn it over, and then bake it until the whole piece of fabric is dry and then take it out;

(2.4) irradiating the coated fabric substrate with ultraviolet light for 2 hours to cross-link the coating and the fabric for reinforcement, and obtain a treated luminous antibacterial substrate;

(3) Formation of sandwich structure: the woven cotton cloth or non-woven fabric base material obtained in step (2), and another layer of woven cotton cloth or non-woven fabric base material without any treatment through the embossing process with a needlework pattern The method is to sew the two substrates together, and the side containing the luminous layer is in the middle of the two substrates to form a sandwich structure.

Beneficial effect:

(1) The fabric of the present invention is mainly produced from woven cotton or non-woven fabric base material, which has the characteristics of soft hand feeling and high comfort. However, the hygroscopicity of the fabric is high, and the microporous structure provides a large number of attachment points for bacteria, which is conducive to bacterial reproduction. This situation can be effectively improved after loading;

(2) The present invention uses luminous powder as a material for storing light energy, and coats it on the fabric substrate by screen printing, absorbs ultraviolet light and visible light under light conditions, and stores light energy, and emits fluorescent light in the dark. The emitted fluorescence can be absorbed by the photosensitizer, so it can also play an antibacterial effect in the aerobic environment of the darkroom, and achieve the purpose of antibacterial around the clock;

(3) Due to the presence of the photosensitizer, the luminous energy storage long-acting photodynamic antibacterial fabric of the present invention has a good killing effect on Staphylococcus aureus under the conditions of light and dark room.

Description of drawings

Fig. 1 is the laser confocal scanning microscope figure of surface microstructure figure and section of the present invention;

Fig. 2 is the fluorescence emission and excitation spectrum of the rare earth strontium aluminate luminous powder SAOED of the present invention and the ultraviolet-visible light absorption spectrum of Bengal rose red RB;

Fig. 3 is that the present invention uses KI as a substrate to detect the singlet oxygen detection figure of Rose Bengal RB;

Fig. 4 is the effect diagram of the anti-staphylococcus aureus performance of the light-dark cycle photodynamic material of the present invention;

Fig. 5 is a graph showing the antibacterial properties of the present invention against Staphylococcus aureus under cyclic light-dark conditions (white irradiation and gray dark period irradiation).

Detailed ways

Embodiments of the present invention will be further clearly and detailedly described below in conjunction with the accompanying drawings of the present invention. What this embodiment relates to is only a part of the embodiments of the present invention, rather than all the embodiments.

The sample in this experiment is rare earth strontium aluminate luminous powder/Bengal rose red loaded woven cotton fabric, which is divided into three steps: the first step is to cut the plain weave cotton fabric with a specification of 80s 151×152 threads/inch into 20cm×15cm (20cm is the warp direction, 15cm is the weft direction) size square cloth, the fabric thickness is 0.16m. After adding 15g of luminous powder and 5g of transparent nylon glue into the beaker, add 4mL of deionized water with a pipette gun, and stir with a glass rod until it is evenly observed with the naked eye.

In the second step, the treated mixture is scraped-coated on a woven cotton or non-woven fabric substrate by screen printing, and dried in an oven at 130° C. for 3 minutes.

The third step is to add 6g of PVA-SbQ to the beaker and measure 60mL of deionized water (10% w/v PVA-SbQ/deionized water) with a measuring cylinder, stir with a glass rod until the PVA-SbQ is fully dissolved in water, and weigh Take 0.06g Rose Bengal (1%w/w Rose Bengal/PVA-SbQ) and add it to the solution, stir evenly, let it settle for 5min, take all the evenly dispersed Rose Bengal solution in the upper layer and add it to the container, and put the treated Soak the woven cotton cloth or non-woven fabric base material for 10 minutes, take it out, put the non-luminous coating side close to the aluminum foil paper, put it in a 60°C oven and dry until the luminous powder coating surface is dry, take it out and turn it over, and then bake it until the whole fabric Remove after drying. Finally, the coated fabric substrate was irradiated with ultraviolet light for 2 hours to make the coating and the fabric cross-linked and strengthened, and finally a photodynamic antibacterial fabric with luminous luminous powder as the background was prepared.

Fig. 1 is the laser confocal scanning electron microscope picture of the surface microstructure figure of the base material of the present invention and the section, wherein a is the scanning electron microscope picture of the surface topography of cotton yarn, b is the scanning electron microscope picture of the microcosmic topography of the base material surface, and c is the cross section Scanning electron micrograph of microscopic morphology; d is the laser confocal scanning microscope image of the cross-section of the luminous antibacterial fabric.

Fig. 2 is the fluorescence emission and excitation spectrum of the rare earth strontium aluminate luminous powder SAOED of the present invention and the ultraviolet-visible light absorption spectrum of Bengal Rose Red RB; for the rare earth strontium aluminate luminous powder SAOED, it has a typical excitation peak at about 368nm , the excitation spectrum covers ultraviolet light and visible light, which means that sunlight can excite luminous powder to store solar energy; about 512nm is the maximum emission wavelength of the photoluminescence spectrum of rare earth strontium aluminate luminous powder SAOED (excitation wavelength is 368nm); Bengal rose The ultraviolet-visible spectrum of red RB has a strong peak at around 540nm; the RB absorption spectrum overlaps with the SAOED emission spectrum in a large range, which provides a strong basis for the feasibility of luminous powder to supply energy to Bengal rose red.

Fig. 3 is a singlet oxygen detection diagram of the present invention using KI as a substrate to detect Rose Bengal. Sample 2 is the substrate containing only rare earth strontium aluminate luminous powder SAOED, which is the control group, sample 3 is the substrate containing both rare earth strontium aluminate luminous powder SAOED and Bengal rose red RB, and sample 4 is only containing Bengal rose red RB base material. Using KI as the substrate for the indirect detection of singlet oxygen, Rose Bengal produces singlet oxygen under light, which can oxidize KI, so that I ^- is oxidized to I ^3- , and an absorption peak appears around 352nm, and its absorbance increases with I ³ The concentration of ^- increased and gradually increased, and a 20-min light-dark fatigue cycle light radiation experiment was carried out on the relevant samples (lighting for 5 minutes, dark room for 15 minutes), as shown in the figure, sample 2 had no photooxidative effect. The singlet oxygen of samples 3 and 4 is mainly produced during the light period, while sample 4 does not produce ¹ O ₂ in the dark, and sample 3 can still produce a small amount of ¹ O ₂ in the dark (in the dark room, the absorbance of sample 3 at 365nm The curve shows an upward trend), which is a good proof that light is one of the necessary factors for the occurrence of antibacterial photodynamic inactivation: when the light source is cut off, the antibacterial photodynamic inactivation mechanism is suspended. Sample 4 in the dark room emits afterglow from luminous powder as a light source, which can continue the occurrence of antibacterial photodynamic inactivation. When the light source irradiated the sample again, the ROS production increased significantly without a significant decrease in activity. After four cycles, sample 3 showed stronger photooxidative activity than sample 4, which is mainly reflected in the absorbance of sample 3 at 365nm is about 2.36 times that of sample 4, indicating that under the energy of luminous powder, the photodynamic material The production of ¹ O ₂ is greatly increased, that is, the luminous powder has a synergistic effect on the production of ¹ O ₂ of Rose Bengal.

Figure 4. When testing the antibacterial effect of light-dark cycles on photodynamic materials, the bacterial solution and the material were contacted in the dark room for 40 minutes in advance, and then the subsequent antibacterial experiments were carried out. The results showed that after 20 minutes of light, the antibacterial rates of sample 3 and sample 4 were 93.3858% and 96.9767%, respectively. Compared with the samples without dark contact in the above experiment, the antibacterial rate increased by 0.72 logarithmic units and 0.98 logarithmic units, which once again verified that dark contact can improve the efficiency of photodynamic inactivation. After the first 40min in the dark room, it was found that sample 4 had bacterial reproduction, and the bacterial survival rate increased from 3.0232% to 4%, while sample 3 had no bacterial re-proliferation in the dark room. This phenomenon shows that for the growth of luminous powder For the effective Bengal rose red material, it has the function of inhibiting the reproduction of bacteria when the light source is cut off. After two light-dark cycles, sample 2 (no photosensitizer control group) has no antibacterial effect in light and dark room, sample 4 bacteriostatic rate is 99.9879%, sample 3 bacteriostatic rate reaches 99.9965% (increase 0.544 logarithm units), which is consistent with the above substrate oxidation and electron paramagnetic resonance spectroscopy results. All in all, this experiment proves that the luminous powder has a synergistic effect on the bactericidal effect of the photosensitizer.

Fig. 5 is a graph showing the antibacterial properties of the present invention against Staphylococcus aureus under cyclic light-dark conditions (white irradiation and gray dark period irradiation). It can be seen from the figure that the photosensitizer can destroy the structure of Staphylococcus aureus. After adding luminous powder, the structure of Staphylococcus aureus is destroyed more thoroughly. The above all prove that the rare earth strontium aluminate luminous powder and Bengal rose red have a synergistic effect antibacterial effect.

Claims

A luminous energy storage long-lasting photodynamic antibacterial fabric, characterized in that it includes a woven cotton or non-woven fabric substrate, and the substrate forms a luminous antibacterial substrate after the surface is coated with a luminous powder/photosensitizer coating, The luminous powder is a rare earth strontium aluminate luminous powder, and the photosensitizer is a Bengal rose red photosensitizer;

The woven cotton base material is made of natural cotton fiber, and the cotton thread is woven through weaving technology; the non-woven fabric base material is polypropylene, and the fiber formed by high-temperature melt spinning is used as the raw material. Under the clamping and traction of high-speed hot air flow, it is stretched, thinned and sprayed, and self-adhesive with residual heat to form a network structure fiber aggregate.
The luminous energy storage long-lasting photodynamic antibacterial fabric according to claim 1, characterized in that the microporous structure of the woven cotton substrate and the fiber diameter of the nonwoven substrate are 2-5 μm and the arrangement is disorderly, It has a three-dimensional microporous structure.
A preparation method of the luminous energy storage long-lasting photodynamic antibacterial fabric according to any one of claims 1-2, characterized in that it comprises weaving of woven cotton cloth or non-woven fabric substrate, luminous powder/photosensitizer coating The deployment of the layer and the formation of the sandwich structure are as follows:

(1) Weaving of woven cotton cloth or non-woven fabric substrate: use woven/melt-blown method to manufacture cotton cloth or non-woven fabric;

(2) Preparation of luminous powder/photosensitizer coating:

(2.1) Preliminary treatment of the coating: Cut the cotton cloth or non-woven fabric into a square cloth with a size of 20cm×15cm, 20cm is the warp direction, 15cm is the weft direction, the thickness of the fabric is 0.16m; the luminous powder content is 75%; the beaker After adding 15g of luminous powder and 5g of transparent nylon glue, add 4mL of deionized water with a pipette gun, and stir with a glass rod until it is evenly observed with the naked eye;

(2.2) Scrape-coat the mixture treated in step (2.1) onto a woven cotton or non-woven fabric substrate by screen printing, and put it in an oven at 130°C for 3 minutes to dry;

(2.3) After adding 6g of PVA-SbQ to the beaker, measure 60mL of deionized water with a graduated cylinder, stir with a glass rod until the PVA-SbQ is fully dissolved in water, weigh 0.06g of Rose Bengal and add it to the solution, stir evenly, and let it stand Precipitate for 5 minutes, take all the evenly dispersed Rose Bengal solution in the upper layer and add it to the container, soak the woven cotton cloth or non-woven fabric substrate treated in step (2.2) for 10 minutes, take it out, and put the side without luminous coating close to the aluminum foil paper , put it in a 60°C oven and bake until the luminous powder coating surface is dry, then take it out and turn it over, and then bake it until the whole piece of fabric is dry and then take it out;

(2.4) irradiating the coated fabric substrate with ultraviolet light for 2 hours to cross-link the coating and the fabric for reinforcement, and obtain a treated luminous antibacterial substrate;

(3) Formation of sandwich structure: the woven cotton cloth or non-woven fabric base material obtained in step (2), and another layer of woven cotton cloth or non-woven fabric base material without any treatment through the embossing process with a needlework pattern The method is to sew the two substrates together, and the side containing the luminous layer is in the middle of the two substrates to form a sandwich structure.