CN113397996A - Antibacterial mouth wash and preparation method thereof - Google Patents

Antibacterial mouth wash and preparation method thereof Download PDF

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CN113397996A
CN113397996A CN202110837689.3A CN202110837689A CN113397996A CN 113397996 A CN113397996 A CN 113397996A CN 202110837689 A CN202110837689 A CN 202110837689A CN 113397996 A CN113397996 A CN 113397996A
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mouthwash
antibacterial
cyclodextrin
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李景果
李博华
石刘奇
栗占荣
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Henan Provincial Peoples Hospital
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    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
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    • A61K8/00Cosmetics or similar toiletry preparations
    • A61K8/18Cosmetics or similar toiletry preparations characterised by the composition
    • A61K8/30Cosmetics or similar toiletry preparations characterised by the composition containing organic compounds
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    • A61P31/04Antibacterial agents
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    • A61Q11/00Preparations for care of the teeth, of the oral cavity or of dentures; Dentifrices, e.g. toothpastes; Mouth rinses
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Abstract

The invention belongs to the technical field of polymer chemistry, biomedical materials and pharmacy, and discloses antibacterial mouth wash and a preparation method thereof. The mouthwash is prepared from the following raw materials in percentage by g/mL: 0.1-1% of mouthwash drug, 0.5-10% of polymer graft copolymer and the balance of water for injection; wherein the macromolecular graft polymer is chitosan-g- (cyclodextrin +3, 4-dihydroxyphenyl propionic acid). The invention obviously prolongs the effective time of the mouth wash acting in the oral cavity, reduces the concentration of the medicine and reduces the toxic and side effect caused by the medicine; the mouthwash of the invention has excellent effect of eradicating bacterial biofilm in vitro and shows excellent curative effect of first-line clinical medicines (minocycline and chlorhexidine) in vivo.

Description

Antibacterial mouth wash and preparation method thereof
Technical Field
The invention belongs to the technical field of polymer chemistry, biomedical materials and pharmacy, and particularly relates to antibacterial mouthwash and a preparation method thereof.
Background
Periodontitis (periodontitis) is a chronic infectious disease caused by bacteria, is a main reason for tooth loss of a patient, not only seriously affects the oral health of the patient, but also is a risk factor of various diseases of the whole body. The bacteria in the plaque biofilm are the initiating factors for periodontal disease. Due to the unique physiological and anatomical characteristics of the oral cavity, effective removal of plaque biofilm and reduction of bacterial adhesion and accumulation still present significant challenges. Many studies have now demonstrated that bacteria in biofilms are much less sensitive to antibacterial agents than when they are in a planktonic state, whereas oral bacteria often become pathogenic in the form of biofilms and are very resistant to many antibacterial agents, which has resulted in poor clinical results in laboratory drug sensitivity. And the oral biofilm can begin to adhere again after mechanical removal for 20 minutes and develop to maturity within two days. Therefore, the use of mouthwashes to further control plaque biofilm growth after oral basal treatment for periodontitis is critical to the prognosis of periodontitis. However, the available commercial antibacterial agents are few, and the action time of the drugs is greatly limited due to the influence of the continuous washing of saliva in the oral cavity and the eating, and the local drug concentration is difficult to maintain.
In recent years, biomaterials have been continually applied in drug delivery to overcome biofilm barriers and effectively eradicate biofilms. However, in the face of complicated oral environment, it is often difficult to ensure the drug action time, and higher drug concentration is required to achieve the bactericidal effect. During local administration, how to keep local drug concentration free from the influence of saliva washing and diet drinking water is a key factor for treating the whole disease. Frequent multiple administrations of high doses of mouthwash in order to achieve a pharmacotherapeutic effect often lead to serious side effects and compliance is difficult to guarantee. The existing clinical commonly used antibacterial mouth wash has high required drug concentration during treatment, short retention time and poor effect, and greatly reduces the compliance of patients.
Disclosure of Invention
In order to overcome the defects in the prior art, the invention aims to provide the antibacterial mouthwash capable of prolonging the detention time of the mouthwash, reducing the administration concentration and enhancing the antibacterial effect in vivo and the preparation method thereof.
In order to achieve the purpose, the technical scheme adopted by the invention is as follows:
an antibacterial mouth wash, which comprises the following raw materials in percentage by g/mL: 0.1-1% of mouthwash drug, 0.5-10% of polymer graft copolymer and the balance of water for injection; wherein the macromolecular graft polymer is chitosan-g- (cyclodextrin +3, 4-dihydroxyphenyl propionic acid).
Preferably, the mouthwash medicament is an antibacterial medicament.
Preferably, the antibacterial drug is minocycline.
Preferably, the graft ratio of cyclodextrin is 20-80% and the graft ratio of 3, 4-dihydroxyphenylpropionic acid is 1-15% in the polymer graft copolymer.
Preferably, the cyclodextrin is alpha-cyclodextrin, beta-cyclodextrin or gamma-cyclodextrin.
The preparation method of the antibacterial mouthwash comprises the following steps: firstly, weighing a high-molecular graft polymer, adding injection water with the formula amount, and stirring until the high-molecular graft polymer is completely dissolved; then weighing the mouthwash medicament, adding the mouthwash medicament into the solution, stirring and centrifuging; and (5) sucking the supernatant, dialyzing, and finally sterilizing to obtain the antibacterial mouth wash.
Chitosan-g- (cyclodextrin +3, 4-dihydroxyphenylpropionic acid) (CS-g- (CD + HCA) for short) can be prepared according to the prior art and comprises the following steps:
s1 Synthesis of CD-COOH (monocarboxylated cyclodextrin): sodium chloroacetate (ClCH) was added2COONa) in alkaline conditions, then adding hydrochloric acid (HCl) to adjust the pH value for acidification;
s2, synthesis of CS-g-CD: grafting monocarboxylated cyclodextrin onto chitosan main chain through amidation reaction in controlled reaction material ratio to synthesize chitosan-grafted-cyclodextrin (CS-g-CD) in different grafting rate;
s3 Synthesis of CS-g- (CD + HCA): 3, 4-dihydroxyphenyl propionic acid (HCA) is grafted to a main chain of CS-g-CD through amidation reaction by controlling the feed ratio of the reaction, and CS-g- (CD + HCA) with different grafting ratios is synthesized;
the detailed steps are as follows:
s1, synthesizing CD-COOH: weighing CD and NaOH, dissolving with water for injection, and adding ClCH in corresponding amount2COONa, and performing oil bath reaction for 5 hours at the temperature of 50 ℃; then regulating the pH value of the system to 6-7 by hydrochloric acid, dropwise adding the system into an excessive organic solvent, filtering and collecting precipitates, and drying to obtain CD-COOH;
s2, synthesis of CS-g-CD: weighing CD-COOH and NHS, dissolving with water for injection, replacing air, carrying out water bath at 4 ℃ for 2h, adding EDC, and carrying out water bath at 4 ℃ for reaction for 2 h; n is a radical of2Adding chitosan in the atmosphere, and reacting for 24 hours at room temperature; centrifuging, filtering, dialyzing, and lyophilizing to obtain CS-g-CD;
s3 Synthesis of CS-g- (CD + HCA): weighing CS-g-CD and NHS, dissolving with water for injection, replacing air, carrying out water bath at 4 ℃ for 2h, adding EDC, and carrying out water bath at 4 ℃ for reaction for 2 h; n is a radical of2Adding HCA under the atmosphere, and reacting for 24h at room temperature; centrifuging, filtering, dialyzing, and lyophilizing to obtain CS-g- (CD + HCA).
The invention has the beneficial effects that: the invention obviously prolongs the effective time of the mouthwash in the oral cavity, reduces the high drug concentration of antibiotic destruction and bacterial biofilm eradication, and greatly reduces the toxic and side effect caused by the drug; the mouthwash prolongs the retention time of the carrier and the medicament in the oral cavity, thereby increasing the actual action time of the medicament; the antibacterial result shows that: the mouthwash of the invention has excellent effect of eradicating bacterial biofilm in vitro and shows excellent curative effect of first-line clinical medicines (minocycline and chlorhexidine) in vivo.
Drawings
FIG. 1: of CCH1H NMR spectrum.
FIG. 2: retention of mouthwash on bacterial biofilm experiments.
FIG. 3: penetration test of mouthwash in bacterial biofilm.
FIG. 4: results of in vitro antifungal experiments.
FIG. 5: results of in vivo antifungal experiments.
FIG. 6: gingival Bleeding Index (GBI) comparison plots.
FIG. 7: intraoral bacterial biofilm area comparison plots.
Detailed Description
In the following description of specific embodiments, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described herein and is therefore not limited to the specific embodiments disclosed below.
EXAMPLE 1 Synthesis of a Polymer graft copolymer
A high molecular graft copolymer having the formula: CS-g- (CD + HCA).
The synthetic route is as follows:
Figure 297981DEST_PATH_IMAGE001
the synthesis steps are as follows:
s1, synthesizing CD-COOH: firstly, 11.92 g of beta-CD and 7.2 g of NaOH are put into a flask and dissolved by 30 mL of injection water; 1.165 g of ClCH was added2COONa, and carrying out oil bath reaction for 5 hours at 50 ℃; adjusting pH of the solution to 6-7 with hydrochloric acid, adding the product dropwise into excessive acetone for precipitation, freezing at 4 deg.C, vacuum filtering, collecting precipitate, and vacuum drying for 24 hr to obtain white powder: monocarboxylated cyclodextrins (abbreviated: CD-COOH);
s2, synthesis of CS-g-CD: CD-COOH (1.313 g, 1.1 mmol) and NHS (0.173 g, 2.8 mmol) were placed in a flask equipped with a magnetic stir bar, dissolved with 180 mL of water for injection, 3 times displaced by air, the flask was placed in a 4 ℃ water bath for 2h, EDC (0.211 g, 2.4 mmol) was added and reacted at 4 ℃ for 2 h; under magnetic stirring, N2Adding 0.222 g of Chitosan (CS) under protection, and reacting for 24 hours at room temperature; dialyzing with water for injection for three days, and freezing to obtain CS-g-CD (abbreviated as CC);
s3 Synthesis of CS-g- (CD + HCA): CS-g-CD (2.15 g) and NHS (141 mg, 1.225 mmol) were placed in a flask equipped with a magnetic stir bar, dissolved with 300 mL of water for injection, 3 times displaced of air, the flask was placed in a water bath at 4 ℃ and the reaction was reversedEDC (156.9 mg, 0.818 mmol) was added for 2h and reacted at 4 ℃ for 2 h; under magnetic stirring, N2Adding HCA (123.9 mg, 0.681 mmol) under protection, and reacting at room temperature for 24 h; dialyzed against water for injection for three days, and frozen to obtain CS-g- (CD + HCA) (abbreviated as CCH).
Of CCH in S31The H NMR spectrum is shown in FIG. 1. In the spectrum of CCH, peaks of 6.5-6.8 ppm are assigned to characteristic peaks on the benzene ring. These results are consistent with literature reports, demonstrating the successful synthesis of the target polymer; calculating the substitution degree of the CD to be 50 percent of the chitosan main chain according to the area integral ratio of the peak (CD) at the position of 4.9-5.0 ppm and the peak (CS) at the position of 2.7-2.9 ppm; the degree of substitution of HCA was calculated to be 14% of the chitosan main chain from the area integral ratio of the peak (benzene ring) at the 6.5-6.8 ppm position to the peak (CS) at the 2.7-2.9 ppm position.
Example 2 preparation of- -0.1wt% CCH-MI mouthwash
First, 0.6 g of CCH copolymer of example 1 was weighed, 100 mL of water for injection was added thereto, and stirred until completely dissolved; then, precisely weighing 0.1 g of Minocycline Hydrochloride (MH) and adding the Minocycline Hydrochloride (MH) into the solution, and stirring the solution until the Minocycline Hydrochloride (MH) is completely dissolved to obtain a light yellow solution; then, centrifuge at 3500 rpm for 10min, and then dialyze the supernatant (MWCO: 3500 Da) against water for injection to remove the drug without loading, to obtain 0.1wt% CCH-MI mouthwash. The whole operation process is carried out at room temperature.
And (3) performance testing:
1. retention test of mouthwash on bacterial biofilm
Cy5 fluorescently labeled CCH solution: weighing 45 mg of CCH prepared in example 1, dissolving the CCH in 3 mL of physiological saline, and stirring until the CCH is completely dissolved; 40 mu g of Cy5 (mono-succinimidyl ester) is weighed and dissolved in 200 mu L of absolute ethyl alcohol, the solution is slowly dripped into the CCH solution, and the solution is continuously shaken to obtain a blue solution, namely the Cy5 fluorescence labeled CCH solution.
The most common pathogenic bacteria of periodontitis, namely Porphyromonas gingivalis, are selected as research objects, and a Cy5 fluorescence labeling CCH solution is used for observing the retention time of a carrier CCH on the surface of a bacterial biomembrane. The retention test procedure is as follows: lyophilized powder of P.gingivalis strain (BNCC 353909) was purchased, as saidActivating in the specification, picking out white bacterial colony after activation, grinding and scattering in physiological saline, measuring turbidity with McLee's instrument, and diluting into 10% by calculation in brain-heart infusion broth liquid culture medium (BHI liquid culture medium for short)5CFU/mL bacterial liquid for later use; taking a sterile 24-hole plate, placing a glass slide with the diameter of 8mm at the bottom of the hole, dripping 400 mu L of the bacterial liquid into the hole, culturing in an anaerobic incubator at 37 ℃ for 3 days to form a mature bacterial biofilm on the slide, then removing the 24-well plate, discarding the supernatant, washing with PBS to remove non-adherent free bacteria, 200 mul of Cy5 fluorescence labeling CCH solution and 200 mul of BHI liquid culture medium are added into the hole with the attached biological membrane, meanwhile, a well without the Cy5 fluorescence labeling CCH solution is used as a control (only 400 mu L of BHI liquid culture medium is added into the well at the moment), after 1 hour of incubation, the supernatant is discarded, PBS is washed for three times, 400 mu L of BHI liquid culture medium is added again, then the BHI liquid culture medium is changed occasionally to simulate the flushing of saliva in the oral cavity, after 12 hours, a slide is taken out, 4% paraformaldehyde is fixed, and after DAPI (blue fluorescence) counterstaining, a laser confocal microscope is used for observation.
The results of the experiment are shown in fig. 2, the left is the control well without the addition of Cy5 fluorescently labeled CCH solution, and the right is the experimental well with the addition of Cy5 fluorescently labeled CCH solution. The results show that: compared with a control hole, the mouthwash carrier can be specifically adhered to a bacterial biofilm, can resist liquid washing for 12 hours, and shows excellent adhesion performance to the bacterial biofilm.
2. Permeability test of mouthwash in bacterial biofilm
Hydrophobic coumarin 6 (C6 for short) (green fluorescence) marker is used for replacing hydrophobic minocycline as a simulated drug to prepare a double fluorescence-labeled CCH solution for simulating CCH-MI mouthwash, and the permeation and diffusion behaviors of C6 in bacterial biofilms are observed. Wherein, the double fluorescence labeling CCH solution is prepared according to the following processes: weighing 45 mg of CCH prepared in example 1, dissolving the CCH in 3 mL of physiological saline, and stirring until the CCH is completely dissolved; weighing 40 mu g of Cy5 (mono-succinimidyl ester) to be dissolved in 200 mu L of absolute ethanol, slowly dripping the solution into the CCH solution, and continuously shaking to obtain a blue solution; measuring 5 mg of coumarin 6 (C6), dissolving in 1 mL of DMF, slowly adding dropwise into a blue solution, continuously shaking to obtain a green turbid solution, placing in a refrigerator at 4 ℃, transferring the green turbid solution into a dialysis bag (3500 Da) after 8 hours, using physiological saline as the dialysis solution for dialysis for 8 hours, changing the physiological saline three times to obtain a green turbid solution, transferring to a 15 mL centrifuge tube, centrifuging at 4000 rpm for 3 minutes, and taking 7 mL of supernatant, namely the double fluorescence labeling CCH solution.
The permeability test procedure is as follows: taking a sterile 24-well plate, placing a glass slide with a diameter of 8mm at the bottom, and dripping 400 mu L10 mu L of the glass slide into each well5The preparation method comprises the following steps of culturing a CFU/mL porphyromonas gingivalis bacterial solution (the preparation process is the same as that in the '1 retention experiment of mouthwash on a bacterial biofilm'), culturing for 3 days in an anaerobic incubator at 37 ℃ so as to form a mature bacterial biofilm on a slide, taking out a 24-hole plate, discarding supernatant, washing by PBS to remove non-adhered free bacteria, adding 200 mu L of double-fluorescence labeling CCH solution and 200 mu L of BHI liquid culture medium into a hole attached with the biofilm, respectively incubating for 10min, 30min and 1h, then discarding supernatant, washing by PBS for three times, taking out the slide, fixing by 4% paraformaldehyde, and observing by using a laser confocal microscope after DAPI counterstaining. Meanwhile, the wells without the double-fluorescence labeled CCH solution are selected as 0-time control, and only 400 μ L of BHI liquid culture medium is added into the wells at the moment.
The results of the experiment are shown in FIG. 3. The results show that: after 10min of adding the double-fluorescence labeling CCH solution, red fluorescence representing the carrier appears on the surface of the bacterial biofilm represented by blue fluorescence, and the periphery of the red fluorescence representing the green fluorescence of the medicine appears. This means that the drug carrier has partially adhered to the surface of the bacterial biofilm and released the simulated drug; as can be seen from the cross section, the green fluorescence enters the light layer of blue fluorescence, representing the light layer where part of the drug enters the bacterial biofilm; after 30min, the red fluorescence area covered on the surface of the bacterial biofilm is gradually increased, and the green fluorescence area around the red fluorescence area is also obviously increased, which means that the drug carriers adhered to the bacterial biofilm are gradually increased, and the drug release is also gradually increased; as can be seen from the section, the position of the green fluorescence in the biological membrane is further deepened, the area is further increased, and the quantity and the depth of the medicine entering the bacterial biological membrane are further increased; after 1h, the surface of the blue bacterial biofilm is almost completely covered by red fluorescence, and a large amount of green fluorescence is released; in cross section, the green fluorescence penetrated the entire layer of blue fluorescence, and the blue fluorescence surface covered with red fluorescence, representing the permeation of the drug into the entire layer of the biofilm. Shows that: the mouthwash disclosed by the invention is adhered to the surface of a bacterial biomembrane through a carrier, so that the retention time of the medicine in the mouth is prolonged, meanwhile, the hydrophobic antibacterial medicine is continuously released, the local medicine concentration is ensured, the penetration of the medicine in the biomembrane is facilitated, and the bioavailability of the medicine is greatly improved. In addition, the hydrophobic drug selected by the mouthwash is easier to diffuse in the biological membrane, and is beneficial to killing bacteria in the biological membrane.
3. In vitro disruption and eradication of biofilm experiment
In vitro biofilm disruption and eradication experiments were conducted with the most common periodontitis pathogen, Porphyromonas gingivalis (BNCC 353909), as the subject, with 0.1wt% CCH-MI mouthwash prepared in example 2 as the experimental group, and with 0.1wt% minocycline hydrochloride aqueous solution and 0.1wt% concentrated chlorhexidine solution as the positive control group, and the lowest biofilm eradication concentration was tested. Wherein, the 0.1wt% minocycline hydrochloride aqueous solution is prepared by the following process: weighing 20 mg of Minocycline Hydrochloride (MH) drug, dissolving in 20 mL of water for injection, and stirring until the drug is completely dissolved to obtain 0.1wt% minocycline hydrochloride water solution; a0.1 wt% concentrated chlorhexidine solution was prepared as follows: a2% concentrated chlorhexidine solution (250 mL in specification) produced by Fujianwei Zhenyuan medicine science and technology Co., Ltd is purchased in the market, and then the solution is diluted into chlorhexidine with the concentration of 0.1wt% by using purified water, so that the 0.1wt% concentrated chlorhexidine solution is obtained.
The specific experimental procedure is as follows:
biofilm disruption test: preparation 105CFU/mL Porphyromonas gingivalis bacterial liquid (the preparation process is the same as that in the '1 retention experiment of mouthwash on bacterial biofilm'), adding 300 muL of bacteria into a 48-hole plate with a slide placed at the bottom, culturing in an anaerobic incubator at 37 ℃ for 3 days to form a mature bacterial biofilm, discarding supernatant, washing with PBS, washing off planktonic bacteria, adding 150 muL of BHI liquid, and culturingAdding 150 mu L of liquid medicine of 1, 2, 4 and 8 mu g/mL prepared by a microdilution method into the culture medium, taking a hole which is not added with any medicine and is only added with 300 mu L of BHI liquid culture medium as a blank control, incubating for 1 day, then discarding the supernatant, adding 300 mu L of crystal violet water solution (1.0%), forming a precipitate by a bacterial biofilm and crystal violet after 20min, and measuring the absorbance value (A570 value) at 570 nm by using an enzyme labeling instrument after dissolving crystal particles by using ethanol.
The results of the experiment are shown in FIG. 4, where Control represents a blank Control- -no drug added but only BHI liquid medium added, MH represents that the drug added is 0.1wt% minocycline hydrochloride aqueous solution, CHX represents that the drug added is 0.1wt% concentrated chlorhexidine solution, CCH represents that the drug added is the polymer graft copolymer prepared in example 1, CCH-MI represents that the drug added is 0.1wt% CCH-MI mouth wash prepared in example 2, FIG. 4A is a digital image of the degree of damage of different drugs to the biological membrane by visual observation, FIG. 4B is a quantitative statistical image of the degree of damage of different concentrations of drugs to the biological membrane, the Control group in figure 4A is a group that exhibited the amount of bacterial biofilm growth without any added drug, FIG. 4B is a graph with the ordinate representing the percentage of biofilm disruption, which is the percentage of the amount of bacterial biofilm growth in the corresponding drug group versus the amount of bacterial biofilm growth in the Control group. The results show that: compared with CCH group, CHX group and MH group, the mouthwash of the invention has obvious damage to the biological membrane when the concentration is 8 mug/mL, and the CCH group, CHX group and MH group have large area of bacterial biological membrane; the mouthwashes of the present invention exhibit superior biofilm disruption properties in vitro relative to the MH and CHX groups.
Biofilm eradication experiments: preparation 105CFU/mL porphyromonas gingivalis bacterial liquid (the preparation process is the same as that in the '1, retention experiment of mouthwash on bacterial biofilm'), 200 muL of each hole is added into a 96-hole plate with a slide placed at the bottom, then the bacterial biofilm is cultured in an anaerobic incubator at 37 ℃ for 3 days to form a mature bacterial biofilm, PBS is washed after supernatant is discarded, planktonic bacteria are washed off, 100 muL BHI liquid culture medium is added, 100 muL of 0.5, 1, 2, 4, 8, 16, 32, 64, 128 and 256 mug/mL of liquid medicine prepared by a microdilution method is added, supernatant is discarded after 1 day of incubation, 200 muL LBHI liquid culture medium is added into each hole, and the supernatant is discardedThe medium was incubated for a further 1 day and the absorbance at 600 nm (A600 value) was measured using a microplate reader.
The experimental results are shown in figure 5, and MH, CHX, CCH-MI have the same meanings as figure 4. The results show that: compared with the CHX group and the MH group, the mouthwash can eradicate the bacterial biofilm when the concentration of the minocycline hydrochloride aqueous solution reaches 128 mug/mL, and the bacterial biofilm cannot be eradicated by the concentrated chlorhexidine solution within the tested concentration.
4. In vivo biofilm resistance assay
SD male rats are taken as research objects, and a rat periodontitis model is established by a method of infinity ligation, local smearing of porphyromonas gingivalis bacterial liquid and high-sugar diet to research the in-vivo effect of the mouthwash. The 0.1wt% CCH-MI mouth rinse prepared in example 2 was used as the test group, 0.1wt% minocycline hydrochloride aqueous solution and 0.1wt% concentrated chlorhexidine solution were used as the positive control group, and physiological saline was used as the blank control group, wherein the 0.1wt% minocycline hydrochloride aqueous solution and 0.1wt% concentrated chlorhexidine solution were prepared as described in "3, in vitro disruption and biofilm eradication test".
The specific experimental procedure is as follows: SD male rats are anesthetized with 10% chloral hydrate (4 mL/kg), under an operating microscope, 5-0 silk thread is ligated to the upper left first and second molar necks, the silk thread penetrates into the gingival sulcus as far as possible, then the cut is made at the gingival part of the ligation part by a blade, and then 10% of the cut is cut by a sterilized bamboo stick5Applying CFU/mL of a Porphyromonas gingivalis liquid (the preparation process is the same as that in the '1 retention experiment of mouthwash on bacterial biomembrane') to a ligation area; after two days, 20 muL of the drug is respectively poured into the oral cavity of the rat and stays for 10 seconds, the drug is administered once every 12 h, the redness and swelling bleeding condition of the gum in the ligation region of the rat is observed 14 days after the drug is administered, the Gum Bleeding Index (GBI) is graded, the drug is dyed with basic fuchsin, and the area of the bacterial biofilm in the oral cavity of the rat is checked and calculated by using Image J software.
Gingival Bleeding Index (GBI) scoring criteria:
0, the gingival margin and the gingival papilla are healthy in appearance, and bleeding does not occur after the gingival sulcus is slightly explored;
1, the gingival margin and the gingival papilla are mild inflammation, and the bleeding does not occur after the gingival sulcus is slightly explored;
2, the gingiva is slightly inflamed, has color change and no swelling or hematoma, and is subjected to punctate bleeding after probing;
3, the gingiva is moderate in inflammation, has color change and mild edema, and bleeds after probing, and the blood overflows in the gingival sulcus;
4, the gingiva is moderate in inflammation, not only is the color changed, but also the gingiva is obviously swollen, and bleeding are caused after probing and bleeding are spilled out of the gingival sulcus;
the color of the gum changes, swelling and sometimes ulceration, bleeding after probing, or bleeding spontaneously.
Gingival Bleeding Index (GBI) As shown in FIG. 6, Control represents blank Control (saline, not treated with drug), CHX represents positive Control 0.1wt% chlorhexidine mouthwash, MH represents positive Control 0.1wt% minocycline hydrochloride aqueous solution, and CCH-MI represents experimental group 0.1wt% CCH-MI mouthwash. As can be seen from fig. 6: the mean value of the gingival bleeding index of the blank control group can reach 4.5, the gingival bleeding condition of the positive control group is slightly improved, but no statistical difference exists, and compared with the positive control group, the gingival bleeding index of the mouthwash is obviously reduced after the mouthwash is used, and the difference has statistical significance.
The area of the bacterial biofilm in the mouth is shown in FIG. 7, FIG. 7A is a picture of basic fuchsin staining of the bacterial biofilm in the mouth of rats, FIG. 7B is a quantitative analysis of the fuchsin staining area, and the meaning of Control, MH, CHX and CCH-MI are the same as those in FIG. 6. Large-area biofilm staining can be seen on the surfaces of the teeth of rats in the blank control group and the positive control group, and the damage of sclerotin at the neck of the tooth and the exposure of the tooth root can be seen; compared with a positive control group, after the mouthwash disclosed by the invention acts, bacterial biofilms on the surfaces of teeth are obviously reduced, and the difference has statistical significance. The results show that: the mouthwash of the invention can resist saliva washing, can maintain the drug concentration locally in the oral bacterial biofilm, effectively eradicate the oral bacterial biofilm, and greatly improve the oral antibacterial effect of the mouthwash.

Claims (6)

1. An antibacterial mouthwash is characterized in that: the mouthwash is prepared from the following raw materials in percentage by g/mL: 0.1-1% of mouthwash drug, 0.5-10% of polymer graft copolymer and the balance of water for injection; wherein the macromolecular graft polymer is chitosan-g- (cyclodextrin +3, 4-dihydroxyphenyl propionic acid).
2. The antibacterial mouthwash according to claim 1, wherein: the mouthwash medicament is an antibacterial medicament.
3. The antibacterial mouthwash according to claim 2, wherein: the antibacterial drug is minocycline.
4. The antibacterial mouthwash according to claim 1, wherein: in the high molecular graft copolymer, the grafting rate of cyclodextrin is 20-80%, and the grafting rate of 3, 4-dihydroxyphenyl propionic acid is 1-15%.
5. The antibacterial mouthwash according to claim 1, wherein: the cyclodextrin is alpha-cyclodextrin, beta-cyclodextrin or gamma-cyclodextrin.
6. A process for the preparation of an antibacterial mouthwash according to any one of claims 1 to 5, characterized in that: firstly, weighing a high-molecular graft polymer, adding injection water with the formula amount, and stirring until the high-molecular graft polymer is completely dissolved; then weighing the mouthwash medicament, adding the mouthwash medicament into the solution, stirring and centrifuging; and (5) sucking the supernatant, dialyzing, and finally sterilizing to obtain the antibacterial mouth wash.
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Application publication date: 20210917