The present disclosure relates to the technical field of biomedicine, in particular to a polycationic polysaccharide and its applications as an antibacterial material and as a medicament for the treatment of chronic inflammatory disease.
Natural polymer polysaccharides have good biocompatibility and bioactivity, and are widely used in clinical and biomedical fields. At present, semi-synthetic cationization-modified natural polysaccharides are most widely studied. They can be used as a carrier for delivery of a nucleic acid medicament, since the amino group on the surface modification can be densely positively charged after protonation in aqueous solution. At the same time, there is a plenty of literature reporting that the polysaccharide structure containing a large number of positive charges has excellent antibacterial properties. Cationized polysaccharides can also bind to biological macromolecules via charge interaction, affecting the related functions of the biological molecules, thereby changing the activity of the biological molecules.
Biofilm is a bacterial colony formed by bacteria, which is wrapped with bacterial extracellular macromolecules secreted by a variety of gram-negative bacteria or gram-positive bacteria, and thus adhered to the surface of an object. Biofilm can easily cause various infections. Biofilm coating can make cells protected by the extracellular macromolecules, thereby resisting against the body's immune defense, and can increase the resistance to antibiotics by 10-1000 times. The existence of biofilm greatly increases the difficulty in killing bacteria for traditional medicines, and promotes the occurrence of chronic infection or secondary infection. Therefore, there is a need to find a novel biofunctional material which can prevent biofilm formation and treat biofilm-related disorders, sterilize biomedical devices, and has better sterilization effects.
Currently, in clinical treatment, the formation and growth of biofilm is still a problem to be solved. The prevention and treatment of bacterial biofilm still remains at killing bacteria with antibiotics to reduce the formation of biofilm. However, the existence of biofilm will protect bacteria from the threat of antibiotics, leading to a vicious circle. Researchers found that polycationic polysaccharides are more effective than previous anti-bacterial biofilm agents because of their unique structure and positive charges, which results in excellent antibacterial activity and unique biological activity such as functions of promoting wound repair. Therefore, a polycationic polysaccharide can be used as a medicament applied in the treatment of infection caused by bacterial biofilm and related chronic inflammatory disease, and can be used for the development and application of bactericidal smears for biomedical devices and new antibacterial functional materials.
In view of the above-mentioned problems in the prior art, the present disclosure provides a polycationic polysaccharide, and the prepared polycationic polysaccharide can be used for the application in biomedical functional materials, biomedical devices and materials with antibacterial functions.
The technical solution of the present disclosure is as follows:
A polycationic polysaccharide, the polycationic polysaccharide is a positively charged polycationic polysaccharide obtained by the reaction between a polysaccharide and a polyamine compound, wherein the polysaccharide has the following general formula:
Preferably, the structural formula of the polycationic polysaccharide is:
Preferably, the molecular weight of the polyamine compound is less than 500 Daltons, and the polyamine compound is any one of the following compounds:
Preferably, the number of sugar units in the structure of the polysaccharide is 2 to 2000.
The present disclosure also discloses the use of the polycationic polysaccharide described above as an antibacterial material.
Preferably, the antibacterial material achieves the effect of killing bacteria by destroying the biofilm structures of the bacteria.
Preferably, the antibacterial material is used for the preparation of a medicament or a medical device for the prevention or treatment of Gram-negative and/or Gram-positive bacterial infection.
Preferably, the antibacterial material is used as a biomedical functional material or a biomedical device.
Preferably, the antibacterial material is an antibacterial functional material, including a daily chemical product, a packaging product, and a home improvement product with antibacterial functions.
The present disclosure also discloses an antibacterial agent, prepared from the polycationic polysaccharide described above as an active ingredient and a pharmaceutically acceptable adjuvant.
The present disclosure also discloses an antibacterial medical device, prepared from the polycationic polysaccharide described above as an active ingredient and a pharmaceutically acceptable adjuvant.
The present disclosure also discloses the use of the polycationic polysaccharide described above as a medicament for the treatment of chronic inflammatory disease.
Preferably, the medicament for the treatment of chronic inflammatory disease includes the medicament for the prevention of surgical wound infection, and the medicament for the prevention of scalding wound infection.
Compared with the prior art (such as the solution with application number of 201810714603.6), the polycationic polysaccharide of the present disclosure has better antibacterial and anti-inflammatory capacities, and functions of promoting wound healing, and has lower cytotoxicity, resulting in a great potential to be applied in biomedical devices and biomedical functional materials.
The following examples are further descriptions of the present disclosure to be an illustration of the present technical content, but the essential content of the present disclosure is not limited to the following examples. Those of ordinary skill in the art can and shall know that any simple changes or substitutions based on the essential spirit of the disclosure shall be within the protection scope of the present disclosure claimed.
A method for producing a polycationic polysaccharide, comprising the following steps:
The specific reaction process is shown in the following formula:
The prepared polycationic polysaccharide was characterized by infrared spectroscopy:
200 mg of potassium bromide and 2 mg of polycationic polysaccharide sample were weighted, and then ground in an agate mortar under baking with infrared lamp for the whole grinding process. The sample powder was placed into a mold and a pressure was applied up to 20 MPa. Maintained for 2 minutes, and then reduced the pressure to 0 slowly. The pressed sample tablet was took out and tested on a machine.
The results are shown in
In addition, 5 mg of the prepared polycationic polysaccharide sample was weighted, then baked and ground fully under an infrared lamp. The sample powder was added to an elemental analyzer for testing. The results are shown in
The prepared polycationic polysaccharide was characterized by H NMR spectrum:
The results are shown in
Verification of cytotoxicity and tissue toxicity of the polycationic polysaccharide of the present disclosure.
Human umbilical vein epithelial cell HUVEC was selected, and inoculated into 96-well plate of cell culture at 104 cells/well, and then pre-cultured for 24 h. The cationized polysaccharide solution (cDex, derived from patent 201810714603.6) as prior art control group and the polycationic polysaccharide solution in this disclosure (named as DETA-Dex) were formulated with cell culture medium to a final concentration of 0.5 μg/ml, 1 μg/ml, 2.5 μg/ml, 5 μg/ml, 10 μg/ml, 20 μg/ml, 50 μg/ml, 100 μg/ml, respectively, and then added to the cell culture system for 30 min. After which, the cells were washed with cell culture medium for detection of cell activity.
Statistical results are shown in
a. Establishment of a Mouse Back Trauma Model According to Literature Reports
Balb/c female mice were selected, weighed and recorded. The mice were randomized into groups with 10 mice per group. All the animals were intraperitoneally anesthetized with pentobarbital sodium. The back was dehaired and sterilized. At the thicker central part on the back of the mouse, a circular skin with a diameter of 0.5 cm was cut off to make a mouse back trauma model.
b. Medicament Treatment after Modeling
In order to detect the tissue toxicity of the polycationic polysaccharide of the present disclosure to wound tissue, an experiment was performed as follows:
Statistical results are shown in
Verification of therapeutic effect of the polycationic polysaccharide of the present disclosure on the model of wound infection by Pseudomonas aeruginosa.
a. Establishment of a Mouse Back Trauma Model According to Literature Reports
Balb/c female mice were selected, weighed and recorded. The mice were randomized into groups with 10 mice per group. All the animals were intraperitoneally anesthetized with pentobarbital sodium. The back was dehaired and sterilized. At the thicker central part on the back of the mouse, a circular skin with a diameter of 0.5 cm was cut off to make a mouse back trauma model.
b. Infection of Mouse by Pseudomonas aeruginosa after Modeling
Mice in each group were evenly smeared with Pseudomonas aeruginosa bacterial solution at the wound site at a dose of 108 CFU/mouse, and the bacteria could form a complete biofilm within 72 hours.
c. Medicament Treatment
In order to detect the influence of the polycationic polysaccharide of the present disclosure on biofilm activity, an experiment was performed as follows:
Statistical results are shown in
A method for constructing the polycationic polysaccharide of the present disclosure with mannan, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with chitosan, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with Bletilla striata polysaccharide, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with konjac polysaccharide, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with amylose, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with cellulose, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with different polyamine compounds, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with dextran of different molecular weights, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with different polyamine compounds and mannan, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with different polyamine compounds and chitosan, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with different polyamine compounds and Bletilla striata polysaccharide, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with different polyamine compounds and konjac polysaccharide, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with different polyamine compounds and amylose, comprising the following steps:
A method for constructing the polycationic polysaccharide of the present disclosure with different polyamine compounds and cellulose, comprising the following steps:
Verification of cytotoxicity of the polycationic polysaccharide of the present disclosure.
Human umbilical vein epithelial cell HUVEC was selected, and inoculated into 96-well plate of cell culture at 104 cells/well, and then pre-cultured for 24 h. The polycationic polysaccharide solution in this disclosure (named as DETA-Dex, DETA-Mannan, DETA-Chitosan, DETA-BSP, DETA-KGM, DETA-Amylose, DETA-Cellulose) were formulated with cell culture medium to a final concentration of 0.5 μg/ml, 1 μg/ml, 2.5 μg/ml, 5 μg/ml, 10 μg/ml, 20 μg/ml, 50 μg/ml, 100 μg/ml, respectively, and then added to the cell culture system for 30 min. After which, the cells were washed with cell culture medium for detection of cell activity.
Statistical results are shown in
Verification of therapeutic effect of the polycationic polysaccharides of the present disclosure constructed with different polysaccharides on the model of wound infection by Pseudomonas aeruginosa.
a. Establishment of a Mouse Back Trauma Model According to Literature Reports
Balb/c female mice were selected, weighed and recorded. The mice were randomized into groups with 10 mice per group. All the animals were intraperitoneally anesthetized with pentobarbital sodium. The back was dehaired and sterilized. At the thicker central part on the back of the mouse, a circular skin with a diameter of 0.5 cm was cut off to make a mouse back trauma model.
b. Infection of Mouse by Pseudomonas aeruginosa after Modeling
Mice in each group were evenly smeared with Pseudomonas aeruginosa bacterial solution at the wound site at a dose of 108 CFU/mouse, and the bacteria could form a complete biofilm within 72 hours.
c. Medicament Treatment
In order to detect the influence of the polycationic polysaccharides of the present disclosure on biofilm activity, an experiment was performed as follows:
Statistical results are shown in
The above descriptions are only preferred examples of the present disclosure and are not intended to limit the present disclosure. Any modification, equivalent replacement or improvement made within the spirit and principle of the present disclosure shall be included in the protection scope of the present disclosure.
Number | Date | Country | Kind |
---|---|---|---|
201911235541.1 | Dec 2019 | CN | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/CN2020/071067 | 1/9/2020 | WO |