CN113088413B - Preparation method of handmade soap capable of removing bacterial biofilm - Google Patents

Abstract

The invention discloses a preparation method of handmade soap capable of obviously removing bacterial biofilm. The invention adopts natural chlorogenic acid and tea seed oil as main active ingredients, and the handmade soap capable of obviously removing bacterial biofilms is prepared by matching, so as to provide a new choice for inhibiting harmful bacteria and reducing the harm of the harmful bacterial biofilms.

Description

Preparation method of handmade soap capable of removing bacterial biofilm

Technical Field

The invention relates to a preparation method of handmade soap capable of removing bacterial biofilm, and belongs to the technical field of handmade soap.

Background

With the improvement of the living standard of people, the green and environment-friendly health concept is increasingly deep in the mind, and the old handmade soap is returned to the field of vision of people. Because of the inexpensive price of handmade soaps, bad merchants have introduced them to imitate and impersonate them. Some of the soap base is crisp and takes the "handmade" two words as an article, and based on cheap soap base, and chemical synthesis reagents such as pigment, essence, preservative, antioxidant and the like are added to make the soap base soap with bright color and fragrant smell, and finally the soap base soap is marketed in the form of "handmade soap", so that the benefit of consumers is seriously infringed, and the handmade soap market is disturbed.

At present, the drug resistance problem of various pathogenic bacteria is more and more serious, the health of people is seriously threatened, and especially the bacterial biofilm (biofilm) has stronger drug resistance than planktonic bacteria, and the harm is more serious. In recent years, the related activity of natural compounds attracts attention, and the natural compounds are not easy to form drug resistance, have small side effects and have wide prospects. The natural active ingredients are adopted to remove the bacterial biofilm, so that the drug resistance of bacteria and adverse reactions of medicines can be avoided.

The method aims to provide a preparation method of the traditional handmade soap, and the preparation method of the handmade soap has the function of removing harmful bacterial biomembrane, so that the harm of the bacterial biomembrane is eliminated, and the health of people is protected.

Disclosure of Invention

(1) Taking 10-20 parts of tap water, taking 3-20 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 36-46 ℃ to obtain alkali liquor;

(2) Taking 3-20 parts of coconut oil and 5-60 parts of palm oil, placing the palm oil in a reaction kettle, and heating the palm oil in a water bath to 36-46 ℃ to obtain mixed oil;

(3) Slowly adding the alkali liquor obtained in the step (1) into the mixed oil liquid obtained in the step (2) under the condition of stirring, controlling the temperature at 40-60 ℃, continuously stirring until the mixed liquid is pasty, adding 0.1-10 parts of tea seed oil, adding 0.5-10 parts of chlorogenic acid, and uniformly stirring to obtain soap liquid;

(4) Pouring the soap solution obtained in the step (3) into a mold, placing the mold in a room for 2-5d, demolding, and air-drying for 1-16d to obtain the handmade soap capable of obviously removing bacterial biofilm.

The invention has the beneficial effects that:

The inhibitor provided by the invention adopts chlorogenic acid with high safety as a main active ingredient, and camellia oil as an auxiliary ingredient, so that the chlorogenic acid and the camellia oil can be cooperatively matched to influence the physiological function of a bacterial biological film, and the biological film removing effect of the handmade soap is further enhanced.

The handmade soap disclosed by the invention is prepared from natural raw materials, so that the safety of the handmade soap is obviously improved, the skin is obviously protected, and the side effect is obviously reduced.

Detailed Description

The following description of the preferred embodiments of the present invention is provided for better illustration of the invention, and should not be construed as limiting the invention.

Example 1

Taking 13 parts of tap water and 5 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 46 ℃ to obtain alkali liquor;

10 parts of coconut oil and 35 parts of palm oil are taken and placed in a reaction kettle, and water bath is carried out to heat to 43 ℃ to obtain mixed oil;

Slowly adding alkali liquor into the mixed oil under the condition of stirring, controlling the temperature at 55 ℃, continuously stirring until the mixed liquor is pasty, adding 3 parts of tea seed oil, adding 4 parts of chlorogenic acid, and uniformly stirring to obtain soap solution;

pouring soap liquid into a mold, placing the mold in a room for 3d, demolding, and air-drying for 7d to obtain the handmade soap capable of remarkably removing bacterial biofilm.

Example 2

Taking 11 parts of tap water and 5 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 46 ℃ to obtain alkali liquor;

10 parts of coconut oil and 37 parts of palm oil are taken and placed in a reaction kettle, and water bath is carried out to heat the mixture to 46 ℃ to obtain mixed oil liquid;

Slowly adding alkali liquor into the mixed oil under the condition of stirring, controlling the temperature at 55 ℃, continuously stirring until the mixed liquor is pasty, adding 1 part of tea seed oil, adding 7 parts of chlorogenic acid, and uniformly stirring to obtain soap solution;

pouring soap liquid into a mold, placing the mold in a room for 3d, demolding, and air-drying for 8d to obtain the handmade soap capable of obviously removing bacterial biofilm.

Example 3

Taking 18 parts of tap water and 6 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 40 ℃ to obtain alkali liquor;

taking 20 parts of coconut oil and 27 parts of palm oil, and placing the coconut oil and the palm oil into a reaction kettle, and heating the mixture to 46 ℃ in a water bath to obtain mixed oil liquid;

slowly adding alkali liquor into the mixed oil under stirring, controlling the temperature at 59 ℃, continuously stirring until the mixed liquor is pasty, adding 4 parts of tea seed oil, adding 5 parts of chlorogenic acid, and uniformly stirring to obtain soap solution;

Pouring soap liquid into a mold, placing the mold in a room for 2d, demolding, and air-drying for 10d to obtain the handmade soap capable of remarkably removing bacterial biofilm.

Example 4 cleaning action of handmade soap on bacterial biofilm

Experiment group 1:

Taking 11 parts of tap water and 5 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 46 ℃ to obtain alkali liquor;

10 parts of coconut oil and 37 parts of palm oil are taken and placed in a reaction kettle, and water bath is carried out to heat the mixture to 46 ℃ to obtain mixed oil liquid;

Slowly adding alkali liquor into the mixed oil under the condition of stirring, controlling the temperature at 55 ℃, continuously stirring until the mixed liquor is pasty, adding 1 part of tea seed oil, adding 1 part of chlorogenic acid, and uniformly stirring to obtain soap solution;

pouring soap liquid into a mold, placing the mold in a room for 3d, demolding, and air-drying for 8d to obtain the handmade soap capable of obviously removing bacterial biofilm.

Experiment group 2:

Taking 11 parts of tap water and 5 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 46 ℃ to obtain alkali liquor;

10 parts of coconut oil and 37 parts of palm oil are taken and placed in a reaction kettle, and water bath is carried out to heat the mixture to 46 ℃ to obtain mixed oil liquid;

slowly adding alkali liquor into the mixed oil under the condition of stirring, controlling the temperature at 55 ℃, continuously stirring until the mixed liquor is pasty, adding 1 part of tea seed oil, adding 0 part of chlorogenic acid, and uniformly stirring to obtain soap solution;

pouring soap liquid into a mold, placing the mold in a room for 3d, demolding, and air-drying for 8d to obtain the handmade soap capable of obviously removing bacterial biofilm.

Experiment group 3:

Taking 11 parts of tap water and 5 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 46 ℃ to obtain alkali liquor;

10 parts of coconut oil and 37 parts of palm oil are taken and placed in a reaction kettle, and water bath is carried out to heat the mixture to 46 ℃ to obtain mixed oil liquid;

slowly adding alkali liquor into the mixed oil under the condition of stirring, controlling the temperature at 55 ℃, continuously stirring until the mixed liquor is pasty, adding 0 part of tea seed oil, adding 1 part of chlorogenic acid, and uniformly stirring to obtain soap solution;

pouring soap liquid into a mold, placing the mold in a room for 3d, demolding, and air-drying for 8d to obtain the handmade soap capable of obviously removing bacterial biofilm.

Experiment group 4:

Taking 11 parts of tap water and 5 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 46 ℃ to obtain alkali liquor;

10 parts of coconut oil and 37 parts of palm oil are taken and placed in a reaction kettle, and water bath is carried out to heat the mixture to 46 ℃ to obtain mixed oil liquid;

slowly adding alkali liquor into the mixed oil under the condition of stirring, controlling the temperature at 55 ℃, continuously stirring until the mixed liquor is pasty, adding 0 part of tea seed oil, adding 0 part of chlorogenic acid, and uniformly stirring to obtain soap solution;

pouring soap liquid into a mold, placing the mold in a room for 3d, demolding, and air-drying for 8d to obtain the handmade soap capable of obviously removing bacterial biofilm.

Measurement method

The experiment of removing the biological film is carried out by referring to the common experiment method at home and abroad. Taking 2 g of handmade soap sample, grinding, adding 10mL of water, and uniformly mixing to prepare the handmade soap liquid for later use. Adding staphylococcus aureus suspension into a 96-well plate, culturing for 24 hours at 37 ℃, discarding plankton bacteria, and washing for 3 times by using phosphate buffer solution; then adding culture medium, adding handmade soap liquid, and culturing at 37 deg.C for 4 hr.

The biofilm was analyzed by crystal violet staining. After the constant temperature culture is completed, the plankton is discarded, washed for 3 times, and dried and fixed at 60 ℃. Then adding 200 mu L of crystal violet solution (w/v) into each hole, dyeing for 5min, washing, flushing out redundant crystal violet dyeing liquid, drying at 37 ℃, adding 200 mu L of 95% ethanol for dissolving, measuring an OD value at 595nm after 30min, and calculating the clearance of the biological film.

Biofilm clearance= (OD of sample without soap solution-OD of sample with soap solution)/OD of sample without soap solution

The specific results are shown in Table 1.

Table 1 results of removal of biofilm by handsoaps from different experimental groups

The measurement result shows that the handmade soap containing 1 part of tea seed oil and 1 part of chlorogenic acid prepared in the example 1 can obviously remove bacterial biomembrane, and the removal rate reaches 93%. In the case of the simple handmade soap containing 1 part of tea seed oil, the handmade soap does not show the scavenging ability under the same use concentration. For the simple handmade soap containing 1 part of chlorogenic acid, the biological film removing capacity of the handmade soap is only 36% under the same use concentration, and for the handmade soap without the tea seed oil and the peach separating component, the biological film removing capacity is not shown under the same use concentration, which shows that: chlorogenic acid and tea seed oil can have synergistic effect, so that bacterial biofilm can be remarkably removed.

Claims (1)

1. A method for preparing handmade soap capable of remarkably removing bacterial biofilm, which comprises the following steps:

(1) Taking 11 parts of tap water and 5 parts of sodium hydroxide, adding sodium hydroxide into the water while stirring, stirring until the sodium hydroxide is completely dissolved in the water, and naturally cooling to 46 ℃ to obtain alkali liquor;

(2) 10 parts of coconut oil and 37 parts of palm oil are taken and placed in a reaction kettle, and water bath is carried out to heat the mixture to 46 ℃ to obtain mixed oil liquid;

(3) Slowly adding the alkali liquor obtained in the step (1) into the mixed oil liquid obtained in the step (2) under the condition of stirring, controlling the temperature at 55 ℃, continuously stirring until the mixed liquid is pasty, adding 1 part of tea seed oil, adding 1 part of chlorogenic acid, and uniformly stirring to obtain soap liquid;

(4) Pouring the soap solution obtained in the step (3) into a mold, placing the mold in a room for 3d, demolding, and air-drying for 8d to obtain the handmade soap capable of removing bacterial biofilm.