Indian Patents. 263530:A PHARMACEUTICAL COMPOSITION AND PROCESS THEREOF FOR THE PREPARATION OF PLANT EXTRACTS FOR TREATING SKIN DISORDERS AND ENHANCING HEALING OF WOUNDS

Title of Invention	A PHARMACEUTICAL COMPOSITION AND PROCESS THEREOF FOR THE PREPARATION OF PLANT EXTRACTS FOR TREATING SKIN DISORDERS AND ENHANCING HEALING OF WOUNDS
Abstract	The invention provides a process for the preparation of Plectranthus amboinicus extracts using a stirring separation method. The invention also provides a pharmaceutical composition comprising the Plectranthus amboinicus crude extract and/or extract for treating skin disorders, including enhancing the healing of wounds, especially in diabetic patients.

Full Text	FIELD OF THE INVENTION The invention relates to a process for the preparation of Chinese herbal medicine extracts. Specifically, the invention relates to the use of a solid-liquid separation in combination with a specific treatment for mass production of a plant extract for treating skin disorders, including enhancing the healing of wounds, especially in diabetic patients. BACKGROUND OF THE INVENTION Plectranthus amboinicus (Lour.) Spreng, growing in Malaysia and India, is a decorative medicinal herb commonly cultivated by ordinary families. The medicinal part of Plectranthus amboinicus is the epigeal portion. Plectranthus amboinicus is also known as Cuban oregano, Indian borage, Indian mint, Mexican mint, Mexican oregano or Spanish thyme. East Indians use Plectranthus amboinicus as a fabric aromatic, and the English discovered its attractive fragrance when importing shawl fabrics from India in the 1820's. When the Plectranthus amboinicus leaves are put directly with clothing, it not only has an aromatic effect, but also prevents the clothing from being eaten by moths. It is thought to be useful for disinfection, enhancing sexual excitement and preventing insect bites. In addition, Plectranthus amboinicus may be used for treating poisonous snake bites and relieving symptoms such as headache, flatulence, vomiting, diarrhea and fever. Moreover, Plectranthus amboinicus oil is a popular perfume in Asia, and it is used in aromatherapy for improving epithelia regeneration, treating acne, and relieving the symptoms of eczema, Athlete's foot and dry cracked skin. Furthermore, Plectranthus amboinicus is a good tranquilizer and aphrodisiac that can relieve anxiety and enhance sexual desire. Various uses of Plectranthus amboinicus are reported in general magazines, but scientific studies on Plectranthus amboinicus are rarely seen in literature. US 2006/0099283 Al discloses leaf juice of Plectranthus amboinicus for treating cancer and/or tumor. USSN 11/605,178, a patent application relating to the present invention, provides a pharmaceutical composition comprising a therapeutically effective amount of Plectranthus amboinicus crude extracts/extracts and a therapeutically effective amount of Centella asiatica Urban extracts. Centella asiatica Urban (pennywort) is a plant naturally growing in the coastal areas of Madagascar and the Indian Ocean. The medicinal part of Centella asiatica Urban of the 2 Apiaceae family is its dried whole plant. Centella asiatica Urban is also known as European water-marvel, Gotu kola, Kola, Indian pennywort, Indian ginseng, Horse-hoof grass, Pegaga, Mandookaparni, Tiger herbal, Spadeleaf, or Tono. For hundreds of years, Centella asiatica Urban has been thought to be useful in the traditional medicine of Asia for improving wound healing. The extracts of Centella asiatica Urban comprise two major compounds: asiaticoside and madecassic acid. Centella asiatica Urban extracts are used to treat burns and trauma and prevent postoperative adhesion, and the preparation methods of Centella asiatica Urban extracts have been described in some patent applications. For example, US 4,318,906 and CN 1353972A disclose the medical uses of Centella asiatica Urban as the single active ingredient; US 6,475,536, US 6,267,996, CN 1313124A, CN 93110425.4 and CN 1089497A disclose the use of Centella asiatica Urban in combination with other substances for cosmetic formulation, treating burns or making ointment for trauma; and US 5,834,437, US 6,417,349 and CN 1194154A disclose the methods for preparing Centella asiatica Urban extracts. Conventional separation processes for separating the components from the mixture include contacting the mixture with a nonionic absorbing resin such as DIAION® HP20, DIAION® HP20SS, Sepabeads® SP207 (Mitsubishi Chemical Corporation), Amberlite™ XAD-2 (Rohm and Hass company), Amberlite™ XAD-4, and the like. The steps comprise packing the nonionic absorbing resin into a separation column, adding the mixture to the column, and eluting the column with a solvent. When such process is taken to treat a massive amount of a mixture, it is time-consuming and the elution conditions are not easily controlled. The leaf juice of US 2006/0099283 Al was obtained by grinding and removing tissue fragments and/or residues, and the different fractions of the leaf juice were separated with centrifugal filter devices. The Plectranthus amboinicus extracts of USSN 11/605,178 were prepared by utilizing a series of solvents with different polarities to elute the extracts from a chromatographic column. This method is complicated and time-consuming. There is still a need to provide a method for obtaining in large quantities the active ingredients of Plectranthus amboinicus. 3 Surprisingly, we found that a stirring method can replace the traditional column separation method and be used for mass production of Plectranthus amboinicus extracts. The stirring method is fast and the elution conditions can be easily controlled. Moreover, Plectranthus amboinicus extracts obtained by stirring separation are more effective than extracts prepared by column chromatographic separation. SUMMARY OF THE INVENTION One embodiment of the invention provides a process for preparing Plectranthus amboinicus crude extract and/or extracts. One embodiment of the invention provides a pharmaceutical composition for treating skin disorders (including enhancing the healing of wounds in diabetic patients), comprising a therapeutically effective amount of Plectranthus amboinicus crude extracts and/or extracts. The pharmaceutical composition may further comprise a therapeutically effective amount of Centella asiatica Urban extracts. One embodiment of the invention provides a wound dressing comprising the pharmaceutical composition of the invention. One embodiment of the invention provides a method for treating skin disorder comprising administering the pharmaceutical composition of the invention. The invention is described in detail in the following sections. Other characterizations, purposes and advantages of the invention can be easily found in the detailed descriptions and claims of the invention. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows the chromatographic spectrum of the Plectranthus amboinicus extract (PA-W4) prepared by stirring separation. The spectrum was determined by Reverse Phase HPLC at UV 270nm. Figure 2 shows the chromatographic spectrum of the Plectranthus amboinicus extract (PA-C4) prepared by column chromatographic separation. The spectrum was determined by Reverse Phase HPLC at UV 270nm. 4 Figure 3 shows wound closures in STZ-induced diabetic rats. Group 1: wound applied with placebo (ointment without medicament); Group 2: wound applied with ointment containing 1% Centella asiatica Urban extracts (SI); Group 3: wound applied with CGS-21680 (10fxg/ml); Group 4: wound applied with Regranex; Group 5: wound applied with DCB-WH1-C (ointment comprising 1% SI and 0.25% PA-C4); Group 6: wound applied with DCB-WH1-W (ointment comprising 1% SI and 0.25% PA-W4). Figure 4 shows wound closures in STZ-induced diabetic rats. Group 1: wound applied with placebo (ointment without medicament); Group 2: wound applied with ointment containing 1% Centella asiatica Urban extracts (SI); Group 3: wound applied with ointment containing 0.25% PA-W4; Group 4: wound applied with DCB-WH1-W (ointment comprising 1% SI and 0.25% PA-W4); Group 5: wound applied with ointment containing 1%PA-W4. DETAILED DESCRIPTION OF THE INVENTION Unless otherwise defined herein, scientific and technical terms used in connection with the present invention shall have the meanings that are commonly understood by those of ordinary skill in the art. The meaning and scope of the terms should be clear; however, in the event of any latent ambiguity, definitions provided herein take precedence over any dictionary or extrinsic definition. As utilized in accordance with the present disclosure, the following terms, unless otherwise indicated, shall be understood to have the following meanings: The term "skin disorders" as used herein includes wounds or sores. In one embodiment, skin disorders include cuts, lacerations, abrasions, stabs or other similar skin injuries, or a diabetic patient's wounds; sores include bedsores. The term "treating" or "enhancing" as used herein denotes improving the symptoms. The term "patients" as used herein denotes animals, especially mammals. In one embodiment, the term "patients" denotes "humans." 5 The term "therapeutically effective amount" as used herein refers to the amount of the pharmaceutical composition used alone or in combination with other medicaments for treating disorders that shows therapeutic efficacy. The term "carrier" or "pharmaceutically acceptable carrier" refers to diluents, excipients, acceptors or analogues, which are well known to persons of ordinary skill in the art for manufacturing pharmaceutical compositions. The term "Centella asiatica Urban extracts" denotes extracts of dried Centella asiatica Urban whole plants, wherein the major active components comprise asiaticoside and madecassic acid. In an embodiment, it is the medicinal part available on the market that mainly comprises asiaticoside and madecassic acid, and its purity is greater than 70%. The term "Plectranthus amboinicus crude extract" denotes an extract obtained from the epigeal portion of Plectranthus amboinicus, and the crude extract may be further concentrated. The term "Plectranthus amboinicus extract" denotes an extract obtained from the crude extract by further separation(s). The term "high-polarity solvent" denotes a solvent that has the highest polarity in the solvents used in the preparation process. The high-polarity solvent includes, but is not limited to, water, methanol, ethanol or a mixture of two or more of the preceding solvents. The term "low-polarity solvent" denotes a solvent that has the lowest polarity in the solvents used in the preparation process. The low-polarity solvent includes, but is not limited to, chloroform, isopropanol, acetone, ethyl acetate, a mixture of two or more of the preceding solvents, or a mixture of one or more of the preceding solvents with one or more solvent that have higher polarity. The term "sub-high-polarity solvent" denotes a solvent that has a polarity lower than that of the high-polarity solvent used in the preparation process but higher than that of the medium-polarity solvent used in the preparation process. The sub-high-polarity solvents can be obtained by mixing a high-polarity solvent with a solvent having lower polarity in a ratio (v:v) of about 30:70 to about 70:30, or about 60:40 to about 40:60. 6 The term "medium-polarity solvent" denotes a solvent that has a polarity lower than that of the sub-high-polarity solvent used in the preparation process but higher than that of the low-polarity solvent used in the preparation process. The medium-polarity solvents can be obtained by mixing a high-polarity solvent with a solvent having lower polarity in a ratio (v:v) of about 30:70 to about 5:95, or about 15:85 to about 5:95. Unless otherwise required by context, singular terms shall include the plural and plural terms shall include the singular. The Preparation Processes The invention is characterized by using solid-liquid separation (stirring separation) in combination with a specific treatment for mass production of Plectranthus amboinicus extracts in a faster manner with a higher yield. The stirring separation comprises stirring an absorbing resin, such as DIAION, into the Plectranthus amboinicus extract and separating the different fractions from the Plectranthus amboinicus extracts by differential separation steps with the utilization of different solvents. In addition to higher throughput, the Plectranthus amboinicus extract obtained by the process of the invention is more effective than that prepared by the column chromatographic separation method. The process of the invention for preparing Plectranthus amboinicus extracts comprises the steps of: - contacting the dried Plectranthus amboinicus leaves with a leaf extracting solvent to obtain a Plectranthus amboinicus crude extract; concentrating the Plectranthus amboinicus crude extract; and - treating the concentrated Plectranthus amboinicus crude extract using a stirring separation method to obtain a Plectranthus amboinicus extract. According to the invention, the stirring separation method comprises the following steps: (a) diluting the concentrated Plectranthus amboinicus crude extract with a high-polarity solvent, mixing the diluted Plectranthus amboinicus crude extract with an absorbing resin, and stirring the absorbing resin and the diluted Plectranthus amboinicus crude extract; 7 (b) removing the liquid portion, extracting the resin with distilled water, and collecting the first extract; (c) extracting the resin with a sub-high-polarity solvent and collecting the second extract; (d) extracting the resin with a medium-polarity solvent and collecting the third extract; and (e) extracting the resin with a low-polarity solvent and collecting the fourth extract. In one embodiment, the process for preparing Plectranthus amboinicus extracts comprises the steps of: 1. contacting dried Plectranthus amboinicus leaves with a leaf extracting solvent for about 30 to about 100 hours to obtain a Plectranthus amboinicus crude extract; 2. concentrating the Plectranthus amboinicus crude extract; 3. diluting the concentrated Plectranthus amboinicus crude extract with a high-polarity solvent and mixing the diluted Plectranthus amboinicus crude extract with an absorbing resin by stirring for about 10 to about 30 hours; 4. removing the liquid portion; 5. dipping the resin in distilled water for about 1 to about 7 hours to obtain a first extract (PA-W1); 6. mixing and stirring the resin with a sub-high-polarity solvent for about 1 to about 7 hours to obtain a second extract (PA-W2); 7. mixing and stirring the resin with a medium-polarity solvent for about 1 to about 7 hours to obtain a third extract (PA-W3); 8. mixing and stirring the resin with a low-polarity solvent for about 1 to about 7 hours to obtain a fourth extract (PA-W4). According to the process of the invention, the leaf extracting solvent is selected from, but not limited to, water and alcohols. In one embodiment, the alcohol is ethanol. The ratio of the volume of the leaf extracting solvent to the weight of the dried Plectranthus amboinicus leaves is about 6:1 to about 15:1, or about 10:1. 8 According to the process of the invention, the leaf extract obtained in step 1 may be concentrated by any conventional concentration methods for solutions, such as using a pressure-reducing rotary evaporator. According to the process of the invention, the absorbing resin is selected from, but not limited to, DIAION® HP20, DIAION® HP20SS, Sepabeads® SP207, Amberlite™ XAD-2, Amberlite™ XAD-4, and the like, or the DIAION® series. In one embodiment, the absorbing resin is DIAION® HP20. In addition, the DIAION®HP20 resin can be pre-treated with methanol. According to the process of the invention, the ratio of the volume of the high-polarity solvent to the weight of the dried Plectranthus amboinicus leaves is about 8:1 to about 4:1, or about 5:1; the ratio of the volume of the sub-high-polarity solvent to the weight of the dried Plectranthus amboinicus leaves is about 8:1 to about 4:1, or about 5:1; the ratio of the volume of the medium-polarity solvent to the weight of the dried Plectranthus amboinicus leaves is about 8:1 to about 4:1, or about 5:1; and the ratio of the volume of the low-polarity solvent to the weight of the dried Plectranthus amboinicus leaves is about 8:1 to about 4:1, or about 5:1. According to the process of the invention, the extraction period of step 1 is about 30 to about 100 hours, or about 50 to about 80 hours, or more than about 72 hours. The absorption period of step 3 is about 10 to about 30 hours, or about 17 to about 25 hours, or more than about 20 hours. The extraction period of step 5 is about 1 to about 7 hours, or about 1 to about 4 hours, or about 1 hour. The extraction period of step 6 is about 1 to about 7 hours, or about 1 to about 4 hours, or about 1 hour. The extraction period of step 7 is about 1 to about 7 hours, or about 1 to about 4 hours, or about 1 hour. The extraction period of step 8 is about 1 to about 7 hours, or about 1 to about 4 hours, or about 1 hour. Furthermore, according to the process of the invention, stirring is conducted at the speed of about 3 to about 15 rpm, or about 5 to about 10 rpm, or 7 rpm. The process of the invention is a high-throughput method for mass production of Plectranthus amboinicus extracts. The process is about five times faster than the column chromatographic separation method to extract the active fractions from Plectranthus amboinicus. 9 Pharmaceutical Compositions One embodiment of the invention provides a pharmaceutical composition comprising a therapeutically effective amount of Plectranthus amboinicus crude extract and/or extract prepared by the separation process of the invention. Another embodiment of the invention provides a pharmaceutical composition comprising a therapeutically effective amount of Plectranthus amboinicus crude extract and/or extract prepared by the separation process of the invention in combination with a therapeutically effective amount of Centella asiatica Urban extract. The pharmaceutical composition of the invention can be applied topically to the wounds, and it may be formulated as spray or non-spray. A spray form includes spray or solution; a non-spray form may be semi-solid or solid, or a solid form having a kinematic viscosity greater than water. Suitable formulations include but are not limited to suspensions, emulsions, creams, ointments, liniments and the like. If necessary, it may be sterilized or mixed with any pharmaceutically acceptable carriers, such as stabilizers, wetting agents and the like. In an embodiment, the pharmaceutical composition of the invention is formulated as ointments, wherein the pharmaceutically acceptable carriers include but are not limited to higher fatty acids, waxes, lipids, glycerol, higher alcohols or synthetic lipids. The pharmaceutical composition of the invention, no matter which form it is formulated in, may further comprise emollients, fragrances or colorings to increase the acceptability for various uses. The therapeutically effective amounts of the Plectranthus amboinicus crude extract and/or extract and the Centella asiatica Urban extract are disclosed in USSN 11/605,178, US 4,318,906, CN 1353972A, US 6,475,536, US 6,267,996, CN 1313124A, CN 93110425.4 and CN 1089497 A, whereby the disclosures of the application are incorporated herein by reference in it entirety. The pharmaceutical compositions of the invention may be prepared by persons of ordinary skill in the art using conventional methods. One embodiment of the invention includes a method for preparing an ointment comprising the following steps: 10 - heating a ointment base in a water bath at about 50°C until softened; - adding the softened ointment base in turn into a beaker containing the frozen dried Plectranthus amboinicus crude extract and/or extract; - adjusting the amount of the ointment base and the Plectranthus amboinicus crude extract and/or extract to make a Plectranthus amboinicus crude extract and/or extract ointment; and - storing the ointment at 4°C in a refrigerator. The content of the Plectranthus amboinicus crude extract is about 1 % to 15% by weight of the ointment. The content of the Plectranthus amboinicus extract is about 0.1% to 5% by weight of the ointment. Another embodiment of the invention includes a method for preparing an ointment comprising the following steps: - heating a ointment base in a water bath at about 50°C until softened; - adding the softened ointment base in turn into a beaker containing the frozen dried Plectranthus amboinicus crude extracts and/or extract to make a Plectranthus amboinicus crude extract and/or extract ointment; - homogenously mixing the Plectranthus amboinicus crude extract and/or extract ointment and the Centella asiatica Urban extract to make a Centella asiatica Urban extract and Plectranthus amboinicus crude extract and/or extract ointment; and storing the ointment at 4°C in a refrigerator. The content of the Plectranthus amboinicus crude extract is about 0.5% to about 5% by weight of the ointment and that of the Centella asiatica Urban extract is about 0.1% to about 20% by weight of the ointment. The content of the Plectranthus amboinicus extract is about 0.05% to about 2% by weight of the ointment and that of the Centella asiatica Urban extract is about 0.1% to about 20% by weight of the ointment. The weight ratio between the Plectranthus amboinicus crude extract and the Centella asiatica Urban extract is about 1:40 to about 1:4. The weight ratio between the Plectranthus amboinicus extract and the Centella asiatica Urban extract is about 1:60 to about 1:4. 11 According to the invention, the ointment containing the fourth Plectranthus amboinicus extract (PA-W4) prepared by the stirring separation method of the invention and that containing PA-W4 in combination with the Centella asiatica Urban extract show a greater efficacy in enhancing healing of wounds than the ointment comprising the Centella asiatica Urban extract alone, the ointment comprising the Plectranthus amboinicus extracts prepared by the traditional column chromatographic separation method in combination with the Centella asiatica Urban extract, or other conventional drugs for enhancing wound healing (shown in the examples below). The amounts of the fourth Plectranthus amboinicus extract and the Centella asiatica Urban extract in the ointment are about at least 0.01% and about at least 0.1% by weight, respectively. In an embodiment, the amount of the fourth Plectranthus amboinicus extract is about 0.01% to about 5%, or about 0.1 % to about 1 %, or about 0.25% to about 1 %, by weight of the ointment. The amount of the Centella asiatica Urban extract is about 0.1% to about 20%, or about 0.5% to about 9%, or about 1% to about 3%, by weight of the ointment. In an embodiment, the weight ratio between the fourth Plectranthus amboinicus extract and the Centella asiatica extract is about 1:60 to about 1:4. Utilities The pharmaceutical compositions of the invention can be used for treating disorders including but not limited to wounds and sores. In one embodiment, said disorders are general trauma and bedsores, or a diabetic patient's wound. Persons skilled in the art should have no difficulty choosing the suitable routes and the dosages for treatments. According to the invention, the route, for example, is topical administration. Dosage will depend on the nature and condition of the disorder, age and health condition of the patient, administration route and any previous treatment. Persons skilled in the art should know that dosage may vary depending on the individual's age, size, health condition and other related factors. The pharmaceutical compositions of the invention may be conveniently used for manufacturing a wound dressing comprising a therapeutically effective amount of the Plectranthus amboinicus crude extract and/or extract and optionally a therapeutically effective amount of the Centella asiatica Urban extract, wherein said wound dressing includes but is not limited to bandage with adhesive, plaster patch and the like. 12 The following examples are provided to aid those skilled in the art in practicing the invention. Even so, the examples should not be construed to unduly limit the invention as modifications to and variations on the embodiments discussed herein may be made by those having ordinary skill in the art without departing from the spirit or scope of the inventive discovery. EXAMPLES Materials A. Ointment base The ointment base (BETAMETHASONE ointment base) used in the examples is purchased from Sinphar, Taiwan. The ointment base is used for preparing the ointments comprising Centella asiatica Urban extract and/or Plectranthus amboinicus extracts as well as the placebo in the biological assays. B. CGS-21680 CGS-21680 (Sigma, batch number 093K4615) is a drug under clinical trials for healing wounds. 5mg of CGS-21680 were added into 500ml distilled water to prepare a 10\|xg/ml CGS-21680 solution. The CGS-21680 solution was used as a comparative drug in the examples. C. Regranex Regranex 0.01% gel contains becaplermin, a recombinant human platelet-derived growth factor (fh-PDGF-BB), at a concentration of 100 μg/g (0.01%). It is a FDA-approved prescription drug for the treatment of deep neuropathic diabetic foot ulcers. Regranex was used as a comparative drug in the examples. D. The Centella asiatica Urban extract and the ointment comprising the same The method for preparing the Centella asiatica Urban extracts and the active component in the pharmaceutical composition of the invention are well known to persons of ordinary skill in the art of herbal medicine extraction. The method comprises: - extracting Centella asiatica by ethanol reflux extraction for 2 hours, and repeating it 2 to 3 times; 13 - condensing the ethanol extract fluids to obtain the extracts; - retrieving the ethanol extracts, mixing and dissolving the extracts in water; - extracting with petroleum ether, chloroform, ethyl acetate separately, and then extracting with water-saturated n-butanol; retrieving the solvent of n-butanol extracts under reduced pressure to obtain a cream-like substance and dissolving the substance in a small amount of methanol; - adding anhydrous acetone, several-fold, to the solution, to precipitate a yellowish crude total glucoside, drying and weighing the sediments; - adding a small amount of methanol to dissolve the crude total glucoside, mixing properly with silica gel and drying the mixture; - wet column packing with silica gel for chromatography and loading the sample silica gel; - eluting with chloroform, methanol and water (16:6:1 homogenous mixture) and collecting 18 components in turn; each component is 50 ml and the components are thin-layer spotting to compare with known controls; - combining components 9 to 15, concentrating, and then purifying with column using chloroform, methanol and water (14:6:1 homogenous mixture) for elution; and - concentrating the same components and crystallizing with methanol repeatedly to obtain the white aciculate crystalline asiaticoside. Furthermore, the drug substance of Centella asiatica Urban extracts containing asiaticoside and madecassic acid, with a purity greater than 70%, is available on the market. The commercial product CENTELLA ASIATICA PURIFIED EXTRACT can be purchased from NuLiv Science, Inc., Taiwan. 1% Centella asiatica Urban extract (SI) ointment was prepared as follows: - heating the ointment base in a water bath at about 50°C until softened; mixing 99g of the softened ointment base with lg of Centella asiatica Urban extract (SI); - storing the ointment at 4°C in a refrigerator. 14 The 1% SI ointment was used in the examples as a comparative drug. E. The Plectranthus amboinicus extracts The Plectranthus amboinicus extracts used in the biological assays were prepared by the preparation process of the invention (the stirring separation method) and a column chromatographic separation method. The details of the preparation are described in the following preparation examples. Example 1. Preparation of Plectranthus amboinicus Extracts by Stirring Separation Method 800g of dried Plectranthus amboinicus leaves was dipped in a 95% alcohol having a volume ten-fold to the total weight of the dried leaves for 72 hours, and then the leaf extract was filtrated. The extraction procedure was repeated. The two leaf extracts were mixed to obtain a Plectranthus amboinicus crude extract and the crude extract was concentrated by a pressure-reducing rotary evaporator (Heidolph LABOROTA 4000, Eleya N-N series) to reduce the volume of the crude extract to about 5% of the original volume (i.e., to about one-half of the original weight of dried leaves). The Plectranthus amboinicus crude extract was diluted with a high-polarity solvent to a volume ten-fold to the original one. The diluted Plectranthus amboinicus crude extract was added into a bucket-like container containing DIAION® HP20 resin which was pre-treated by using methanol. The resin and the extract in the container were stirred at a speed of 3 to 10 rpm overnight. The fluid was then poured from the container. Double distilled water having a volume five-fold to the total weight of the dry leaves was added to the container. The resin was dipped in the water by stirring once in a while for one hour and the fluid was collected. The collected fluid (PA-W1) was concentrated and dried to obtain 2.4g of dried product with a yield of 0.3%. A sub-high-polarity solvent having a volume five-fold to the total weight of the dry leaves was further added to the container with the resin. The resin was dipped in the solvent by stirring once in a while for one hour and the fluid was collected. The process was repeated twice. The extracted fluids were mixed (PA-W2) and then concentrated and dried to obtain 4g of dried product with a yield of 0.5%. 15 A medium-polarity solvent having a volume five-fold to the total weight of the dry leaves was further added to the container with the resin. The resin was dipped in the solvent by stirring once in a while for one hour and the fluid was collected. The process was repeated twice. The extracted fluids were mixed (PA-W3) and then concentrated and dried to obtain 6g of dried product with a yield of 0.75%. A low-polarity solvent having a volume five-fold to the total weight of the dry leaves was further added to the container with the resin. The resin was dipped in the solvent by stirring once in a while for one hour and the fluid was collected. The process was repeated three times. The extracted fluids were mixed (PA-W4) and then concentrated and dried to obtain 7.52g of dried product with a yield of 0.94%. Example 2. Preparation of Plectranthus amboinicus Extracts by Column Chromatographic Separation Method DIAION resin having a weight identical to that of the dried Plectranthus amboinicus leaves was dipped in methanol and packed into a chromatographic column. The packed DIAION resin was then washed with methanol having a volume one- to two-fold to the total weight of the DIAION resin, and subsequently washed with double distilled water having a volume five- to six-fold to the total weight of the DIAION resin. 800g of dried Plectranthus amboinicus leaves was dipped in 95% alcohol having a volume ten-fold to the total weight of the dried leaves for 24 hours. After filtration, the leaves were further dipped in 95% alcohol having a volume ten-fold to the total weight of the dried leaves for 24 hours. The Plectranthus amboinicus extract fluids were mixed and concentrated by a pressure-reducing rotary evaporator to reduce the volume to about 2-3% of the original volume. The extract obtained from the preceding steps was diluted with distilled water and loaded into the DIAION resin column. The column was eluted with a high-polarity solvent having a volume ten-fold to the total weight of the dried leaves. An eluted fraction (PA-C1) was collected and the yield was 0.38%. 16 The column was then eluted with a sub-high-polarity solvent having a volume five- to ten-fold to the total weight of the dried leaves. An eluted fraction (PA-C2) was collected and the yield was 0.5%. The column was eluted again with a medium-polarity solvent having a volume five- to ten-fold to the total weight of the dried leaves. An eluted fraction (PA-C3) was collected and the yield was 0.78%. Finally, the column was eluted with a low-polarity solvent having a volume five- to ten-fold to the total weight of the dried leaves. An eluted fraction (PA-C4) was collected and the yield was 0.67%. Example 3. Composition analysis of the Plectranthus amboinicus extracts Instruments and equipments High Performance Liquid Chromatography (HPLC) Spectra System,Thermo Pump: Spectra-Physics P4000 Detector: UV/VIS Spectra-PhysicsSpectraSystem UV600OLP Auto sampler: Thermo Separation Products AS3500 Software: Thermo Separation Products ChromQuest System Controller: Thermo Separation Products SN4000 Conditions for Liquid Phase HPLC Chromatographic column: Phenomenex, 4.6x250nm, Luna 5μ silica(2) Flow rate: 1.0 ml/min Pressure Limit: 250 kgf/cm2 Sample amount: 10 μl PDA conditions: Sampling period: 0.64 sec Wavelength range: 190-370 run Channels: 270, 320 ran Elution Profile: Time (min) Mobile phase 0 15 45 50 n-hexane 95% 85% 30% 95% Ethyl acetate 5% 15% 70% 5% 17 The chromatographic spectrum of the PA-W4 extract obtained by stirring separation and that of the PA-C4 extract obtained by column chromatographic separation are shown in Figures 1 and 2, respectively. The PA-W4 has HPLC peaks at the following retention time: Peak Retention time (min) 1 5.5 2 9.6 3 20.0 4 22.5 5 23.5 6 24.8 7 27.7 8 27.8 9 28.6 10 28.9 11 29.7 12 31.0 13 31.9 14 36.6 15 37.8 Example 4. Preparation of Ointments Comprising Plectranthus amboinicus Extracts and Ointments Comprising Centella asiatica Urban Extract (SI) and Plectranthus amboinicus Extracts. Suitable amounts of ointment base, PA-W4 extract and PA-C4 extract were measured. The ointment base was preheated in a water bath at about 50C until softened and added into beakers containing the PA-W4 extract and the PA-C4 extract to obtain a 0.25% PA-W4 ointments and a 0.25% PA-C4 ointment. The weight ratio of the ointment base to the Plectranthus amboinicus extracts was 99.75:0.25. The obtained ointments were then mixed with Centella asiatica Urban extract (SI) in a weight ratio of 99:1 to obtain a DCR-WH1-W ointment (1% SI + 0.25% PA-W4) and a DCR-WH1-C ointment (1% SI + 0.25% PA-C4). 18 Biological Assays Example 5. Animal Experiments for Wound Closures in Diabetic Rats [Animal experiments] Induction of high blood sugar in the animals Rats with a body weight of over 300g were administered with Streptozotocin (STZ, 65 mg/kg, i.p.) to induce high blood sugar. Rats with successfully induced high blood sugar (over 300mg/DL) were selected to conduct the wound closure tests two months after high-blood-sugar syndromes appeared. Trauma surgeries for the diabetic animals i. The high-blood-sugar animals with a body weight of lower than 300g were eliminated and the rest were randomized into 6 groups, ii. The animals were anesthetized with pentobarbital and the hair on the surgical area (dorsal area) was removed. The surgical areas and instruments were then sterilized with 75% alcohol before operation. iii. The skins on the dorsal medium areas (4, 6 and 8 cm from the midpoint of two scapula) were excised (full thickness) using a round cutting blade with a diameter of 1 cm. Measuring the wounds, applying testing materials, and preventing the wounds from being scratched i. A standard ruler was placed beside the wounds and pictures were taken, ii. A thin layer of the test materials formulated as ointments and 0.05 ml of CGS21680 solution were applied to each wound, iii. The wounds were covered with gauze and hoods were worn on the rats' necks. Test materials were applied to the rats twice a day (morning and evening) and the wounds were measured at each time point. 19 After the experiments were finished, the regenerated skins were taken for biochemistry and histology analysis. [Wound area analysis] A standard ruler was placed beside the wounds when pictures were taken. The length of the wounds was standardized according to the scale of the standard ruler in the pictures before the wounds were analyzed with the image processing software Image-Pro (Media Cybernetics, Inc.) to avoid the errors caused by different picturing distances. [Data analysis and statistics] The areas of the three wounds on the rats' backs were analyzed by Image-Pro. The wound areas of day zero were the original wound areas. The original wound areas minus the wound areas at different time points were divided by the original wound areas to get the wound closure percentages. The mean of the three wound closure percentages of each rat represents the wound closure of each rat. Four to seven rats per group were used for each test materials. The data was shown as mean ± standard error (SEM). The p-values of the test results were calculated by t-test in statistics software sigma statis (Systat software Inc.). P charts or tables. P on the statistics charts or tables. P difference, and it is marked with * on the statistics charts or tables. Example 6. Comparison of the Efficacies of 1% SI, CGS-21680, Regranex, DCB-WH1-C and DCB-WH1-W on Wound Closures in STZ-Induced Diabetic Rats The purpose of this example is to compare the efficacy of the composition of the invention and that of the commercially available products on wound closures. The wound closure animal experiments were conducted according to Example 5. On day 0, 4, 6, 8, 10 and 12 after the treatments of placebo (Group 1), 1% SI ointment (Group 2), CGS-21680 (Group 3), Regranex (Group 4), DCB-WH1-C (Group 5) and DCB-WH1-W (Group 6), the wound areas of all experimental groups were measured and the wound closure percentages and CT50 (time required for 50% wound closure) values were calculated. The results are 20 shown in Figure 3 and Table 1. The P-values of the paired comparison of wound closure percentages of the experimental groups are shown in Table 2. Table 1 Wound closure percentages and CT50 of the experimental groups treated with placebo, 1% SI ointment, CGS21680, Regranex, DCB-WH1-C and DCB-WH1-W Groups Test materials Wound closure percentage (%) CT50 (day) Day 4 Day 6 Day 8 Day 10 DAY 12 1 Placebo -99.6±13.3 -107.6±10.5 -45.14±13 19.9±5.3 61.5±3.1 11.4 2 1% SI -62.7±6.0 -51.4±6.0 -18.2±9.7 45.2±5.9 77.7±2.3 10.3 3 CGS-2168 -21.3±4.8 -27.3 8±3.2 -2.4±4.1 46.7±6.0 71.7±2.4 10.3 4 Regranex -21.0±l 0.4 2.7±8.1 1.46±6.7 59.9±2.6 78.0±4.8 9.7 5 DCB-WH1-C -19.2±7.0 -13.6±6.7 18.3±6.6 59.9±2.9 84.8±3.0 9.5 6 DCB-WH1-W 4.1±2.9 22.3±2.7 56.0±2.5 84.5±1.8 93.9±0.7 7.65 Table 2 The P-values of the paired comparison of wound closure percentages of the experimental groups Day Group vs. Group P-values 4 2 3 0.000289 * 4 2 4 0.0054565 4 2 5 0.0004544 * 4 2 6 0.000001203 * 4 3 4 0.9788 4 3 5 0.5697 4 3 6 0.00075098 *** 4 4 5 0.7119 4 4 6 0.0276 * 4 5 6 0.0157 * 6 2 3 0.0055961 6 2 4 0.00039598 * 6 2 5 0.001875 6 2 6 0.0000005765 * 6 3 4 0.0049146 6 3 5 0.0947 6 3 6 0.000000339 * 6 4 5 0.1504 6 4 6 0.0356 6 5 6 0.0005663 *** 8 2 3 0.1659 8 2 4 0.1454 8 2 5 0.0113 * 21 8 2 6 0.000023634 *** 8 3 4 0.62 8 3 5 0.0238 * 8 3 6 0.0000002486 * 8 4 5 0.1087 8 4 6 0.000016991 * 8 5 6 0.00031843 * 10 2 3 0.8675 10 2 4 0.0954 10 2 5 0.0509 10 2 6 0.000084357 * 10 3 4 0.1274 10 3 5 0.0740 10 3 6 0.00011665 * 10 4 5 0.9934 10 4 6 0.000055221 * 10 5 6 0.000026694 * On day 4, the wound closure percentages of Groups 3,4, 5 or 6 are significantly higher than those of Groups 1 and 2 (P significantly higher than those of Groups 3, 4 and 5 (P closure percentages of Groups 3, 4, 5 and 6 are significantly higher than those of Groups 1 and 2 (P even significantly higher than those of Group 3,4 or 5 (P wound closure percentages of Groups 5 and 6 are significantly higher than those of Groups 2 (P those of Groups 3, 4 and 5 (P 6 is significantly higher than those of other groups (P are 11.4,10.3, 10.36, 9.4, 9.5 and 7.65 days, respectively. In summary, the DCB-WH1-W ointment of the invention has a superior efficacy over other test materials, i.e., ointment base, 1% SI ointment, CGS21680, Regranex and DCB-WH1-C. Example 7. Comparison of the Efficacies of 1 % S1, 0.25% PA-W4. DCB-WH1 -W and 1% PA-W4 on Wound Closures in STZ-Induced Diabetic Rats The purpose of this example is to compare the efficacy of DCB-WH1-W with that of its active ingredients in wound closures. The test materials are placebo (Group 1), 1% SI ointment (Group 2), 0.25% PA-W4 ointment (Group 3), DCB-WH1-W (Group 4) and 1% 22 PA-W4 ointment (Group 5). The wound closure animal experiments were conducted according to Example 5. On day 0, 4, 9, 11 and 13 after the treatment with the test materials, the wound areas of all experimental groups were measured and the wound closure percentages and CT50 were calculated. The results are shown in Figure 4 and Table 3. The P-values of the paired comparison of wound closure percentages of the experimental groups are shown in Table 4. Table 3 Wound closure percentages and CT50 of the experimental groups treated with placebo, 1% SI ointment, 0.25% PA-W4 ointment, DCB-WH1-W and 1% PA-W4 ointment Groups Test materials Wound closure percentage (%) CT50 (day) Day 4 Day 9 Day 11 Day 13 1 Placebo -65.07±9.5 -19.6±13.4 35.7±11.1 79.8±4.9 11.7 2 1% SI -62.55±8.9 16.8±7.5 59.1±5.1 93.2±1.7 10.6 3 0.25% PA-W4 -46.1±13.8 29.9±9.8 77.9±2.3 95.2±1.0 9.9 4 DCB-WH1-W -3.51±1.7 59.7±6.6 87.9±3.1 97.42±1.0 8.25 5 1%PA-W4 -16.5±10.9 62.2±7.4 88.45±3.3 98.59±0.8 8.25 Table 4 The P-values of the paired comparison of wound closure percentages of the experimental groups Day Group vs. Group P-values 4 1 2 0.8505 4 1 3 0.2822 4 1 4 0.0001 * 4 1 5 0.0047 4 2 3 0.3391 4 2 4 0.0001 * 4 2 5 0.0052 4 3 4 0.0094 4 3 5 0.1015 4 4 5 0.1874 9 1 2 0.0714 9 1 3 0.0239 * 9 1 4 0.0004 * 9 1 5 0.0009 * 9 2 3 0.3126 9 2 4 0.0010 9 2 5 0.0015 9 3 4 0.0173 * 9 3 5 0.0274 * 9 4 5 0.8053 23 11 1 2 0.0847 11 1 3 0.0041 11 1 4 0.0008 * 11 1 5 0.0024 11 2 3 0.0075 11 2 4 0.0003 * 11 2 5 0.0012 11 3 4 0.0073 ** 11 3 5 0.0201 * 11 4 5 0.5970 13 1 2 0.0271 * 13 1 3 0.0117 13 1 4 0.0092 13 1 5 0.0072 13 2 3 0.3247 13 2 4 0.0444 * 13 2 5 0.0199 * 13 3 4 0.0800 13 3 5 0.0214 * 13 4 5 0.5622 On day 4, the wound closure percentages of Groups 4 or 5 are significantly higher than those of Groups 1 and 2 (P and 5 are significantly higher than those of Group 1 (P Group 3 (P than that of Group 1 (P and 5 are significantly higher than that of Group 2 (P percentages of Groups 4 and 5 are significantly higher than that of Group 3 (P day 13, the wound closure percentage of Groups 4 and 5 are significantly higher than those of Group 1 (P is significantly higher than that of Group 3 (P between Groups 4 and 5 on days 4, 9, 11 and 13. The CT50 for Groups 1 to 5 are 11.7, 10.6, 9.9, 8.25 and 8.25 days, respectively. In summary, the efficacy of the ointment comprising 1% PA-W4 (1% PA-W4 ointment) on wound closures is equivalent to that of the DCB-WH1-W (1% Sl+0.25% PA-W4) ointment. The 1% PA-W4 and DCB-WH1-W ointments of the present invention have a superior efficacy over the ointment base, the 1% SI ointment and the 0.25% PA-W4 ointment. 24 WE CLAIM; 1. A process for preparing Plectranthus amboinicus extracts comprising the step of: a) contacting dried Plectranthus amboinicus leaves with a leaf extracting solvent to obtain a Plectranthus amboinicus crude extract; b) concentrating the Plectranthus amboinicus crude extract; and c) separating the concentrated Plectranthus amboinicus crude extract by stirring to obtain a Plectranthus amboinicus extract. 2. The process according to Claim 1, wherein the leaf extracting solvent comprises water or alcohol. 3. The process according to Claim 1, wherein the concentrated Plectranthus amboinicus crude extract is separated by a stirring separation method. 4. The process according to Claim 3, wherein the stirring separation method comprises the steps of: (a) diluting the concentrated Plectranthus amboinicus crude extract with a high-polarity solvent; (b) mixing the diluted Plectranthus amboinicus crude extract with an absorbing resin; (c) stirring the absorbing resin with the diluted Plectranthus amboinicus crude extract; (d) after removing liquid portion, extracting the resin with the high-polarity solvent, and collecting a first extract; (e) extracting the resin with a sub-high-polarity solvent and collecting a second extract; (f) extracting the resin with a medium-polarity solvent and collecting a third extract; and (g) extracting the resin with a low-polarity solvent and collecting a fourth extract. 5. The process according to Claim 4, wherein the high-polarity solvent comprises water, methanol, ethanol, or mixture thereof. 25 6. The process according to Claim 4, wherein the sub-high-polarity solvent has a polarity lower than that of the high-polarity solvent. 7. The process according to Claim 4, wherein the medium-polarity solvent has a polarity lower than that of the sub-high-polarity solvent. 8. The process according to Claim 4, wherein the low-polarity solvent has a polarity lower than that of the medium-polarity solvent. 9. A Plectranthus amboinicus extract prepared by the process according to Claim 4, containing one or more extracts selected from the first, second, third and fourth extracts. 10. The Plectranthus amboinicus extract according to Claim 9, wherein the fourth extract has the following HPLC peaks of retention time: Peak Retention time (min) 1 5.5 2 9.6 3 20.0 4 22.5 5 23.5 6 24.8 7 27.7 8 27.8 9 28.6 10 28.9 11 29.7 12 31.0 13 31.9 14 36.6 15 37.8 wherein said HPLC is conducted in the following conditions: Chromatographic column: Phenomenex, 4.6x250mm, Luna 5(0, silica(2) Flow rate: 1 .0ml/min Pressure Limit: 250 kgf/cm2 Sample amount: 10 μl PDA condition: Sampling period: 0.64 sec Wavelength range: 190-370 nm Channel: 270, 320 nm 26 Elution Profile: Time (min) Mobile phase 0 15 45 50 n-hexane 95% 85% 30% 95% Ethyl acetate 5% 15% 70% 5% 11. A Plectranthus amboinicus crude extract prepared by step a) and/or b) of the process according to Claim 1. 12. A pharmaceutical composition comprising a therapeutically effective amount of the Plectranthus amboinicus extract according to Claim 9 or 10 and optionally a pharmaceutically acceptable carrier, diluent or excipient. 13. The pharmaceutical composition according to Claim 12, further comprising a therapeutically effective amount of Centella asiatica Urban extract. 14. The pharmaceutical composition according to Claim 13, wherein the Plectranthus amboinicus extract and the Centella asiatica Urban extract have a weight ratio of about 1:60 to about 1:4. 15. A pharmaceutical composition comprising a therapeutically effective amount of the Plectranthus amboinicus crude extract according to Claim 11 and optionally a pharmaceutically acceptable carrier, diluent or excipient. 16. The pharmaceutical composition according to Claim 15, further comprising a therapeutically effective amount of Centella asiatica Urban extract. 17. A wound dressing comprising a pharmaceutical composition according to any one of Claims 12 to 16. 18. A use of the pharmaceutical composition of any one of Claims 12 to 16 in the manufacture of a medicament for treating skin disorder. 27 19. The use according to Claim 18, wherein the skin disorder is general trauma or bedsores. 20. The use according to Claim 18, wherein the skin disorder is wounds in a diabetic patient. The invention provides a process for the preparation of Plectranthus amboinicus extracts using a stirring separation method. The invention also provides a pharmaceutical composition comprising the Plectranthus amboinicus crude extract and/or extract for treating skin disorders, including enhancing the healing of wounds, especially in diabetic patients.

Full Text

FIELD OF THE INVENTION
The invention relates to a process for the preparation of Chinese herbal medicine extracts.
Specifically, the invention relates to the use of a solid-liquid separation in combination
with a specific treatment for mass production of a plant extract for treating skin disorders,
including enhancing the healing of wounds, especially in diabetic patients.
BACKGROUND OF THE INVENTION
Plectranthus amboinicus (Lour.) Spreng, growing in Malaysia and India, is a decorative
medicinal herb commonly cultivated by ordinary families. The medicinal part of
Plectranthus amboinicus is the epigeal portion. Plectranthus amboinicus is also known as
Cuban oregano, Indian borage, Indian mint, Mexican mint, Mexican oregano or Spanish
thyme. East Indians use Plectranthus amboinicus as a fabric aromatic, and the English
discovered its attractive fragrance when importing shawl fabrics from India in the 1820's.
When the Plectranthus amboinicus leaves are put directly with clothing, it not only has an
aromatic effect, but also prevents the clothing from being eaten by moths. It is thought to
be useful for disinfection, enhancing sexual excitement and preventing insect bites. In
addition, Plectranthus amboinicus may be used for treating poisonous snake bites and
relieving symptoms such as headache, flatulence, vomiting, diarrhea and fever. Moreover,
Plectranthus amboinicus oil is a popular perfume in Asia, and it is used in aromatherapy
for improving epithelia regeneration, treating acne, and relieving the symptoms of eczema,
Athlete's foot and dry cracked skin. Furthermore, Plectranthus amboinicus is a good
tranquilizer and aphrodisiac that can relieve anxiety and enhance sexual desire.
Various uses of Plectranthus amboinicus are reported in general magazines, but scientific
studies on Plectranthus amboinicus are rarely seen in literature. US 2006/0099283 Al
discloses leaf juice of Plectranthus amboinicus for treating cancer and/or tumor. USSN
11/605,178, a patent application relating to the present invention, provides a
pharmaceutical composition comprising a therapeutically effective amount of Plectranthus
amboinicus crude extracts/extracts and a therapeutically effective amount of Centella
asiatica Urban extracts.
Centella asiatica Urban (pennywort) is a plant naturally growing in the coastal areas of
Madagascar and the Indian Ocean. The medicinal part of Centella asiatica Urban of the
2

Apiaceae family is its dried whole plant. Centella asiatica Urban is also known as
European water-marvel, Gotu kola, Kola, Indian pennywort, Indian ginseng, Horse-hoof
grass, Pegaga, Mandookaparni, Tiger herbal, Spadeleaf, or Tono. For hundreds of years,
Centella asiatica Urban has been thought to be useful in the traditional medicine of Asia
for improving wound healing. The extracts of Centella asiatica Urban comprise two
major compounds: asiaticoside and madecassic acid. Centella asiatica Urban extracts are
used to treat burns and trauma and prevent postoperative adhesion, and the preparation
methods of Centella asiatica Urban extracts have been described in some patent
applications. For example, US 4,318,906 and CN 1353972A disclose the medical uses of
Centella asiatica Urban as the single active ingredient; US 6,475,536, US 6,267,996, CN
1313124A, CN 93110425.4 and CN 1089497A disclose the use of Centella asiatica Urban
in combination with other substances for cosmetic formulation, treating burns or making
ointment for trauma; and US 5,834,437, US 6,417,349 and CN 1194154A disclose the
methods for preparing Centella asiatica Urban extracts.
Conventional separation processes for separating the components from the mixture include
contacting the mixture with a nonionic absorbing resin such as DIAION® HP20, DIAION®
HP20SS, Sepabeads® SP207 (Mitsubishi Chemical Corporation), Amberlite™ XAD-2
(Rohm and Hass company), Amberlite™ XAD-4, and the like. The steps comprise
packing the nonionic absorbing resin into a separation column, adding the mixture to the
column, and eluting the column with a solvent. When such process is taken to treat a
massive amount of a mixture, it is time-consuming and the elution conditions are not easily
controlled.
The leaf juice of US 2006/0099283 Al was obtained by grinding and removing tissue
fragments and/or residues, and the different fractions of the leaf juice were separated with
centrifugal filter devices.
The Plectranthus amboinicus extracts of USSN 11/605,178 were prepared by utilizing a
series of solvents with different polarities to elute the extracts from a chromatographic
column. This method is complicated and time-consuming. There is still a need to
provide a method for obtaining in large quantities the active ingredients of Plectranthus
amboinicus.
3

Surprisingly, we found that a stirring method can replace the traditional column separation
method and be used for mass production of Plectranthus amboinicus extracts. The
stirring method is fast and the elution conditions can be easily controlled. Moreover,
Plectranthus amboinicus extracts obtained by stirring separation are more effective than
extracts prepared by column chromatographic separation.
SUMMARY OF THE INVENTION
One embodiment of the invention provides a process for preparing Plectranthus
amboinicus crude extract and/or extracts.
One embodiment of the invention provides a pharmaceutical composition for treating skin
disorders (including enhancing the healing of wounds in diabetic patients), comprising a
therapeutically effective amount of Plectranthus amboinicus crude extracts and/or extracts.
The pharmaceutical composition may further comprise a therapeutically effective amount
of Centella asiatica Urban extracts.
One embodiment of the invention provides a wound dressing comprising the
pharmaceutical composition of the invention.
One embodiment of the invention provides a method for treating skin disorder comprising
administering the pharmaceutical composition of the invention.
The invention is described in detail in the following sections. Other characterizations,
purposes and advantages of the invention can be easily found in the detailed descriptions
and claims of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 shows the chromatographic spectrum of the Plectranthus amboinicus extract
(PA-W4) prepared by stirring separation. The spectrum was determined by Reverse
Phase HPLC at UV 270nm.
Figure 2 shows the chromatographic spectrum of the Plectranthus amboinicus extract
(PA-C4) prepared by column chromatographic separation. The spectrum was determined
by Reverse Phase HPLC at UV 270nm.
4

Figure 3 shows wound closures in STZ-induced diabetic rats. Group 1: wound applied
with placebo (ointment without medicament); Group 2: wound applied with ointment
containing 1% Centella asiatica Urban extracts (SI); Group 3: wound applied with
CGS-21680 (10fxg/ml); Group 4: wound applied with Regranex; Group 5: wound applied
with DCB-WH1-C (ointment comprising 1% SI and 0.25% PA-C4); Group 6: wound
applied with DCB-WH1-W (ointment comprising 1% SI and 0.25% PA-W4).
Figure 4 shows wound closures in STZ-induced diabetic rats. Group 1: wound applied
with placebo (ointment without medicament); Group 2: wound applied with ointment
containing 1% Centella asiatica Urban extracts (SI); Group 3: wound applied with
ointment containing 0.25% PA-W4; Group 4: wound applied with DCB-WH1-W
(ointment comprising 1% SI and 0.25% PA-W4); Group 5: wound applied with ointment
containing 1%PA-W4.
DETAILED DESCRIPTION OF THE INVENTION
Unless otherwise defined herein, scientific and technical terms used in connection with the
present invention shall have the meanings that are commonly understood by those of
ordinary skill in the art. The meaning and scope of the terms should be clear; however, in
the event of any latent ambiguity, definitions provided herein take precedence over any
dictionary or extrinsic definition.
As utilized in accordance with the present disclosure, the following terms, unless otherwise
indicated, shall be understood to have the following meanings:
The term "skin disorders" as used herein includes wounds or sores. In one embodiment,
skin disorders include cuts, lacerations, abrasions, stabs or other similar skin injuries, or a
diabetic patient's wounds; sores include bedsores.
The term "treating" or "enhancing" as used herein denotes improving the symptoms.
The term "patients" as used herein denotes animals, especially mammals. In one
embodiment, the term "patients" denotes "humans."
5

The term "therapeutically effective amount" as used herein refers to the amount of the
pharmaceutical composition used alone or in combination with other medicaments for
treating disorders that shows therapeutic efficacy.
The term "carrier" or "pharmaceutically acceptable carrier" refers to diluents, excipients,
acceptors or analogues, which are well known to persons of ordinary skill in the art for
manufacturing pharmaceutical compositions.
The term "Centella asiatica Urban extracts" denotes extracts of dried Centella asiatica
Urban whole plants, wherein the major active components comprise asiaticoside and
madecassic acid. In an embodiment, it is the medicinal part available on the market that
mainly comprises asiaticoside and madecassic acid, and its purity is greater than 70%.
The term "Plectranthus amboinicus crude extract" denotes an extract obtained from the
epigeal portion of Plectranthus amboinicus, and the crude extract may be further
concentrated.
The term "Plectranthus amboinicus extract" denotes an extract obtained from the crude
extract by further separation(s).
The term "high-polarity solvent" denotes a solvent that has the highest polarity in the
solvents used in the preparation process. The high-polarity solvent includes, but is not
limited to, water, methanol, ethanol or a mixture of two or more of the preceding solvents.
The term "low-polarity solvent" denotes a solvent that has the lowest polarity in the
solvents used in the preparation process. The low-polarity solvent includes, but is not
limited to, chloroform, isopropanol, acetone, ethyl acetate, a mixture of two or more of the
preceding solvents, or a mixture of one or more of the preceding solvents with one or more
solvent that have higher polarity.
The term "sub-high-polarity solvent" denotes a solvent that has a polarity lower than that of
the high-polarity solvent used in the preparation process but higher than that of the
medium-polarity solvent used in the preparation process. The sub-high-polarity solvents
can be obtained by mixing a high-polarity solvent with a solvent having lower polarity in a
ratio (v:v) of about 30:70 to about 70:30, or about 60:40 to about 40:60.
6

The term "medium-polarity solvent" denotes a solvent that has a polarity lower than that of
the sub-high-polarity solvent used in the preparation process but higher than that of the
low-polarity solvent used in the preparation process. The medium-polarity solvents can
be obtained by mixing a high-polarity solvent with a solvent having lower polarity in a
ratio (v:v) of about 30:70 to about 5:95, or about 15:85 to about 5:95.
Unless otherwise required by context, singular terms shall include the plural and plural
terms shall include the singular.
The Preparation Processes
The invention is characterized by using solid-liquid separation (stirring separation) in
combination with a specific treatment for mass production of Plectranthus amboinicus
extracts in a faster manner with a higher yield. The stirring separation comprises stirring
an absorbing resin, such as DIAION, into the Plectranthus amboinicus extract and
separating the different fractions from the Plectranthus amboinicus extracts by differential
separation steps with the utilization of different solvents. In addition to higher throughput,
the Plectranthus amboinicus extract obtained by the process of the invention is more
effective than that prepared by the column chromatographic separation method.
The process of the invention for preparing Plectranthus amboinicus extracts comprises the
steps of:
- contacting the dried Plectranthus amboinicus leaves with a leaf extracting
solvent to obtain a Plectranthus amboinicus crude extract;
concentrating the Plectranthus amboinicus crude extract; and
- treating the concentrated Plectranthus amboinicus crude extract using a
stirring separation method to obtain a Plectranthus amboinicus extract.
According to the invention, the stirring separation method comprises the following steps:
(a) diluting the concentrated Plectranthus amboinicus crude extract with a
high-polarity solvent, mixing the diluted Plectranthus amboinicus crude
extract with an absorbing resin, and stirring the absorbing resin and the
diluted Plectranthus amboinicus crude extract;
7

(b) removing the liquid portion, extracting the resin with distilled water, and
collecting the first extract;
(c) extracting the resin with a sub-high-polarity solvent and collecting the second
extract;
(d) extracting the resin with a medium-polarity solvent and collecting the third
extract; and
(e) extracting the resin with a low-polarity solvent and collecting the fourth
extract.
In one embodiment, the process for preparing Plectranthus amboinicus extracts comprises
the steps of:
1. contacting dried Plectranthus amboinicus leaves with a leaf extracting solvent
for about 30 to about 100 hours to obtain a Plectranthus amboinicus crude
extract;
2. concentrating the Plectranthus amboinicus crude extract;
3. diluting the concentrated Plectranthus amboinicus crude extract with a
high-polarity solvent and mixing the diluted Plectranthus amboinicus crude
extract with an absorbing resin by stirring for about 10 to about 30 hours;
4. removing the liquid portion;
5. dipping the resin in distilled water for about 1 to about 7 hours to obtain a first
extract (PA-W1);
6. mixing and stirring the resin with a sub-high-polarity solvent for about 1 to about
7 hours to obtain a second extract (PA-W2);
7. mixing and stirring the resin with a medium-polarity solvent for about 1 to about
7 hours to obtain a third extract (PA-W3);
8. mixing and stirring the resin with a low-polarity solvent for about 1 to about 7
hours to obtain a fourth extract (PA-W4).
According to the process of the invention, the leaf extracting solvent is selected from, but
not limited to, water and alcohols. In one embodiment, the alcohol is ethanol. The ratio
of the volume of the leaf extracting solvent to the weight of the dried Plectranthus
amboinicus leaves is about 6:1 to about 15:1, or about 10:1.
8

According to the process of the invention, the leaf extract obtained in step 1 may be
concentrated by any conventional concentration methods for solutions, such as using a
pressure-reducing rotary evaporator.
According to the process of the invention, the absorbing resin is selected from, but not
limited to, DIAION® HP20, DIAION® HP20SS, Sepabeads® SP207, Amberlite™ XAD-2,
Amberlite™ XAD-4, and the like, or the DIAION® series. In one embodiment, the
absorbing resin is DIAION® HP20. In addition, the DIAION®HP20 resin can be
pre-treated with methanol.
According to the process of the invention, the ratio of the volume of the high-polarity
solvent to the weight of the dried Plectranthus amboinicus leaves is about 8:1 to about 4:1,
or about 5:1; the ratio of the volume of the sub-high-polarity solvent to the weight of the
dried Plectranthus amboinicus leaves is about 8:1 to about 4:1, or about 5:1; the ratio of the
volume of the medium-polarity solvent to the weight of the dried Plectranthus amboinicus
leaves is about 8:1 to about 4:1, or about 5:1; and the ratio of the volume of the
low-polarity solvent to the weight of the dried Plectranthus amboinicus leaves is about 8:1
to about 4:1, or about 5:1.
According to the process of the invention, the extraction period of step 1 is about 30 to
about 100 hours, or about 50 to about 80 hours, or more than about 72 hours. The
absorption period of step 3 is about 10 to about 30 hours, or about 17 to about 25 hours, or
more than about 20 hours. The extraction period of step 5 is about 1 to about 7 hours, or
about 1 to about 4 hours, or about 1 hour. The extraction period of step 6 is about 1 to
about 7 hours, or about 1 to about 4 hours, or about 1 hour. The extraction period of step 7
is about 1 to about 7 hours, or about 1 to about 4 hours, or about 1 hour. The extraction
period of step 8 is about 1 to about 7 hours, or about 1 to about 4 hours, or about 1 hour.
Furthermore, according to the process of the invention, stirring is conducted at the speed of
about 3 to about 15 rpm, or about 5 to about 10 rpm, or 7 rpm.
The process of the invention is a high-throughput method for mass production of
Plectranthus amboinicus extracts. The process is about five times faster than the column
chromatographic separation method to extract the active fractions from Plectranthus
amboinicus.
9

Pharmaceutical Compositions
One embodiment of the invention provides a pharmaceutical composition comprising a
therapeutically effective amount of Plectranthus amboinicus crude extract and/or extract
prepared by the separation process of the invention. Another embodiment of the invention
provides a pharmaceutical composition comprising a therapeutically effective amount of
Plectranthus amboinicus crude extract and/or extract prepared by the separation process of
the invention in combination with a therapeutically effective amount of Centella asiatica
Urban extract.
The pharmaceutical composition of the invention can be applied topically to the wounds,
and it may be formulated as spray or non-spray. A spray form includes spray or solution;
a non-spray form may be semi-solid or solid, or a solid form having a kinematic viscosity
greater than water. Suitable formulations include but are not limited to suspensions,
emulsions, creams, ointments, liniments and the like. If necessary, it may be sterilized or
mixed with any pharmaceutically acceptable carriers, such as stabilizers, wetting agents
and the like. In an embodiment, the pharmaceutical composition of the invention is
formulated as ointments, wherein the pharmaceutically acceptable carriers include but are
not limited to higher fatty acids, waxes, lipids, glycerol, higher alcohols or synthetic lipids.
The pharmaceutical composition of the invention, no matter which form it is formulated in,
may further comprise emollients, fragrances or colorings to increase the acceptability for
various uses.
The therapeutically effective amounts of the Plectranthus amboinicus crude extract and/or
extract and the Centella asiatica Urban extract are disclosed in USSN 11/605,178, US
4,318,906, CN 1353972A, US 6,475,536, US 6,267,996, CN 1313124A, CN 93110425.4
and CN 1089497 A, whereby the disclosures of the application are incorporated herein by
reference in it entirety.
The pharmaceutical compositions of the invention may be prepared by persons of ordinary
skill in the art using conventional methods. One embodiment of the invention includes a
method for preparing an ointment comprising the following steps:
10

- heating a ointment base in a water bath at about 50°C until softened;
- adding the softened ointment base in turn into a beaker containing the frozen
dried Plectranthus amboinicus crude extract and/or extract;
- adjusting the amount of the ointment base and the Plectranthus amboinicus crude
extract and/or extract to make a Plectranthus amboinicus crude extract and/or
extract ointment; and
- storing the ointment at 4°C in a refrigerator.
The content of the Plectranthus amboinicus crude extract is about 1 % to 15% by weight of
the ointment. The content of the Plectranthus amboinicus extract is about 0.1% to 5% by
weight of the ointment.
Another embodiment of the invention includes a method for preparing an ointment
comprising the following steps:
- heating a ointment base in a water bath at about 50°C until softened;
- adding the softened ointment base in turn into a beaker containing the frozen
dried Plectranthus amboinicus crude extracts and/or extract to make a
Plectranthus amboinicus crude extract and/or extract ointment;
- homogenously mixing the Plectranthus amboinicus crude extract and/or extract
ointment and the Centella asiatica Urban extract to make a Centella asiatica
Urban extract and Plectranthus amboinicus crude extract and/or extract ointment;
and
storing the ointment at 4°C in a refrigerator.
The content of the Plectranthus amboinicus crude extract is about 0.5% to about 5% by
weight of the ointment and that of the Centella asiatica Urban extract is about 0.1% to
about 20% by weight of the ointment. The content of the Plectranthus amboinicus extract
is about 0.05% to about 2% by weight of the ointment and that of the Centella asiatica
Urban extract is about 0.1% to about 20% by weight of the ointment. The weight ratio
between the Plectranthus amboinicus crude extract and the Centella asiatica Urban extract
is about 1:40 to about 1:4. The weight ratio between the Plectranthus amboinicus extract
and the Centella asiatica Urban extract is about 1:60 to about 1:4.
11

According to the invention, the ointment containing the fourth Plectranthus amboinicus
extract (PA-W4) prepared by the stirring separation method of the invention and that
containing PA-W4 in combination with the Centella asiatica Urban extract show a greater
efficacy in enhancing healing of wounds than the ointment comprising the Centella
asiatica Urban extract alone, the ointment comprising the Plectranthus amboinicus extracts
prepared by the traditional column chromatographic separation method in combination
with the Centella asiatica Urban extract, or other conventional drugs for enhancing wound
healing (shown in the examples below). The amounts of the fourth Plectranthus
amboinicus extract and the Centella asiatica Urban extract in the ointment are about at
least 0.01% and about at least 0.1% by weight, respectively. In an embodiment, the
amount of the fourth Plectranthus amboinicus extract is about 0.01% to about 5%, or about
0.1 % to about 1 %, or about 0.25% to about 1 %, by weight of the ointment. The amount of
the Centella asiatica Urban extract is about 0.1% to about 20%, or about 0.5% to about 9%,
or about 1% to about 3%, by weight of the ointment. In an embodiment, the weight ratio
between the fourth Plectranthus amboinicus extract and the Centella asiatica extract is
about 1:60 to about 1:4.
Utilities
The pharmaceutical compositions of the invention can be used for treating disorders
including but not limited to wounds and sores. In one embodiment, said disorders are
general trauma and bedsores, or a diabetic patient's wound.
Persons skilled in the art should have no difficulty choosing the suitable routes and the
dosages for treatments. According to the invention, the route, for example, is topical
administration. Dosage will depend on the nature and condition of the disorder, age and
health condition of the patient, administration route and any previous treatment. Persons
skilled in the art should know that dosage may vary depending on the individual's age, size,
health condition and other related factors.
The pharmaceutical compositions of the invention may be conveniently used for
manufacturing a wound dressing comprising a therapeutically effective amount of the
Plectranthus amboinicus crude extract and/or extract and optionally a therapeutically
effective amount of the Centella asiatica Urban extract, wherein said wound dressing
includes but is not limited to bandage with adhesive, plaster patch and the like.
12

The following examples are provided to aid those skilled in the art in practicing the
invention. Even so, the examples should not be construed to unduly limit the invention as
modifications to and variations on the embodiments discussed herein may be made by
those having ordinary skill in the art without departing from the spirit or scope of the
inventive discovery.
EXAMPLES
Materials
A. Ointment base
The ointment base (BETAMETHASONE ointment base) used in the examples is
purchased from Sinphar, Taiwan. The ointment base is used for preparing the ointments
comprising Centella asiatica Urban extract and/or Plectranthus amboinicus extracts as
well as the placebo in the biological assays.
B. CGS-21680
CGS-21680 (Sigma, batch number 093K4615) is a drug under clinical trials for healing
wounds. 5mg of CGS-21680 were added into 500ml distilled water to prepare a 10|xg/ml
CGS-21680 solution. The CGS-21680 solution was used as a comparative drug in the
examples.
C. Regranex
Regranex 0.01% gel contains becaplermin, a recombinant human platelet-derived growth
factor (fh-PDGF-BB), at a concentration of 100 μg/g (0.01%). It is a FDA-approved
prescription drug for the treatment of deep neuropathic diabetic foot ulcers. Regranex was
used as a comparative drug in the examples.
D. The Centella asiatica Urban extract and the ointment comprising the same
The method for preparing the Centella asiatica Urban extracts and the active component in
the pharmaceutical composition of the invention are well known to persons of ordinary
skill in the art of herbal medicine extraction. The method comprises:
- extracting Centella asiatica by ethanol reflux extraction for 2 hours, and repeating
it 2 to 3 times;
13

- condensing the ethanol extract fluids to obtain the extracts;
- retrieving the ethanol extracts, mixing and dissolving the extracts in water;
- extracting with petroleum ether, chloroform, ethyl acetate separately, and then
extracting with water-saturated n-butanol;
retrieving the solvent of n-butanol extracts under reduced pressure to obtain a
cream-like substance and dissolving the substance in a small amount of methanol;
- adding anhydrous acetone, several-fold, to the solution, to precipitate a yellowish
crude total glucoside, drying and weighing the sediments;
- adding a small amount of methanol to dissolve the crude total glucoside, mixing
properly with silica gel and drying the mixture;
- wet column packing with silica gel for chromatography and loading the sample
silica gel;
- eluting with chloroform, methanol and water (16:6:1 homogenous mixture) and
collecting 18 components in turn; each component is 50 ml and the components
are thin-layer spotting to compare with known controls;
- combining components 9 to 15, concentrating, and then purifying with column
using chloroform, methanol and water (14:6:1 homogenous mixture) for elution;
and
- concentrating the same components and crystallizing with methanol repeatedly to
obtain the white aciculate crystalline asiaticoside.
Furthermore, the drug substance of Centella asiatica Urban extracts containing asiaticoside
and madecassic acid, with a purity greater than 70%, is available on the market. The
commercial product CENTELLA ASIATICA PURIFIED EXTRACT can be purchased
from NuLiv Science, Inc., Taiwan.
1% Centella asiatica Urban extract (SI) ointment was prepared as follows:
- heating the ointment base in a water bath at about 50°C until softened;
mixing 99g of the softened ointment base with lg of Centella asiatica Urban
extract (SI);
- storing the ointment at 4°C in a refrigerator.
14

The 1% SI ointment was used in the examples as a comparative drug.
E. The Plectranthus amboinicus extracts
The Plectranthus amboinicus extracts used in the biological assays were prepared by the
preparation process of the invention (the stirring separation method) and a column
chromatographic separation method. The details of the preparation are described in the
following preparation examples.
Example 1. Preparation of Plectranthus amboinicus Extracts by Stirring Separation
Method
800g of dried Plectranthus amboinicus leaves was dipped in a 95% alcohol having a
volume ten-fold to the total weight of the dried leaves for 72 hours, and then the leaf extract
was filtrated. The extraction procedure was repeated. The two leaf extracts were mixed
to obtain a Plectranthus amboinicus crude extract and the crude extract was concentrated
by a pressure-reducing rotary evaporator (Heidolph LABOROTA 4000, Eleya N-N series)
to reduce the volume of the crude extract to about 5% of the original volume (i.e., to about
one-half of the original weight of dried leaves).
The Plectranthus amboinicus crude extract was diluted with a high-polarity solvent to a
volume ten-fold to the original one. The diluted Plectranthus amboinicus crude extract
was added into a bucket-like container containing DIAION® HP20 resin which was
pre-treated by using methanol. The resin and the extract in the container were stirred at a
speed of 3 to 10 rpm overnight. The fluid was then poured from the container. Double
distilled water having a volume five-fold to the total weight of the dry leaves was added to
the container. The resin was dipped in the water by stirring once in a while for one hour
and the fluid was collected. The collected fluid (PA-W1) was concentrated and dried to
obtain 2.4g of dried product with a yield of 0.3%.
A sub-high-polarity solvent having a volume five-fold to the total weight of the dry leaves
was further added to the container with the resin. The resin was dipped in the solvent by
stirring once in a while for one hour and the fluid was collected. The process was repeated
twice. The extracted fluids were mixed (PA-W2) and then concentrated and dried to
obtain 4g of dried product with a yield of 0.5%.
15

A medium-polarity solvent having a volume five-fold to the total weight of the dry leaves
was further added to the container with the resin. The resin was dipped in the solvent by
stirring once in a while for one hour and the fluid was collected. The process was repeated
twice. The extracted fluids were mixed (PA-W3) and then concentrated and dried to
obtain 6g of dried product with a yield of 0.75%.
A low-polarity solvent having a volume five-fold to the total weight of the dry leaves was
further added to the container with the resin. The resin was dipped in the solvent by
stirring once in a while for one hour and the fluid was collected. The process was repeated
three times. The extracted fluids were mixed (PA-W4) and then concentrated and dried to
obtain 7.52g of dried product with a yield of 0.94%.
Example 2. Preparation of Plectranthus amboinicus Extracts by Column
Chromatographic Separation Method
DIAION resin having a weight identical to that of the dried Plectranthus amboinicus leaves
was dipped in methanol and packed into a chromatographic column. The packed DIAION
resin was then washed with methanol having a volume one- to two-fold to the total weight
of the DIAION resin, and subsequently washed with double distilled water having a
volume five- to six-fold to the total weight of the DIAION resin.
800g of dried Plectranthus amboinicus leaves was dipped in 95% alcohol having a volume
ten-fold to the total weight of the dried leaves for 24 hours. After filtration, the leaves
were further dipped in 95% alcohol having a volume ten-fold to the total weight of the
dried leaves for 24 hours. The Plectranthus amboinicus extract fluids were mixed and
concentrated by a pressure-reducing rotary evaporator to reduce the volume to about 2-3%
of the original volume.
The extract obtained from the preceding steps was diluted with distilled water and loaded
into the DIAION resin column. The column was eluted with a high-polarity solvent
having a volume ten-fold to the total weight of the dried leaves. An eluted fraction
(PA-C1) was collected and the yield was 0.38%.
16

The column was then eluted with a sub-high-polarity solvent having a volume five- to
ten-fold to the total weight of the dried leaves. An eluted fraction (PA-C2) was collected
and the yield was 0.5%.
The column was eluted again with a medium-polarity solvent having a volume five- to
ten-fold to the total weight of the dried leaves. An eluted fraction (PA-C3) was collected
and the yield was 0.78%.
Finally, the column was eluted with a low-polarity solvent having a volume five- to
ten-fold to the total weight of the dried leaves. An eluted fraction (PA-C4) was collected
and the yield was 0.67%.
Example 3. Composition analysis of the Plectranthus amboinicus extracts
Instruments and equipments
High Performance Liquid Chromatography (HPLC) Spectra System,Thermo
Pump: Spectra-Physics P4000
Detector: UV/VIS Spectra-PhysicsSpectraSystem UV600OLP
Auto sampler: Thermo Separation Products AS3500
Software: Thermo Separation Products ChromQuest
System Controller: Thermo Separation Products SN4000
Conditions for Liquid Phase HPLC
Chromatographic column: Phenomenex, 4.6x250nm, Luna 5μ silica(2)
Flow rate: 1.0 ml/min Pressure Limit: 250 kgf/cm2
Sample amount: 10 μl
PDA conditions: Sampling period: 0.64 sec
Wavelength range: 190-370 run
Channels: 270, 320 ran
Elution Profile:

Time (min)
Mobile phase 0 15 45 50
n-hexane 95% 85% 30% 95%
Ethyl acetate 5% 15% 70% 5%
17

The chromatographic spectrum of the PA-W4 extract obtained by stirring separation and
that of the PA-C4 extract obtained by column chromatographic separation are shown in
Figures 1 and 2, respectively. The PA-W4 has HPLC peaks at the following retention
time:

Peak Retention time (min)
1 5.5
2 9.6
3 20.0
4 22.5
5 23.5
6 24.8
7 27.7
8 27.8
9 28.6
10 28.9
11 29.7
12 31.0
13 31.9
14 36.6
15 37.8
Example 4. Preparation of Ointments Comprising Plectranthus amboinicus Extracts and
Ointments Comprising Centella asiatica Urban Extract (SI) and Plectranthus amboinicus
Extracts.
Suitable amounts of ointment base, PA-W4 extract and PA-C4 extract were measured.
The ointment base was preheated in a water bath at about 50C until softened and added
into beakers containing the PA-W4 extract and the PA-C4 extract to obtain a 0.25%
PA-W4 ointments and a 0.25% PA-C4 ointment. The weight ratio of the ointment base to
the Plectranthus amboinicus extracts was 99.75:0.25. The obtained ointments were then
mixed with Centella asiatica Urban extract (SI) in a weight ratio of 99:1 to obtain a
DCR-WH1-W ointment (1% SI + 0.25% PA-W4) and a DCR-WH1-C ointment (1% SI +
0.25% PA-C4).
18

Biological Assays
Example 5. Animal Experiments for Wound Closures in Diabetic Rats
[Animal experiments]
Induction of high blood sugar in the animals
Rats with a body weight of over 300g were administered with Streptozotocin (STZ, 65
mg/kg, i.p.) to induce high blood sugar. Rats with successfully induced high blood sugar
(over 300mg/DL) were selected to conduct the wound closure tests two months after
high-blood-sugar syndromes appeared.
Trauma surgeries for the diabetic animals
i. The high-blood-sugar animals with a body weight of lower than 300g were
eliminated and the rest were randomized into 6 groups,
ii. The animals were anesthetized with pentobarbital and the hair on the surgical
area (dorsal area) was removed. The surgical areas and instruments were then
sterilized with 75% alcohol before operation.
iii. The skins on the dorsal medium areas (4, 6 and 8 cm from the midpoint of two
scapula) were excised (full thickness) using a round cutting blade with a diameter of 1
cm.
Measuring the wounds, applying testing materials, and preventing the wounds from
being scratched
i. A standard ruler was placed beside the wounds and pictures were taken,
ii. A thin layer of the test materials formulated as ointments and 0.05 ml of
CGS21680 solution were applied to each wound,
iii. The wounds were covered with gauze and hoods were worn on the rats' necks.
Test materials were applied to the rats twice a day (morning and evening) and the wounds
were measured at each time point.
19

After the experiments were finished, the regenerated skins were taken for biochemistry and
histology analysis.
[Wound area analysis]
A standard ruler was placed beside the wounds when pictures were taken. The length of
the wounds was standardized according to the scale of the standard ruler in the pictures
before the wounds were analyzed with the image processing software Image-Pro (Media
Cybernetics, Inc.) to avoid the errors caused by different picturing distances.
[Data analysis and statistics]
The areas of the three wounds on the rats' backs were analyzed by Image-Pro. The wound
areas of day zero were the original wound areas. The original wound areas minus the
wound areas at different time points were divided by the original wound areas to get the
wound closure percentages. The mean of the three wound closure percentages of each rat
represents the wound closure of each rat. Four to seven rats per group were used for each
test materials. The data was shown as mean ± standard error (SEM). The p-values of the
test results were calculated by t-test in statistics software sigma statis (Systat software Inc.).
P charts or tables. P ** on the statistics charts or tables. P difference, and it is marked with *** on the statistics charts or tables.
Example 6. Comparison of the Efficacies of 1% SI, CGS-21680, Regranex,
DCB-WH1-C and DCB-WH1-W on Wound Closures in STZ-Induced Diabetic Rats
The purpose of this example is to compare the efficacy of the composition of the invention
and that of the commercially available products on wound closures. The wound closure
animal experiments were conducted according to Example 5. On day 0, 4, 6, 8, 10 and 12
after the treatments of placebo (Group 1), 1% SI ointment (Group 2), CGS-21680 (Group
3), Regranex (Group 4), DCB-WH1-C (Group 5) and DCB-WH1-W (Group 6), the wound
areas of all experimental groups were measured and the wound closure percentages and
CT50 (time required for 50% wound closure) values were calculated. The results are
20

shown in Figure 3 and Table 1. The P-values of the paired comparison of wound closure
percentages of the experimental groups are shown in Table 2.
Table 1 Wound closure percentages and CT50 of the experimental groups treated
with placebo, 1% SI ointment, CGS21680, Regranex, DCB-WH1-C and
DCB-WH1-W

Groups Test materials Wound closure percentage (%) CT50
(day)

Day 4 Day 6 Day 8 Day 10 DAY 12

1 Placebo -99.6±13.3 -107.6±10.5 -45.14±13 19.9±5.3 61.5±3.1 11.4
2 1% SI -62.7±6.0 -51.4±6.0 -18.2±9.7 45.2±5.9 77.7±2.3 10.3
3 CGS-2168 -21.3±4.8 -27.3 8±3.2 -2.4±4.1 46.7±6.0 71.7±2.4 10.3
4 Regranex -21.0±l 0.4 2.7±8.1 1.46±6.7 59.9±2.6 78.0±4.8 9.7
5 DCB-WH1-C -19.2±7.0 -13.6±6.7 18.3±6.6 59.9±2.9 84.8±3.0 9.5
6 DCB-WH1-W 4.1±2.9 22.3±2.7 56.0±2.5 84.5±1.8 93.9±0.7 7.65
Table 2 The P-values of the paired comparison of wound closure percentages of
the experimental groups

Day Group vs. Group P-values
4 2 3 0.000289 ***
4 2 4 0.0054565 **
4 2 5 0.0004544 ***
4 2 6 0.000001203 ***
4 3 4 0.9788
4 3 5 0.5697
4 3 6 0.00075098 ***
4 4 5 0.7119
4 4 6 0.0276 *
4 5 6 0.0157 *
6 2 3 0.0055961 **
6 2 4 0.00039598 ***
6 2 5 0.001875 **
6 2 6 0.0000005765 ***
6 3 4 0.0049146 **
6 3 5 0.0947
6 3 6 0.000000339 ***
6 4 5 0.1504
6 4 6 0.0356
6 5 6 0.0005663 ***
8 2 3 0.1659
8 2 4 0.1454
8 2 5 0.0113 *
21

8 2 6 0.000023634 ***
8 3 4 0.62
8 3 5 0.0238 *
8 3 6 0.0000002486 ***
8 4 5 0.1087
8 4 6 0.000016991 ***
8 5 6 0.00031843 ***
10 2 3 0.8675
10 2 4 0.0954
10 2 5 0.0509
10 2 6 0.000084357 ***
10 3 4 0.1274
10 3 5 0.0740
10 3 6 0.00011665 ***
10 4 5 0.9934
10 4 6 0.000055221 ***
10 5 6 0.000026694 ***
On day 4, the wound closure percentages of Groups 3,4, 5 or 6 are significantly higher than
those of Groups 1 and 2 (P significantly higher than those of Groups 3, 4 and 5 (P closure percentages of Groups 3, 4, 5 and 6 are significantly higher than those of Groups 1
and 2 (P even significantly higher than those of Group 3,4 or 5 (P wound closure percentages of Groups 5 and 6 are significantly higher than those of Groups
2 (P those of Groups 3, 4 and 5 (P 6 is significantly higher than those of other groups (P are 11.4,10.3, 10.36, 9.4, 9.5 and 7.65 days, respectively.
In summary, the DCB-WH1-W ointment of the invention has a superior efficacy over other
test materials, i.e., ointment base, 1% SI ointment, CGS21680, Regranex and
DCB-WH1-C.
Example 7. Comparison of the Efficacies of 1 % S1, 0.25% PA-W4. DCB-WH1 -W and
1% PA-W4 on Wound Closures in STZ-Induced Diabetic Rats
The purpose of this example is to compare the efficacy of DCB-WH1-W with that of its
active ingredients in wound closures. The test materials are placebo (Group 1), 1% SI
ointment (Group 2), 0.25% PA-W4 ointment (Group 3), DCB-WH1-W (Group 4) and 1%
22

PA-W4 ointment (Group 5). The wound closure animal experiments were conducted
according to Example 5. On day 0, 4, 9, 11 and 13 after the treatment with the test
materials, the wound areas of all experimental groups were measured and the wound
closure percentages and CT50 were calculated. The results are shown in Figure 4 and
Table 3. The P-values of the paired comparison of wound closure percentages of the
experimental groups are shown in Table 4.
Table 3 Wound closure percentages and CT50 of the experimental groups treated
with placebo, 1% SI ointment, 0.25% PA-W4 ointment, DCB-WH1-W and 1%
PA-W4 ointment

Groups Test materials Wound closure percentage (%) CT50
(day)

Day 4 Day 9 Day 11 Day 13

1 Placebo -65.07±9.5 -19.6±13.4 35.7±11.1 79.8±4.9 11.7
2 1% SI -62.55±8.9 16.8±7.5 59.1±5.1 93.2±1.7 10.6
3 0.25% PA-W4 -46.1±13.8 29.9±9.8 77.9±2.3 95.2±1.0 9.9
4 DCB-WH1-W -3.51±1.7 59.7±6.6 87.9±3.1 97.42±1.0 8.25
5 1%PA-W4 -16.5±10.9 62.2±7.4 88.45±3.3 98.59±0.8 8.25
Table 4 The P-values of the paired comparison of wound closure percentages of
the experimental groups

Day Group vs. Group P-values
4 1 2 0.8505
4 1 3 0.2822
4 1 4 0.0001 ***
4 1 5 0.0047 **
4 2 3 0.3391
4 2 4 0.0001 ***
4 2 5 0.0052 **
4 3 4 0.0094 **
4 3 5 0.1015
4 4 5 0.1874
9 1 2 0.0714
9 1 3 0.0239 *
9 1 4 0.0004 ***
9 1 5 0.0009 ***
9 2 3 0.3126
9 2 4 0.0010 **
9 2 5 0.0015 **
9 3 4 0.0173 *
9 3 5 0.0274 *
9 4 5 0.8053
23

11 1 2 0.0847
11 1 3 0.0041 **
11 1 4 0.0008 ***
11 1 5 0.0024 **
11 2 3 0.0075 **
11 2 4 0.0003 ***
11 2 5 0.0012 **
11 3 4 0.0073 **
11 3 5 0.0201 *
11 4 5 0.5970
13 1 2 0.0271 *
13 1 3 0.0117
13 1 4 0.0092 **
13 1 5 0.0072 **
13 2 3 0.3247
13 2 4 0.0444 *
13 2 5 0.0199 *
13 3 4 0.0800
13 3 5 0.0214 *
13 4 5 0.5622
On day 4, the wound closure percentages of Groups 4 or 5 are significantly higher than
those of Groups 1 and 2 (P and 5 are significantly higher than those of Group 1 (P Group 3 (P than that of Group 1 (P and 5 are significantly higher than that of Group 2 (P percentages of Groups 4 and 5 are significantly higher than that of Group 3 (P day 13, the wound closure percentage of Groups 4 and 5 are significantly higher than those
of Group 1 (P is significantly higher than that of Group 3 (P between Groups 4 and 5 on days 4, 9, 11 and 13. The CT50 for Groups 1 to 5 are 11.7,
10.6, 9.9, 8.25 and 8.25 days, respectively.
In summary, the efficacy of the ointment comprising 1% PA-W4 (1% PA-W4 ointment) on
wound closures is equivalent to that of the DCB-WH1-W (1% Sl+0.25% PA-W4)
ointment. The 1% PA-W4 and DCB-WH1-W ointments of the present invention have a
superior efficacy over the ointment base, the 1% SI ointment and the 0.25% PA-W4
ointment.
24

WE CLAIM;
1. A process for preparing Plectranthus amboinicus extracts comprising the step of:
a) contacting dried Plectranthus amboinicus leaves with a leaf extracting solvent
to obtain a Plectranthus amboinicus crude extract;
b) concentrating the Plectranthus amboinicus crude extract; and
c) separating the concentrated Plectranthus amboinicus crude extract by stirring
to obtain a Plectranthus amboinicus extract.

2. The process according to Claim 1, wherein the leaf extracting solvent comprises
water or alcohol.
3. The process according to Claim 1, wherein the concentrated Plectranthus
amboinicus crude extract is separated by a stirring separation method.
4. The process according to Claim 3, wherein the stirring separation method
comprises the steps of:

(a) diluting the concentrated Plectranthus amboinicus crude extract with a
high-polarity solvent;
(b) mixing the diluted Plectranthus amboinicus crude extract with an absorbing
resin;
(c) stirring the absorbing resin with the diluted Plectranthus amboinicus crude
extract;
(d) after removing liquid portion, extracting the resin with the high-polarity
solvent, and collecting a first extract;
(e) extracting the resin with a sub-high-polarity solvent and collecting a second
extract;
(f) extracting the resin with a medium-polarity solvent and collecting a third
extract; and
(g) extracting the resin with a low-polarity solvent and collecting a fourth extract.
5. The process according to Claim 4, wherein the high-polarity solvent comprises water,
methanol, ethanol, or mixture thereof.
25

6. The process according to Claim 4, wherein the sub-high-polarity solvent has a
polarity lower than that of the high-polarity solvent.
7. The process according to Claim 4, wherein the medium-polarity solvent has a polarity
lower than that of the sub-high-polarity solvent.
8. The process according to Claim 4, wherein the low-polarity solvent has a polarity
lower than that of the medium-polarity solvent.

9. A Plectranthus amboinicus extract prepared by the process according to Claim 4,
containing one or more extracts selected from the first, second, third and fourth extracts.
10. The Plectranthus amboinicus extract according to Claim 9, wherein the fourth
extract has the following HPLC peaks of retention time:

Peak Retention time (min)
1 5.5
2 9.6
3 20.0
4 22.5
5 23.5
6 24.8
7 27.7
8 27.8
9 28.6
10 28.9
11 29.7
12 31.0
13 31.9
14 36.6
15 37.8
wherein said HPLC is conducted in the following conditions:
Chromatographic column: Phenomenex, 4.6x250mm, Luna 5(0, silica(2)
Flow rate: 1 .0ml/min Pressure Limit: 250 kgf/cm2
Sample amount: 10 μl
PDA condition: Sampling period: 0.64 sec
Wavelength range: 190-370 nm
Channel: 270, 320 nm
26

Elution Profile:

Time (min)
Mobile phase 0 15 45 50
n-hexane 95% 85% 30% 95%
Ethyl acetate 5% 15% 70% 5%
11. A Plectranthus amboinicus crude extract prepared by step a) and/or b) of the
process according to Claim 1.
12. A pharmaceutical composition comprising a therapeutically effective amount of the
Plectranthus amboinicus extract according to Claim 9 or 10 and optionally a
pharmaceutically acceptable carrier, diluent or excipient.
13. The pharmaceutical composition according to Claim 12, further comprising a
therapeutically effective amount of Centella asiatica Urban extract.
14. The pharmaceutical composition according to Claim 13, wherein the Plectranthus
amboinicus extract and the Centella asiatica Urban extract have a weight ratio of about
1:60 to about 1:4.
15. A pharmaceutical composition comprising a therapeutically effective amount of the
Plectranthus amboinicus crude extract according to Claim 11 and optionally a
pharmaceutically acceptable carrier, diluent or excipient.
16. The pharmaceutical composition according to Claim 15, further comprising a
therapeutically effective amount of Centella asiatica Urban extract.
17. A wound dressing comprising a pharmaceutical composition according to any one
of Claims 12 to 16.
18. A use of the pharmaceutical composition of any one of Claims 12 to 16 in the
manufacture of a medicament for treating skin disorder.
27

19. The use according to Claim 18, wherein the skin disorder is general trauma or
bedsores.
20. The use according to Claim 18, wherein the skin disorder is wounds in a diabetic
patient.

The invention provides a process for the preparation of Plectranthus amboinicus extracts using
a stirring separation method. The invention also provides a pharmaceutical composition
comprising the Plectranthus amboinicus crude extract and/or extract for treating skin disorders,
including enhancing the healing of wounds, especially in diabetic patients.

A PHARMACEUTICAL COMPOSITION AND PROCESS THEREOF FOR THE PREPARATION OF PLANT EXTRACTS FOR TREATING SKIN DISORDERS AND ENHANCING HEALING OF WOUNDS

Documents:

Inventors:

PCT Conventions: