저탄소 공정을 이용한 추출 기술인 초음파, 마이크로파 및 초고압 추출 공정기술의 이산화탄소 배출량(TCO2)과 얻어진 저분자 진세노사이드 총량의 상관관계를 비교하였다. 기존의 공정인 열수 추출 공정의 TCO2 배출량은 약 0.4 TCO2로 나타났다. 마이크로파 추출 공정의 경우 0.1437 Ton 당 CO2를 배출하는 것으로 확인 되었다. 또한, 초음파 추출 공정의 경우 0.0862 Ton 당 CO2를 배출하는 것을 확인 하였으며, 초고압 추출 공정의 경우 0.1014 Ton당 CO2를 배출하는 것을 확인 하였다. 저탄소 공정별 저분자 진세노사이드의 전환된 양을 측정한 결과 마이크로파 추출 공정의 경우 약 246.65% 정도 증진된 것을 확인 할 수 있었다. 또한, 초음파 공정의 약 275.71% 증진된 결과를 보였다. 초고압 추출 공정의 경우에는 약 295.21% 증진된 결과를 얻었다. 전체적으로 열수 추출 공정의 경우 얻어진 저분자 진세노사이드가 적은 반면 CO2 배출량이 매우 높은 것을 확인하였다. 반대로, 저탄소 추출 공정인 마이크로파, 초음파 및 초고압 공정의 경우 얻어진 저분자 진세노사이드의 양이 높으며, 방출되는 CO2의 양이 기존의 재래 방법보다 적은 것을 확인 하였다. 따라서, 저탄소 추출 공정인 마이크로파, 초음파, 초고압
추출 공정을 통해 인삼을 효과적으로 추출을 할 수 있으며, 친환경 저탄소 공법을 통해 CO2 발생량을 억제하여 경제적으로 천연물을 추출할 수 있을 것으로 사료된다.
김치 및 젓갈 등의 150여 전통 발효 식품을 시료로 하여 protease 활성을 갖는 유산균을 분리한 결과, 24 U/mgcrude protein의 높은 활성을 갖는 젖산균 BV-26 균주을 분리하였다. API 50CHL kit를 이용하여 BV-26 균주의 당 이용성을 분석하고 16S rRNA 염기서열(99.9% 상동성)을 비교한 결과, 분리된 균주를 L. plantarum BV-26으로 표기하였다. L. plantarum BV-26의 생장과 protease 활성 변화를 MRS 배지를 이용하여 측정한 결과, L. plantarum BV-26의 생장은 배양 6시간 이후 활발하게 진행되어 18시간에 최고의 균체 농도를 보였으며, protease 활성은 배양 후 12시간부터 생성되기 시작하여 16시간에서 최고의 활성을 나타내는 것으로 확인되었다. 따라서 본 연구에서 분리된 L. plantarum BV-26을 동물사료의 발효용 스타터로 이용할 경우 유산균이 갖는 유익한 장점 및 안전성을 확보할 수 있을 뿐만 아니라, 특히 대두박의 발효시 사료의 영양적 가치를 높일 수 있을 것으로 기대된다.
This study was performed to enhance contents of low molecular ginsenoside using steaming and fermentationprocess in low quality fresh ginseng. For increase in contents of Rg2, Rg3, Rh2 and CK in low quality fresh ginseng, a steam-ing process was applied at 90℃ for 12hr which was followed by fermentation process at Lactobacillus rhamnosus HK-9incubated at 36℃ for 72h. The contents of ginsenoside Rg1, Rb1, Rc, Re and Rd were decreased with the steaming associ-ated with fermentation process but ginsenoside Rg2, Rg3, Rh2 and CK increased after process. It was found that under thesteaming associated with fermentation process, low molecule ginsenosides such as Rg2, Rg3, Rh2 and CK were increased as3.231㎎/g, 2.585㎎/g and 1.955m/g and 2.478㎎/g, respectively. In addition, concentration of benzo[α]pyrene in extracts ofthe low quality fresh ginseng treated by the complex process was 0.11ppm but it was 0.22ppm when it was treated with thesteaming process. This result could be caused by that the most efficiently breakdown of 1,2-glucoside and 1,4-glucoside link-age to backbone of ginsenosides by steaming associated with fermentation process. This results indicate that steaming pro-cess and fermenration process can increase in contents of Rg2, Rg3, Rh2 and CK in low quality fresh ginseng.
This study was designed to evaluate antioxidant activity of Curcuma longa L. leaves treated by ultra highpressure extraction. Curcuma longa L. leaves was subjected to 5,000 bar for 5 and 15 min at 25℃ The highest phenolics andflavonoids content was observed in the treatment of high pressure extraction for 15 min (308.28㎍/㎎, 124.33㎍/㎎). TheDPPH scavenging activity was 82.34% at 1.0㎎/㎖ of Curcuma longa L. leaves treated by ultra high pressure process for 15min. The highest SOD-like acitivity of Curcuma longa L. leaves (1.0㎎/㎖) was observed at ultra high pressure extractionfor 15 min (67.54%). The high pressure extraction significantly increased the contents of phenolics and flavonoids and alsoenhanced the antioxidant activity. These results provide useful information for enhancing biological properties of Curcumalonga L. leaves.
This study was performed to enhance contents of low molecular weight ginsenoside Rh2 and Rg3 using an ultra high pressure and steaming process in wild cultured-Root in wild ginseng. For selective increase in contents of Rg3 and Rh2 in cultured wild ginseng roots, an ultra high extraction was applied at 500MPa for 20 min which was followed by steaming process at 90℃ for 12 hr. It was revealed that contents of ginsenosides, Rb1, Rb2, Rc and Rd, were decreased with the complex process described above, whereas contents of ginsenoside Rh2 and Rg3 were increased up to 4.918 mg/g and 6.115 mg/g, respectively. In addition, concentration of benzo[α]pyrene in extracts of the cultured wild ginseng roots treated by the complex process was 0.64 ppm but it was 0.78 ppm when it was treated with the steaming process. From the results, it was strongly suggested that low molecular weight ginsenosides, Rh2 and Rg3, are converted from Rb1, Rb2, Rc, and Rd which are easily broken down by an ultra high pressure and steaming process. This results indicate that an ultra high pressure and steaming process can selectively increase in contents of Rg3 and Rh2 in cultured wild ginseng roots and this process might enhance the utilization and values of cultured wild ginseng roots.
In general, stepwise hot steaming process is known to be effective in improving its biological activities; however, not much employed in processing Codonopsis lanceolata due to its hardness. In this study, C. lanceolata was first pretreated with warm water at 50℃ and 60℃ for two hours, then steamed for 3 hours. Antioxidant activities of 70% ethanol extracts were compared with the extract from the water solvent: 41.58% vs 8.98% of DPPH radical scavenging activity in adding 1.25mg/ml of steamed extract and water extract, respectively. Reducing power of steamed and fresh C. lanceolata were also measured as 1.39 and 0.71. Total poly phenolic of the steamed extract was estimated as 12.11mg/g, compared to 3.98mg/g fresh C. lanceolata. Total flavonoid contents were also obtained as 11.48mg/g, compared to 7.11mg/g of fresh C. lanceolata. In comparing phenolic acids profiles in the extract, in general higher amounts of gallic acid, trans-ferulic acid, vanillic acid were obtained possibly by easy release of active components during thermal processing, which results in better antioxidant activities than that of water extract. This findings can also be supported by result that the ethanol extract showed better activities than the water extract.
This study compared the contents of low molecular ginsenoside according to fermentation process in low grade fresh ginseng. Low grade fresh ginseng was directly inoculated with a 24 h seed culture of Bifidobacterium Longum B6., Lactobacillus casei., and incubated at 36℃ for 72 h. Bifidobacterium Longum B6 was specifically was found to show the best growth on 3,255×106 CFU/ml after 48 h of fermentation. The content of ginsenoside Rb1, Re and Rd were decreased with the fermentation but ginsenoside Rh2 and Rg2 increased after fermentation process. In the case of low molecular ginsenoside conversion yields were 56.07% of Rh2, 12.03% of Rg3 and 77.11% of Rg2, respectively. In addition, compound-K was irregular conversion yield as long as 72 h of fermentation. This results indicate that fermentation process could increase the low molecular ginsenoside in low grade fresh ginseng.
Conventional Thiamine Dilauryl Sulfate (TDS) powder has a low stability. In order to solve this problem, this study was performed to improve the solubility of TDS. The process for enhance solubility of TDS was nano grinding mill and ultrasonic dispersion process. TDS paticle was manufactured to nano size through nano grinding mill process. The size of TDS nanoparticle was measured as average 220 nm by DLS. And The TDS nanoparticle in water solution manufactured through ultrasonic dispersion process. The TDS nanoparticle in water solution was showed the highest solubility with 40% ethanol. These results was increased the concentration of TDS from 200 ppm to 240 ppm in water solution. The TDS nanoparticle in water solution showed diameter of Colletotrichum gloeosporioides growth with smaller than about 1.56 cm compared to the TDS paticle in water solution at same concentration. Also, TDS nanoparticle in water solution showed growth inhibition activity as 59.2% with higher than about 10% compared to the TDS paticle water solution in same concentration. Finally, TDS nanoparticle in water solution was increased solubility through nano grinding mill and ultrasonic dispersion process. Also, the increase of concentration in TDS nanopaticle in water solution according to solubility enhancement lead to an result enhancement of antifungal activity. Consequently, we suggested that the TDS nanoparticle in water solution was more effective than TDS particle in water solution owing to the sub-cellular particle size, ability to persistence and targeting to cell membrane of Colletotrichum gloeosporioides. Furthermore we expected the applicating possibility with bio pesticide.
In this study, we investigated the cosmetic application of Acer mono sap through an ultra-high pressure process. Exposing Acer mono sap to a ultra-high pressure process resulted in 90.1% cell viability of human normal fibroblast cells (CCD-986sk) when added at the highest concentration. Acer mono sap also showed the hightest free radical scavenging activity after the ultra high pressure process. The melanogenesis inhibition rate in cloned M-3 cells was 59.0%. Tyrosinase was inhibited at a rate of 87.2% by adding 100% HPAMS. Anti-wrinkle activity was 78.1%. Acer mono sap showed enhanced storage following the ultra high pressure process. These results indicate that Acer mono sap may be a source for functional cosmetic agents capable of improving antioxidant, whitening, and antiwrinkling effects.
In this study, we investigated antioxidant activities and whitening effects of Acer mono sap by encapsulation of nanoparticles. Acer mono sap was through ultra high pressure process and then encapsulated by lecithin. Nano-encapsulated The nanoparticles of Acer mono sap showed highest free radical scavengering effect as 89.7% in adding sample (1.0 mg/ml), compared to sap of non-encapsulation. It was showed strong inhibition effect on melanin production test by Clone M-3 cells as 47.8%. High inhibitory of tyrosinase was also measured as 85.8% by adding lecithin nano-particle of 1.0 mg/ml. The nano-particles also showed 14.8% of low cytotoxicity against human normal fibroblast cells in adding 1.0 mg/ml of the highest concentration. These results indicate that Acer mono sap may be a source of cosmetic agents capable of improving whitening effect and antioxidant activites.
This study was to investigate the effect of fermentation extracts on the concentration of serotonin and melatonin in the serum of the ICR mice. The ICR mice were divided into water control group, lactobacillus fermentation solution including (Lactobacillus paracasei and Bifidobacterium longum B6) control group, positive control group (milk and doxylamine succinate), negative control group (caffein) and the groups treated with the extracts of Berberis koreana bark (WE: water extracts, FE-L.P: fermentation extracts of Lactobacillus paracasei, FE-B.L: fermentation extracts of Bifidobacterium longum B6). After ten-day feeding treatment, the mean concentration of serotonin for water control, WE, FE-L.P and FEB. L group was 134.72, 183.01, 232.09 and 223.78 ng/ml, respectively. The mean concentration for FE-L.P and FE-B.L group were approximately 66% larger than that for water control group. The mean concentration of melatonin for water control, WE, FE-L.P and FE-B.L group was 76.92, 106.66, 157.56 and 141.81pg/ml, respectively. The mean concentration of melatonin for FE-L.P and FE-B.L group were also larger than that for water control group. Our results indicated that the fermentation extracts of Berberis koreana bark have relatively greater potential to induce secretion of serotonin and melatonin. Therefore, the fermentation extracts have antidepressant effect.
This study was performed to enhance anticancer activities of Lithospermum erythrorhizon by eluting high amount of shikonin through ultra high pressure process. Extraction yield was increased up to 5~10% by ultra high pressure process, compare to the normal extraction processes such as water solvent extraction, 70% ethyl alcohol solvent extraction. The cytotoxicity of the extracts (1.0μg/ml) from ultra high pressure process was showed the lowest cytotoxicity 13.4% for human lung cell (HEL299). The anticancer activities showed 80~85% by adding 1.0μg/ml of the extracts from ultra high pressure process in several cancer cell lines such as AGS, Hep3B, MCF-7 and HeLa cells. Among them, MCF-7 cell of the endocrine system was highest inhibited than other cells. The anticancer activities of the extracts from ultra high pressure extraction process showed 10~15%, which was higher than the extracts from normal extraction processes. From HPLC analysis of the extracts, the contents of shikonin in the extracts from ultra high pressure process was 11.42% (w/w), which was 20% higher than others. This results indicate that ultra high pressure process could increase the extraction yield of shikonin and other contents, which resulted in higher anticancer activities.
In this study, whitening activity of Lithospermum erythrorhizon extracts were investigated according to several extraction processes: water extraction at 100℃ (WE100) and 60℃ (WE60), 70% ethyl alcohol extraction (EE) and ultra high pressure extraction (HPE) at 500 MPa for 30 minutes at 60℃. The extracts from ultra high pressure extraction showed the highest tyrosinase inhibition and melanogenesis inhibition activities as 52% and 79.5%, respectively, in adding 1mg/ml than others extraction processes. HPE extracts also showed the strong reducing power as 3.19 that absorbance at 450 mm. The contents of polyphenol in WE100, we measured as 10.1μg/ml in adding 1mg/ml. Extracts have a high total flavonoid contents by HPE as 4.1μg/ml at 1mg/ml. We can conclude that better whitening activity of extracts from high pressure extraction was due to high antioxidant activities which could be extracted by higher polyphenol and flavonoid contents in HPE than others.