• Title/Summary/Keyword: Herbal Decoction

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Concentration of Heavy Metals, Residual Pesticides and Sulfur Dioxide of before/after a Decoction - In Prescription of Digestive System - (전탕 전과 후의 중금속, 잔류농약 및 잔류이산화황의 농도변화 - 소화기계 약을 중심으로 -)

  • Seo, Chang-Seob;Huang, Dae-Sun;Lee, Jun-Kyoung;Ha, Hye-Kyoung;Chun, Jin-Mi;Um, Young-Ran;Jang, Seol;Shin, Hyun-Kyoo
    • The Korea Journal of Herbology
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    • v.24 no.1
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    • pp.111-119
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    • 2009
  • Objectives : To compare the contents of hazardous substances before/after a decoction. Methods : The heavy metal contents before/after a decoction were measured by Inductively Coupled Plasma Atomic Emission Spectrometer (ICP-AES) and mercury analyzer. In order to analyze pesticides in 6 samples we used simultaneous multi-residue analysis of pesticides by GC/ECD, which was followed by GC/MSD analysis to confirm the identity of the detected pesticide in each sample. In addition, the contents of sulfur dioxide (SO2) were performed by Monier-Williams distillation method. Results : 1. The mean values of heavy metal contents (mg/kg) for the samples were as follows: Samchulkunbi-tang (before decoction - Pb; 1.592, Cd; 0.155, As; 0.055 and Hg; 0.014, after decoction - Pb; 0.036, Cd; 0.002, As; not detected and Hg; 0.001), Yijin-tang (before decoction - Pb; 0.830, Cd; 0.077, As; 0.045 and Hg; 0.015, after decoction - Pb; 0.193, Cd; 0.010, As; not detected and Hg; 0.002), Banhabaikchulcheunma-tang (before decoction - Pb; 0.976, Cd; 0.164, As; 0.167 and Hg; 0.019, after decoction - Pb; 0.031, Cd; 0.003, As; 0.006 and Hg; 0.005), Pyungwi-san (before decoction - Pb; 2.162, Cd; 0.128, As; 0.061 and Hg; 0.018, after decoction - Pb; 0.080, Cd; 0.006, As; not detected and Hg; 0.005), Leejung-tang (before decoction - Pb; 1.480, Cd; 0.294, As; 0.034 and Hg; 0.012, after decoction - Pb; 0.064, Cd; 0.007, As; 0.007 and Hg; 0.002) and Kwibi-tang (before decoction - Pb; 0.907, Cd; 0.193, As; 0.085 and Hg; 0.020, after decoction - Pb; 0.072, Cd; 0.006, As; 0.004 and Hg; 0.002). 2. Contents (mg/kg) of sulfur dioxide ($SO_2$) before a decoction in Banhabaikchulcheunma-tang, Pyungwi-san, Leejung-tang and Kwibi-tang exhibited 3.5, 3.4, 3.8 and 12.4, respectively. However, contents of sulfur dioxide after a decoction in all samples were not detected. 3. Contents (mg/kg) of residual pesticides before/after a decoction in all samples were not detected. Conclusions : These results will be used to establish a criterion of heavy metals, residual pesticides and sulfur dioxide.

Concentration of Heavy Metals, Residual Pesticides and Sulfur Dioxide of before/after a Decoction (전탕 전과 후의 중금속, 잔류농약 및 잔류이산화황의 농도변화 - 감기약을 중심으로 -)

  • Seo, Chang-Seob;Huang, Dae-Sun;Lee, Jun-Kyoung;Ha, Hye-Kyoung;Chun, Jin-Mi;Um, Young-Ran;Jang, Seol;Shin, Hyun-Kyoo
    • The Korea Journal of Herbology
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    • v.23 no.4
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    • pp.51-58
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    • 2008
  • Objectives: To compare the contents of heavy metals, residual pesticides and sulfur dioxide before/after a decoction. Methods: The heavy metal contents before/after a decoction were measured by Inductively Coupled Plasma Atomic Emission Spectrometer(ICP-AES) and mercury analyzer. In order to analyze pesticides in 5 samples we used simultaneous multi-residue analysis of pesticides by GC/ECD, which was followed by GC/MSD analysis to confirm the identity of the detected pesticide in each sample. In addition, the contents of sulfur dioxide($SO_2$) were performed by Monier-Williams distillation method. Results: 1. The mean values of heavy metal contents(mg/kg) for the samples were as follows: Galgeun-tang(before decoction-Pb; 0.793, Cd; 0.133, As; 0.016 and Hg; 0.005, after decoction-Pb; 0.033, Cd; 0.004, As; 0.002 and Hg; not detected), Gumiganghwal-tang(before decoction-Pb; 0.934, Cd; 0.197, As; 0.046 and Hg; 0.006, after decoction-Pb; 0.062, Cd; 0.007, As; 0.004 and Hg; 0.0001), Sosiho-tang(before decoction-Pb; 0.891, Cd; 0.134, As; 0.091 and Hg; 0.014, after decoction-Pb; 0.036, Cd; 0.002, As; 0.004 and Hg; not detected), Ojuck-san(before decoction-Pb; 0.907, Cd; 0.136, As; 0.084 and Hg; 0.007, after decoction-Pb; 0.074, Cd; 0.007, As; 0.011 and Hg; 0.0005) and Samsoeum(before decoction-Pb; 1.234, Cd; 0.154, As; 0.016 and Hg; 0.007, after decoction-Pb; 0.094, Cd; 0.006, As; 0.002 and Hg; 0.001). 2. Contents(mg/kg) of residual pesticides before/after a decoction in all samples were not detected. 3. Contents(mg/kg) of sulfur dioxide($SO_2$) before a decoction in Galgeun-tang, Gumiganghwal-tang, Sosiho-tang, Ojuck-san and Samsoeum exhibited 1.2, 3.4, 11.1, 12.0 and 5.7, respectively. However, contents of sulfur dioxide after a decoction in all samples were not detected. Conclusions: These results will be used to establish a criterion of heavy metals, residual pesticides and sulfur dioxide.

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Establishment of the Expiration Date of Herbal Formula Decoction Pouch by Antimicrobial Activities Against Microorganisms (미생물에 대한 항균효과를 이용한 한약 전탕팩의 유효기한 연구)

  • Ha, Hyekyung;Choi, Soon-Yong;Seo, Chang-Seob;Lee, Nari;Shin, Hyeun-Kyoo
    • The Journal of Korean Medicine
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    • v.41 no.2
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    • pp.1-8
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    • 2020
  • Objectives: To establish the expiration date of herbal decoction pouch, the change in antimicrobial activities was measured according to storage temperature and period. Methods: Five herbal formulas, Gyeji-tang, Jakyakgamcho-tang, Saengmaek-san, Paljung-san, and Dangguisu-san, with antimicrobial activity were selected from 51 herbal formulas commonly used in traditional Korean medical institutions. Five herbal formula decoction pouches were prepared and stored at room temperature (RT) or 4℃ from 0 to 12 weeks to evaluate the antimicrobial activity against Bacillus cereus, Listeria monocytogenes, or Vibrio parahaemolyticus. The antimicrobial activities were evaluated by the disk diffusion method (disk size: 10 mm). Results: The decoction pouches of Gyeji-tang and Jakyakgamcho-tang maintained antimicrobial activity against V. parahaemolyticus from week 0 (14 mm) to week 12 (14 mm) at both temperatures. Saengmaek-san pouch had antimicrobial activities against V. parahaemolyticus and B. cereus from week 0 (19 mm and 20 mm) to week 12 (both 18 mm), respectively. At RT and 4℃, the antimicrobial activity of Paljung-san pouch was maintained week 0 (17 mm) to week 12 (both 13 mm) against B. cereus. Against L. monocytogenes, the antimicrobial activity of Dangguisu-san pouch showed 27 mm at week 0 and 23 mm (RT) and 24 mm (4℃) at week 12, respectively. Conclusion: According to increase of the storage duration, the antimicrobial activities of 5 herbal formula decoction pouches decreased slightly but remained up to 12 weeks. These results can be used as important data to establish the expiration date of herbal formula decoction pouches.

Concentration of Heavy Metals, Residual Pesticides and Sulfur Dioxide of before/after Decoction (중금속, 잔류농약 및 잔류이산화황의 전탕 전, 후의 농도 변화 - 다빈도 태음인 사상처방을 중심으로 -)

  • Seo, Chang-Seob;Huang, Dae-Sun;Lee, Jun-Kyoung;Ha, Hye-Kyoung;Chun, Jin-Mi;Um, Young-Ran;Jang, Seol;Kim, Jong-Yeol;Lee, Si-Woo;Shin, Hyun-Kyoo
    • Journal of Sasang Constitutional Medicine
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    • v.21 no.1
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    • pp.237-246
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    • 2009
  • 1. Objectives To compare the contents of heavy metals, residual pesticides and sulfur dioxide before/after decoction. 2. Methods The heavy metal contents before/after decoction were measured by Inductively Coupled Plasma Atomic Emission Spectrometry (ICP-AES) and mercury analyzer. In order to analyze pesticides in 3 samples we used simultaneous multi-residue analysis of pesticides by GC/ECD, followed by GC/MSD analysis to confirm the identity of the detected pesticide in each sample. In addition, the contents of sulfur dioxide (SO2) were performed by Monier-Williams distillation method. 3. Results 1) The mean values of heavy metal contents (mg/kg) for the samples were as follows: Yuldahanso-tang (before decoction - Pb; 1.85, Cd; 0.148, As; 0.042 and Hg; 0.003, after decoction - Pb; 0.096, Cd; 0.006, As; 0.006 and Hg; 0.002), Chongsimyonja-tang (before decoction - Pb; 1.193, Cd; 0.094, As; 0.084 and Hg; 0.008, after decoction - Pb; 0.053, Cd; 0.007, As; 0.011 and Hg; not detected) and Taeyeumjowee-tang (before decoction - Pb; 0.878, Cd; 0.078, As; 0.302 and Hg; 0.004, after decoction - Pb; 0.079, Cd; 0.005, As; 0.006 and Hg; not dectcted). 2) Contents (mg/kg) of residual pesticides before/after decoction in all samples were not detected. 3) Contents (mg/kg) of sulfur dioxide (SO2) before decoction in Yuldahanso-tang, Chongsimyonja-tang and Taeyeumjowee-tang exhibited 6.1, 37.8, 31.5 and 19.7, respectively. However, contents of sulfur dioxide after decoction in all samples were not detected. 4. Conclusion These results will be used to establish a criterion of heavy metals, residual pesticides and sulfur dioxide.

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Concentration of Heavy Metals in Sagunjatang, Decoction and Its Ingredient Herbal Medicines (사군자탕 제조 시 탕약과 찌꺼기 중의 중금속 함량연구)

  • Park, Moon-Ki
    • Journal of Environmental Science International
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    • v.16 no.2
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    • pp.241-245
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    • 2007
  • We studied concentration of heavy metals in Sagunjatang. In this experiment was analyzed the concentration of heavy metals of boiled Sagunjatang, decoction and its ingredient herbal medicines. The concentration of heavy metals(As, Pb, and Cd) were analysed using ICP-AES, and Hg was analysed by mercury analyzer. The average concentration of heavy metals in Sagunjatang were as follows : In all ingredient herbal medicines (Glycyrrhizae Radix, Atractylodes Macrocephala, Poria Cocos and Jinseng) of Sagunjatang, As(arsenite) contents in ail samples was in the range of 0.369-0.723ppm, Cd(cadmium) was in the range of 0.000-0.085ppm, Pb(lead) was in the range of 0.059-0.871ppm and Hg(mercury) was in the range of 0.001-0.004ppm. In boiled Sagunjatang, the concentration of heavy metals(As, Pb, Cd and Hg) was in the range of 0.000-0.016ppm, respectively. In the decoction of herbal medicines after boiled, the concentration of heavy metals was in the range of 0.004-0.387ppm. These results suggest that Sagunjatang which we take is less harmful than herbal medicine itself, and there are more significant for using the decoction of herbal medicines.

Concentration of metal in herbal drugs -in crude, remnant after boiling and decoction of herbal drugs- (한약재에 포함된 금속의 전탕 전과 후의 농도변화연구 -첩약 / 다린 찌꺼기 / 탕약을 중심으로-)

  • 이선동;박해모;이장천;국윤범
    • The Journal of Korean Medicine
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    • v.24 no.2
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    • pp.59-65
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    • 2003
  • This study was conducted to analyze metal concentration changes following processing steps for crude, remnant after boiling, and decoction of Korea herbal drugs. We measured meta.! concentration from 20 random patients who visited Oriental medical clinics for treatment of several diseases through normal action. The results obtained were as below: First, in the study to acknowledge quality control between Korean Lab and Harvard Lab in the US, 20 equal herbal samples resulted in the same values, so we confirmed the precision of measurement results from both labs. Second, hazardous metal mean concentration in crude, remnant after boiling, and decoction of herbal drugs were $32.5{\mu\textrm{g}}/22.1{\mu\textrm{g}}/8.8{\mu\textrm{g}}$ for As, $0.0{\mu\textrm{g}}/0.0{\mu\textrm{g}}/0.0{\mu\textrm{g}}$ for Cd, $1.0{\mu\textrm{g}}/0.0{\mu\textrm{g}}/0.0{\mu\textrm{g}}$ for Hg and $5416.3{\mu\textrm{g}}/3639.6{\mu\textrm{g}}/1002.6{\mu\textrm{g}}$ for Pb, respectively. These metal concentrations decreased 72.9-100.0% compared to crude status. The same trend was also visible in the other essential elements. From reviewing these results, we could carefully conclude that decoction had the least amount of metal concentration and is the optimal way to intake herbal drugs.

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Comparative Study on Biological Activities of Gwakhyangjeonggi-san Decoction According to the Preservation Periods (곽향정기산 전탕액의 보관 기간에 따른 항염증 및 항산화 효능 비교 연구)

  • Jin, Seong Eun;Kim, Ohn Soon;Shin, Hyeun-Kyoo;Jeong, Soo-Jin
    • The Journal of Korean Medicine
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    • v.35 no.3
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    • pp.60-69
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    • 2014
  • Background: Herbal formulas are generally served as a type of decoction. However, there is no scientific evidence for determining preservation and circulation period of herbal medicine decoctions. Thus, we investigated anti-inflammatory and anti-oxidative effects of the Gwakhyangjeonggi-san decoction according to its preservation period. Methods: Gwakhyangjeonggi-san decoction was stored for 0, 1, 2 or 3 months at room temperature. To evaluate anti-inflammatory effects, enzyme-linked immunosorbent assays (ELISAs) for tumor necrosis factor-alpha (TNF-${\alpha}$) and interleukin-6 (IL-6), and nitric oxide (NO) assay were conducted using the culture supernatant from RAW 264.7 cells stimulated with lipopolysaccharide (LPS). The antioxidant activities were studied by measuring free radical scavenging activities on ABTS and DPPH. Results: Gwakhyangjeonggi-san decoction maintained the inhibitory effects on TNF-${\alpha}$, IL-6 and NO productions after up to 2 months of storage in LPS-treated RAW 264.7 cells. No inflammatory response was observed in 3 months of storage. In addition, the scavenging activities on ABTS and DPPH of Gwakhyangjeonggi-san decoction were reduced time-dependently and showed less than 50% inhibition after 3 months of storage. Conclusions: Our results suggest that preservation period of Gwakhyangjeonggi-san decoction is recommended within 2 months after storage.

Development of Hazardous Materials Management Standard for Decoction Type of Personalized Herbal Medicine

  • Jeong, Hye-In;Kim, Kyeong-Han;Won, Jae-Hee;Sung, Gi-Un;Kim, Ji-Won;Han, Ji-eun;Sung, Angela Dong-Min;Park, Eun-Jung;Sung, Soo-Hyun
    • Journal of Pharmacopuncture
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    • v.23 no.2
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    • pp.71-78
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    • 2020
  • Objectives: This study was conducted to development of hazardous materials management standards for the decoction type of personalized herbal medicines (PHMs). Methods: This study was conducted in two stages. We searched documents about criteria to use words such as 'Herb', 'Herbal medicine', and 'Botanical Drug' and summarized the results. We organized the committee consisted of seven experts, and held two meetings to reach an agreement on hazardous management standards of the decoction type of PHMs. Results: The seven documents were presented in the literature review and six items related to hazardous management standards of decoction were identified. The second expert meeting brought that a total of six items, including heavy metal, pesticide residues, sulfur dioxide, benzopyrene, mycotoxin, and micro-organism limits, were selected for safety management of decoction type of PHMs. Also, the criteria and test methods for each standard were suggested for monitoring the decoction type of PHMs. Conclusion: The study suggested hazardous material management standards and criteria for the decoction types of PHMs. In the future, it would be necessary to conduct a pilot test to ensure the validity and credibility of the safety management standard and criteria. Furthermore, the government level safety management system should be introduced to verify the safety of decoction medicines.

Successful Treatment of Two Patients with Immune Thrombocytopenic Purpura Using Herbal Decoction

  • Kwon, Soo Young;Jang, Eun Gyeong;Cho, Young Hwan;Lee, Jang Hoon;Kim, Young Chul;Hong, Jung Woo
    • The Journal of Korean Medicine
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    • v.34 no.2
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    • pp.59-65
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    • 2013
  • Objectives: This case report was conducted to introduce the effectiveness of herbal decoction on patients with chronic immune thrombocytopenic purpura (ITP). Methods: We closely observed two patients who were admitted to the Department of Internal Medicine 1 of Kyung-Hee Korean Medical Hospital due to ITP. We gave a herbal decoction to these patients and then analyzed the changes in their general conditions as well as blood test results. Results and Conclusions: The treatment with herbal decoctions was helpful for ITP patients.

Concentration of Hazardous Substances of before/after a Decoction in Prescription of Herbal Medicine -In Prescription of tonify Yang and tonify Yin- (한방처방의 전탕 전과 후의 위해물질 농도변화 -보양.보음 처방을 중심으로 -)

  • Seo, Chang-Seob;Huang, Dae-Sun;Lee, Jun-Kyoung;Ha, Hye-Kyoung;Chun, Jin-Mi;Um, Young-Ran;Jang, Seol;Shin, Hyeun-Kyoo
    • Herbal Formula Science
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    • v.17 no.2
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    • pp.53-63
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    • 2009
  • Objective : To compare the contents of heavy metals, residual pesticides and sulfur dioxide before/after a decoction. Methods : The heavy metal contents before/after a decoction were measured by Inductively Coupled Plasma Atomic Emission Spectrometer (ICP-AES) and mercury analyzer. In order to analyze pesticides in 4 samples we used simultaneous multi-residue analysis of pesticides by GC/ECD, which was followed by GC/MSD analysis to confirm the identity of the detected pesticide in each sample. In addition, the contents of sulfur dioxide ($SO_2$) were performed by Monier-Williams distillation method. Results: 1. The mean values of heavy metal contents (mg/kg) for the samples were as follows: Jaeumganghwa-tang (before decoction - Pb; 1.190, Cd; 0.184, As; 0.099 and Hg; 0.028, after decoction - Pb; .033, Cd; 0.003, As; 0.005 and Hg; 0.001), Yukmijiwhang-tang (before decoction - Pb; 0.484, Cd; 0.133, As; 0.053 and Hg; 0.009, after decoction - Pb; 0.065, Cd; 0.008, As; 0.007 and Hg; not detected), Bojungikgi-tang (before decoction - Pb; 0.863, Cd; 0.197, As; below 0.016 and Hg; 0.011, after decoction - Pb; 0.071, Cd; 0.009, As; 0.004 and Hg; 0.001) and Ssangwha-tang (before decoction - Pb; 1.511, Cd; 0.212, As; 0.094 and Hg; 0.016, after decoction - Pb; 0.029, Cd; 0.006, As; 0.005 and Hg; 0.0004). 2. Contents (mg/kg) of sulfur dioxide ($SO_2$) before a decoction in Jaeumganghwa-tang, Yukmijiwhang-tang and Ssangwha-tang exhibited 22.7, 107.3 and 5.5, respectively. However, contents of sulfur dioxide after a decoction in all samples were not detected. 3. Contents (mg/kg) of residual pesticides before/after a decoction in all samples were not detected. Conclusion : These results will be used to establish a criterion of heavy metals, residual pesticides and sulfur dioxide.

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