고래(古來)로 한국인(韓國人)이 매일(每日) 먹고있는 김치의 세균학적(細菌學的) 위생성(衛生性)을 검토(檢討)하기 위하여 하절(夏節)의 김치재료와 일반(一般)김치에 대(對)하여 장내세균(腸內細菌)의 오염여하(汚染如何)를 조사(調査)하였고 김치 담근시(時)에 장내세균(腸內細菌)을 첨가(添加)하여 발효중(醱酵中)의 길항력(拮抗力)을 조사(調査)하였던 바 다음과 같은 결과(結果)를 믿었다. 1. 하절(夏節)김치의 재료(材料)채소나 김치담근의 초기(初期)에는 의외(意外)로 많은 장내세균(腸內細菌)이 오염(汚染)되어 있었다. 2. 오염(汚染)된 장내세균중(腸內細菌中)에는 병원성(病原性)이거나 식중독성(食中毒性)인 Salmonella 균(菌)이 있었다. 3. 겨울온도(溫度)인 $10^{circ}C$ 내외(內外)에서는 김치에 첨가(添加)된 Salmonella typhi Shigella flexneri, E. Coli 등 병원성세균(病原性細菌)은 약(約) 10일간(日間) 잔존(殘存)하였고 강력(强力)한 식중독균(食中毒菌)인 Vibrio Parahemolyticus는 더 강(强)한 길항(拮抗)을 보였다. 4. 여름조건인 $30^{circ}C$ 이상 온도에서 김치에 첨가된 장내세균(腸內細菌)은 pH가 4.5이하(以下)로 된 2일(日)후에 와서야 거의 사멸(死滅)되는 것이었다. 5. 약(約) $30^{circ}C$에서 각종 장내세균류(腸內細菌類)의 김치발효중에서의 길항력(拮抗力)은 pH 4.8의 젖산완충액에서 보다 상당(相當)히 약(弱)하였다. 6. 이상의 결과(結果)로 김치재료(材料)는 일반적(一般的)으로 사내세균오염(賜內細菌汚染)이 많아서 채소의 세갈방법개선(洗渴方法改善)등이 필요(必要)하며 김치 담근 직후의 식용(食用)은 비위생적(非衛生的)이라 하겠다.
It is a general trend everywhere that the uses of vegetable oils are increasing due to the fact that they are effective in curing and preventing symptoms of high blood pressure and various heart failure conditions. At the same time the concept that oxidative rancidity is caused by the oxidation of unsaturated fatty acid moieties whose subsequent decomposition gives rise to various undesirable, sometimes toxic compounds is now well accepted. Linolenic acid (C, 18:3) is one of highly unsaturated and readily oxidizable fatty acid. The content of this essential polyunsaturated fatty acid in perilla seed oil (PSO) was found to be as high as 48% while only 1.5% in sesame seed oil (SSO). In this experiment the oxidative stability of PSO was compared with that of SSO. The experimental test group were as follows: A) Stored at different temperatures, namely $4^{circ}C,;30^{circ}C,$ and $60^{circ}C,$ B) Stored at room temperature $(20{pm}5^{circ}C)$ ; a. protected from sunlight and air, b. exposed to air without sunlight c. exposed to sunlight but protected front air, d. completely exposed to both air and sunlight. The following results were obtained; 1) It was found to be most stable against oxidation to store both PSO and SSO under the low temperature $(4^{circ}C)$ condition. According to P.V. measurements it was found to be safe to keep both oils up to $30^{circ}C$ for at least 8 weeks. When exposed to air, sunlight and high temperature $(60^{circ}C)$, P.V. of PSO reached there peak values, which were much higher than those of SSO. This explains much of its instability as compared to SSO against oxidation. 2) The effect of high temperature $(60^{circ}C)$ on A.V. was found to be more striking than those of all the other storage conditions. The condition of refrigeration was most effective in keeping A.V. low for both oils as was the case in P.V. 3) For both oils, I.V. decreased throughout the experimental period (8 weeks). The range of decrement was larger for PSO than SSO. 4) There was no significant change in the compositions of fatty acids of SSO caused by various experimental storage conditions. But for PSO the compositions of stearic, oleic and linoleic acid were decreased, whereas linolenic acid was increased proportionally.
