木荷花挥发性成分的GC-MS分析

采用无水乙醚超声萃取得到新鲜木荷(Schima superba)花浸膏提取物,顶空固相微萃取富集挥发性成分,气相色谱-质谱联用仪分析,归一化法计算各组分的相对含量.鉴定出挥发性化合物中的51个成分,约占相对总含量的99%;挥发性成分中含氧化合物的含量超过93%,其中主要的化合物及其相对含量为酮代异佛尔酮(26.33%)、氧化芳樟醇(19.53%)、环氧芳樟醇(8.80%)、3,7-二甲基-2,6-辛二烯-1-醇(8.23%)、白藜芦素(7.89%)、4-羟基3,5,5-三甲基-2-环己烯-1-酮(6.54%)、2,6,6-三甲基-1,4-环己二酮(4.06%)、苯乙醇(2.17%)、2-甲基-2-壬烯-1-醇(2.04%)等.     

兴安杜鹃叶中挥发性成分的GC-MS分析

采用水蒸气蒸馏法对兴安杜鹃叶中的挥发性成分进行提取,并运用气相色谱—质谱联用技术(GC-MS)对其挥发性成分进行了系统的分离和鉴定。从兴安杜鹃叶中共鉴定出54种挥发性成分,占总馏出成分的97.84%。兴安杜鹃叶主要挥发性成分为桉叶醇(eduesmol),相对含量10.95%;β-愈创木烯(β-guaiene),相对含量10.21%;长叶醛(longifolenaldehyde),相对含量7.88%;1,5,9,9-四甲基-1,4,7-环十一碳三烯(1,5,9,9-tetramethyl-1,4,7-cy-cloundecatriene),相对含量7.80%;杜鹃酮(germacrone),相对含量5.91%;(-)-葎草烯环氧化物Ⅱ((-)-HumuleneepoxideⅡ),相对含量5.52%;2-庚基-1,3-二氧戊环(2-heptyl-1,3-dioxolane),相对含量4.99%;石竹烯(caryo-phyllene),相对含量3.70%;(+)-γ-古芸烯((+)-γ-gurjunene),相对含量3.44%。     

巴戟天挥发性成分研究

目的：研究巴戟天中的挥发性成分。方法：利用水蒸气蒸馏法提取巴戟天（Radix morindae offtcinalis）挥发油,用GC—MS进行测定,结合计算机检索技术对分离的化合物进行结构鉴定,应用色谱峰面积归一化法计算各成分的相对百分含量。结果：鉴定出34个化学成分,其中相对百分含量大于2％的分别确定为L-龙脑（Bomeol L）29．28％,α-姜烯（Alpha—Zingiberene）4．88％,2-甲基-6-对甲基苯基-2-庚烯（Ar-Cureumene）4．49％,1-己醇（1-Hexanol）3．40％,β-倍半水芹烯（beta—sesquiphellandrene）3．34％,2-戊基呋喃（2-Amylfuran）3．32％,正壬醛（n—nonanal）2．17％,樟脑（L—camphor）2．07％,β-没药烯（bete—Bisabolene）2．06％。结论：34个挥发性成分均为首次从该植物中得到。     

三种毒菌的化学成分研究

本文对三种毒菌的化学成分进行了研究。从光盖伞(Psilocybe spp)分离鉴定了4个化合物,经波谱分析鉴定为:(22E,24R)-麦角甾-7,22-二烯-3β-十八烷酸酯(1)、β-胡萝卜苷(2)、(22E,24R)-5α,6α-环氧麦角甾-8,22-二烯-3β,7α-二醇(3)、色氨酸(4);从假褐云斑鹅膏(Amanita pseudoporphyria)分离鉴定了4个化合物:(22E,24R)-3β-羟基-5α,8α-过氧化麦角甾-6,22-二烯(5)、(22E,24R)-麦角甾-7,22-二烯-3β,5α,6β-三醇(6)、1-O-β-D-吡喃葡萄糖基-(2S,3R,4E,8E,2′R)-2-N-(2′-羟基棕榈酰)-9-甲基-4,8-脱氢鞘氨醇(7)、1-O-β-D-吡喃葡萄糖基-(2S,3R,4E,8E,2′R)-2-N-(2′-羟基十八烷酰)-9-甲基-4,8-脱氢鞘氨醇(8);大青褶伞(Chlorophyllum molybdites)发酵菌丝体分离鉴定了4个化合物:5、6、(22E,24R)-5α,6α-环氧麦角甾-8(14),22-二烯-3β,7α-二醇(9)、(22E,24R)-麦角甾-7,22-二烯-3β-醇(10)。除化合物9外其它化合物均为首次从以上相应毒菌中分离得到。     

HS-SPME-GC-MS用于苍术中挥发性成分的分析

本文通过优化顶空固相微萃取萃取条件,采用顶空固相微萃取和气相色谱质谱联用(HS-SPME-GC-MS)对苍术中挥发性成分进行了分析.鉴定出桉叶油醇(β-Eudesmol),苍术酮(atractylone),γ-榄香烯(γ-Elemene),4(14),11-桉叶二烯(Eudesma-4(14),11-diene),α-蒎烯(α-Pinene),水芹烯(α-Phellandrene),倍半水芹烯(β-SesquipheIlandrene),绿叶烯(Patchouhne)等56种组分,占出峰总面积的90.38%,并与传统水蒸汽蒸馏法(SD)提取的挥发油成分进行了对比.结果表明,两种方法提取的苍术中挥发性成分基本相同,HS-SPME-GC-MS方法作为一种简单快速便利的手段非常适应于苍术中挥发性物质的提取和分析.     

土茯苓挥发性成分研究

目的:研究土茯苓中的挥发性成分。方法:利用水蒸气蒸馏法提取土茯苓(Smilax glabraRoxb.)挥发油,用GC-MS进行测定,结合计算机检索技术对分离的化合物进行结构鉴定,应用色谱峰面积归一化法计算各成分的相对百分含量。结果:分离了40个化合物,鉴定出22个化学成分,占总挥发性成分的47.88%,其中相对百分含量大于1%的分别确定为棕榈酸17.87%,萜品烯-4-醇7.533%,亚油酸6.775%,正壬烷4.509%,8,11-十八碳二烯酸甲酯2.215%,α-雪松醇1.81%,甲基棕榈酯1.293%。结论:22个挥发性成分均为首次从该植物中得到。     

石灰菌代谢产物的化学研究(Ⅰ)

从石灰菌(Lactarius hysginus Fr.)提取物的中性部分,分离得到六个化合物,经物理常数和光谱分析,鉴定为麦角甾醇(A)、硬脂酸甲脂(B)、N-苯基-2-萘胺(C)、24E-麦角甾7,22-二烯-6-酮一3β,5α-二醇(D)、庚酰胺(E)、24E-麦角甾-7.22-二烯-3β,5α,6β-三醇(F),其中化合物D作为天然产物尚未见文献报道。     

台琼海桐蒴果皮油及籽油的主要挥发性化学成分

采用GC-MS技术,对台琼海桐蒴果皮的水蒸气蒸馏油样,以及蒴果籽的索氏提取油样的甲酯化样品进行分析。样品中各化学成分的相对含量用面积归一化法确定。在实验条件下,果皮油样共分离出24个峰,鉴定了17个,占总峰面积的94.70%。其主要成分为柠檬烯(24.27%)、γ-榄香烯(8.30%)、β-榄香烯(17.13%)、α-榄香烯(16.02%)、长叶龙脑(15.52%)和α-松油醇(2.17%),α-石竹烯(1.88%)。果籽油的甲酯化样品共分离出16个峰,鉴定了12个,占总峰面积的96.69%,其主要成分为棕榈油酸(34.83%)、反油酸(26.63%)、14-甲基-十五烷酸(17.08%),十八烷酸(1.88%),十四烷酸(1.61%)。分析结果说明台琼海桐蒴果皮富含挥发性芳香油,而蒴果籽油含有多种脂肪酸。     

黄瓜藤的化学成分研究

从丽江产黄瓜藤甲醇提取物的氯仿部位分离得到9个化合物,经理化和波谱分析鉴定为α-菠甾醇(1)、α-菠甾醇-3-O-β-D-葡萄糖苷(2)、β-谷甾醇(β-sitosterol,3)、豆甾-7-烯-3-O-β-D-葡萄糖苷(4)、22-亚甲基-9,19-环羊毛甾烷-3β-醇(5)、(2S,3S,4R,10E)-2-(2′,3′-二羟基二十四烷酰氨基)-10-十八烯-1,3,4-三醇(6)、(2S,3S,4R,10E)-2-[(2′R)-2-羟基二十四烷酰氨基]-10-十八烯-1,3,4-三醇(7)、(2S,3S,4R,10E)-1-(β-D-葡萄糖苷)-2-[(2′R)-2-羟基二十四烷酰氨基]-10-十八烯-1,3,4-三醇(8)、大豆脑苷(9),除化合物3外,其它化合物均为首次从该植物中分离得到.     

超临界二氧化碳萃取川黄柏挥发性成分及其GC—MS分析

采用超临界二氧化碳萃取技术从川黄柏中萃取分离挥发性成分,得率为4.65%.并用GC-MS联用技术对萃取物进行分析,从中分离鉴定了28个成分.川黄柏挥发性成分主要为油酸、棕榈酸、2,4,6-三甲基辛烷、2-十二烯醛、2,4-二甲基-3-庚醇、2-己内酯,5-(1,1-二甲基乙基)、硬脂酸等.     

Investigation of the mechanism of temperature sensitivity of the electroreceptors of ampullae of lorenzini

In experiments on Black Sea skates (Raja clavata), the potential of the receptor epithelium of the ampullae of Lorenzini and spike activity of single nerve fibers connected to them were investigated during electrical and temperature stimulation. Usually the potential within the canal was between 0 and –2 mV, and the input resistance of the ampulla 250–400 k. Heating of the region of the receptor epithelium was accompanied by a negative wave of potential, an increase in input resistance, and inhibition of spike activity. With worsening of the animal's condition the transepithelial potential became positive (up to +10 mV) but the input resistance of the ampulla during stimulation with a positive current was nonlinear in some cases: a regenerative spike of positive polarity appeared in the channel. During heating, the spike response was sometimes reversed in sign. It is suggested that fluctuations of the transepithelial potential and spike responses to temperature stimulation reflect changes in the potential difference on the basal membrane of the receptor cells, which is described by a relationship of the Nernst's or Goldman's equation type.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. I. M. Sechenov, Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Pacific Institute of Oceanology, Far Eastern Scientific Center, Academy of Sciences of the USSR, Vladivostok. Translated from Neirofiziologiya, Vol. 12, No. 1, pp. 67–74, January–February, 1980.     

Principles of organization and evolution of systems of regulation of functions

Evolution of living organisms is closely connected with evolution of structure of the system of regulations and its mechanisms. The functional ground of regulations is chemical signalization. As early as in unicellular organisms there is a set of signal mechanisms providing their life activity and orientation in space and time. Subsequent evolution of ways of chemical signalization followed the way of development of delivery pathways of chemical signal and development of mechanisms of its regulation. The mechanism of chemical regulation of the signal interaction is discussed by the example of the specialized system of transduction of signal from neuron to neuron, of effect of hormone on the epithelial cell and modulation of this effect. These mechanisms are considered as the most important ways of the fine and precise adaptation of chemical signalization underlying functioning of physiological systems and organs of the living organism