以葛根素为探针解析SD大鼠时辰节律的研究
|
摘要
在生命过程中,从分子到细胞、从个体到群体都具有明显的周期往复的现象。已有研究显示,人类多种宏观生命活动以及微观的生理指标,如内分泌激素、微量元素等都具有的规律性周期活动。随着医学科学的发展,人们发现许多药物的疗效除了与病人所患疾病及药物本身特性、用量大小、用药途径等因素有关外,还与机体节律性密切相关。因此,适应生物节律制定合理的给药方案,对提高药物疗效、降低毒副作用、具有重要的临床意义与价值。目前,在对药物作用的时间节律和药物对机体生物节律的影响,及临床治疗最佳用药时间的研究中,科研方法主要局限于通过检测血药浓度等内源性理化指标来获得药物体内代谢及分布的时辰节律,但是对外源性物质作用靶点的时辰节律变化尚缺乏有效的研究手段。
随着现代科学技术的飞速发展,单克隆抗体免疫分析技术逐渐成熟,因其具有特异性强、灵敏度高、可靠安全、快捷方便等优点在医学临床检验和基础研究中获得广泛应用。本团队基于自主制备的中药小分子葛根素与栀子苷的单克隆抗体,采用免疫分析法可以特异灵敏的检测单味药和复方中葛根素与栀子苷在体内的代谢分布,其中葛根素灵敏度可达到匹克级。因此以中药小分子物质为探针,通过检测不同时辰其在体内靶器官分布情况。以此作为一种新的思路与手段来证明时辰节律的本质内涵。从而为达到理想的治疗目的提供科学依据。
目的:本论文旨在通过应用葛根素单克隆抗体为探针,解析葛根素在SD大鼠体内时辰节律的分布趋势,为基于人体节律的时间医学研究提供新的思路与方法。
方法:1分组和给药:将25只SD大鼠随机分成8:00组、12:00组、16:00组、20:00组、24:00组,实验前各组动物动物禁食8小时,自由饮水。在设定的各个时间点上对各组动物按20mg/kg给药剂量腹腔注射给药。2取材一小时后腹主动脉取血,处死动物,立即取心、肝、脾、肺、肾和脑,冰上对全脑分离出皮层、海马、间脑、延髓、小脑、松果体。所有组织于-40℃冷冻保存。3血液和组织前处理方法血液常温放置2h,4℃冰箱放置过夜,3000r/min离心取上清。皮层、小脑、间脑、海马、延髓、松果体等容易破碎的、重量小的组织称重,按100mg组织:1mlPBS的比例加入PBS溶液,冰浴条件下200W功率超声波粉碎匀浆15S;其余组织称取200mg,剪碎后按100mg组织:1m1PBS的比例加入PBS溶液,冰浴条件下超声破碎仪200W功率超声波粉碎匀浆15S,匀浆液于15000r/min、4℃条件下离心30min,取上清分装,于-40℃冷冻保存。
结果:(1)葛根素在SD大鼠血液中其峰值相位为20:00时,24:00时浓度较低,其谷值相位为8:00,峰谷值之间相位相差12小时(p<0.05),因此周期为为近似昼夜节律。(2)葛根素在SD大鼠肾脏、肺脏、肝脏、脾脏中的分布趋势其峰值出现在12:00,而心脏中的分布趋势峰值出现在12:00,这种分布趋势的差异提示葛根素不同的靶器官具有不同的时辰节律。(3)葛根素8:00时在SD大鼠主要脏器中的药物分布趋势呈肝<脾<肺<心<肾。在12:00时在SD大鼠主要脏器中的药物分布趋势呈脾<心<肺<肝<肾。在16:00时在SD大鼠主要脏器中的药物分布趋势呈脾<肺<肝<心<肾。在20:00时在SD大鼠主要脏器中的药物分布趋势呈脾<肝<肺<心<肾。在24:00时在SD大鼠主要脏器中的药物分布趋势呈脾<肝<肺<心<肾。这种分布趋势的差异提示不同时辰下葛根素在SD大鼠主要脏器中的分布呈不同的趋势。(4)葛根素在脑部不同分区皮层、松果体、间脑、小脑、延髓、海马中的分布趋势呈近日节律的趋势,然而其相位峰值的时间却并不一致。(5)葛根素在SD大鼠不同脑区中的药物分布趋势8:00时呈松果体<间脑<延髓<海马<皮层<小脑,12:00时呈松果体<海马<间脑<皮层<延髓<小脑,16:00时呈松果体<间脑<延髓<海马<皮层<小脑,20:00呈松果体<海马<延髓<皮层<间脑<小脑,0:00时呈松果体<间脑<延髓<皮层<海马<小脑。这种分布趋势的差异提示不同时辰下葛根素在SD大鼠不同脑区中的分布亦呈不同的趋势。
结论:本实验的结果提示利用葛根素单克隆抗体El isa方法,可以观察到葛根素在SD大鼠内分布趋势具有时辰节律。不同的脏器时辰节律的相位不完全一致。因此,葛根素单克隆抗体可以做为更深刻解析中医学时辰节律实质与科学内涵的探针。
During the span of human being, there are the recycling circumstances existing in organs, from molecules to cells, from organisms to colonies; however, among those, life activities, like growth and reproduction, and even some more subtle physical indicators, like endocrine hormones and trace elements, are the most well-known. As the development of medical science, we have find out that the therapeutic effects are closely related to the patient's illness, and the drug's nature, dose, taking method, but also the rhythm of organism. Therefore, it is crucial and valuable to apply biological rhythm to prescribe in enhancing therapeutic effects and reducing side effects. However, nowadays our research in the time rhythm of drug intervention and in the influence of drug on biological rhythm are mainly limited in physical and chemical indicators and plasma concentration detection. There is still lack of an effective studying means in the rhythm change of the therapeutic effect on targets.
As the high-speed development of modern science, the monoclonal antibody immunoassay technology has become maturer and maturer, which has merits in specificity, sensitivity, reliability and convenience. Our researching team utilize small molecules of TCM puerarin, extracting in immunosorbent assay, and the monoclonal antibody of geniposide to detect the metabolism distribution of puerarin and geniposide, with a sensitivity reaching pg-level. Therefore, we can demonstrate the nature of time rhythm by a updated approach of using small molecules as the probe to detect their distribution in target organs in different hours in order to provide the scientific basis for reaching ideal treatment objective
Objective:This paper aims to provide a new approach in researching the rhythm of human body in time medical science by illustrating the distribution tendency of puerarin monoclonal antibody as the probe in the SD mouses in the double-hour rhythm.
Methods:Firstly, divide25SD rats into5groups at random. There are:group eight o'clock, group twelve o'clock, group sixteen o'clock, group twenty o'clock, and group twenty-four group. Then inject each mouse20mgl/kg puerarin injection from abdominal cavity. One hour after the injection, detect the distribution tendency of puerarin in the cerebral cortex, diencephalon, hippocampus, cerebellar, oblongata, pineal gland, liver, heart, kidney, lung, spleen and blood of the SD mouse.
Results:(1) The density of puerarin in the blood of SD rats reaches its peak at20o'clock at night. The density is relatively lower at8o'clock, reaching its bottom. There are twelve hours between the peak and the bottom, with a cycle time of24±4hours, which is approximate to the day-and-night rhythm.(2) The density of puerarin in the kidney, lung, liver and spleen of SD mouse reaches its peak at12o'clock.But that in the heart of it reaches its bottom at12o'clock, which is resting and calm period. This difference in distribution tendency indicates the different target organs are different in time rhythm.(3) At8o'clock, the distribution tendency of puerarin in the major organs in SD mouse presents as:liver Conclusion:The results of this experiment indicates that we can detect the influence of double-hour rhythm on the distribution tendency of puerarin in SD mouses by using the approach of puerarin-monoclonal-antibody-Elisa. Therefore, the method of puerarin monoclonal antibody can be used as probe for more profound research in the nature and scientific connotation of TMC double-hour rhythm.
随着现代科学技术的飞速发展,单克隆抗体免疫分析技术逐渐成熟,因其具有特异性强、灵敏度高、可靠安全、快捷方便等优点在医学临床检验和基础研究中获得广泛应用。本团队基于自主制备的中药小分子葛根素与栀子苷的单克隆抗体,采用免疫分析法可以特异灵敏的检测单味药和复方中葛根素与栀子苷在体内的代谢分布,其中葛根素灵敏度可达到匹克级。因此以中药小分子物质为探针,通过检测不同时辰其在体内靶器官分布情况。以此作为一种新的思路与手段来证明时辰节律的本质内涵。从而为达到理想的治疗目的提供科学依据。
目的:本论文旨在通过应用葛根素单克隆抗体为探针,解析葛根素在SD大鼠体内时辰节律的分布趋势,为基于人体节律的时间医学研究提供新的思路与方法。
方法:1分组和给药:将25只SD大鼠随机分成8:00组、12:00组、16:00组、20:00组、24:00组,实验前各组动物动物禁食8小时,自由饮水。在设定的各个时间点上对各组动物按20mg/kg给药剂量腹腔注射给药。2取材一小时后腹主动脉取血,处死动物,立即取心、肝、脾、肺、肾和脑,冰上对全脑分离出皮层、海马、间脑、延髓、小脑、松果体。所有组织于-40℃冷冻保存。3血液和组织前处理方法血液常温放置2h,4℃冰箱放置过夜,3000r/min离心取上清。皮层、小脑、间脑、海马、延髓、松果体等容易破碎的、重量小的组织称重,按100mg组织:1mlPBS的比例加入PBS溶液,冰浴条件下200W功率超声波粉碎匀浆15S;其余组织称取200mg,剪碎后按100mg组织:1m1PBS的比例加入PBS溶液,冰浴条件下超声破碎仪200W功率超声波粉碎匀浆15S,匀浆液于15000r/min、4℃条件下离心30min,取上清分装,于-40℃冷冻保存。
结果:(1)葛根素在SD大鼠血液中其峰值相位为20:00时,24:00时浓度较低,其谷值相位为8:00,峰谷值之间相位相差12小时(p<0.05),因此周期为为近似昼夜节律。(2)葛根素在SD大鼠肾脏、肺脏、肝脏、脾脏中的分布趋势其峰值出现在12:00,而心脏中的分布趋势峰值出现在12:00,这种分布趋势的差异提示葛根素不同的靶器官具有不同的时辰节律。(3)葛根素8:00时在SD大鼠主要脏器中的药物分布趋势呈肝<脾<肺<心<肾。在12:00时在SD大鼠主要脏器中的药物分布趋势呈脾<心<肺<肝<肾。在16:00时在SD大鼠主要脏器中的药物分布趋势呈脾<肺<肝<心<肾。在20:00时在SD大鼠主要脏器中的药物分布趋势呈脾<肝<肺<心<肾。在24:00时在SD大鼠主要脏器中的药物分布趋势呈脾<肝<肺<心<肾。这种分布趋势的差异提示不同时辰下葛根素在SD大鼠主要脏器中的分布呈不同的趋势。(4)葛根素在脑部不同分区皮层、松果体、间脑、小脑、延髓、海马中的分布趋势呈近日节律的趋势,然而其相位峰值的时间却并不一致。(5)葛根素在SD大鼠不同脑区中的药物分布趋势8:00时呈松果体<间脑<延髓<海马<皮层<小脑,12:00时呈松果体<海马<间脑<皮层<延髓<小脑,16:00时呈松果体<间脑<延髓<海马<皮层<小脑,20:00呈松果体<海马<延髓<皮层<间脑<小脑,0:00时呈松果体<间脑<延髓<皮层<海马<小脑。这种分布趋势的差异提示不同时辰下葛根素在SD大鼠不同脑区中的分布亦呈不同的趋势。
结论:本实验的结果提示利用葛根素单克隆抗体El isa方法,可以观察到葛根素在SD大鼠内分布趋势具有时辰节律。不同的脏器时辰节律的相位不完全一致。因此,葛根素单克隆抗体可以做为更深刻解析中医学时辰节律实质与科学内涵的探针。
During the span of human being, there are the recycling circumstances existing in organs, from molecules to cells, from organisms to colonies; however, among those, life activities, like growth and reproduction, and even some more subtle physical indicators, like endocrine hormones and trace elements, are the most well-known. As the development of medical science, we have find out that the therapeutic effects are closely related to the patient's illness, and the drug's nature, dose, taking method, but also the rhythm of organism. Therefore, it is crucial and valuable to apply biological rhythm to prescribe in enhancing therapeutic effects and reducing side effects. However, nowadays our research in the time rhythm of drug intervention and in the influence of drug on biological rhythm are mainly limited in physical and chemical indicators and plasma concentration detection. There is still lack of an effective studying means in the rhythm change of the therapeutic effect on targets.
As the high-speed development of modern science, the monoclonal antibody immunoassay technology has become maturer and maturer, which has merits in specificity, sensitivity, reliability and convenience. Our researching team utilize small molecules of TCM puerarin, extracting in immunosorbent assay, and the monoclonal antibody of geniposide to detect the metabolism distribution of puerarin and geniposide, with a sensitivity reaching pg-level. Therefore, we can demonstrate the nature of time rhythm by a updated approach of using small molecules as the probe to detect their distribution in target organs in different hours in order to provide the scientific basis for reaching ideal treatment objective
Objective:This paper aims to provide a new approach in researching the rhythm of human body in time medical science by illustrating the distribution tendency of puerarin monoclonal antibody as the probe in the SD mouses in the double-hour rhythm.
Methods:Firstly, divide25SD rats into5groups at random. There are:group eight o'clock, group twelve o'clock, group sixteen o'clock, group twenty o'clock, and group twenty-four group. Then inject each mouse20mgl/kg puerarin injection from abdominal cavity. One hour after the injection, detect the distribution tendency of puerarin in the cerebral cortex, diencephalon, hippocampus, cerebellar, oblongata, pineal gland, liver, heart, kidney, lung, spleen and blood of the SD mouse.
Results:(1) The density of puerarin in the blood of SD rats reaches its peak at20o'clock at night. The density is relatively lower at8o'clock, reaching its bottom. There are twelve hours between the peak and the bottom, with a cycle time of24±4hours, which is approximate to the day-and-night rhythm.(2) The density of puerarin in the kidney, lung, liver and spleen of SD mouse reaches its peak at12o'clock.But that in the heart of it reaches its bottom at12o'clock, which is resting and calm period. This difference in distribution tendency indicates the different target organs are different in time rhythm.(3) At8o'clock, the distribution tendency of puerarin in the major organs in SD mouse presents as:liver
引文
[1]何绍雄等.时间药理学与时间治疗学[M],天津:天津科技出版社,1994,第一版
[2]何明丰,高振和.时间医学的研究进展与发展趋势[J].中国中医急症,2004,(03):180-181.
[3]杨晓.时辰医学与中药的时间治疗方法[J].甘肃中医,2009,(08):1-3.
[4]徐福成;樛秀俊.中药的服药时间与临床疗效的观察[J].光明中医,2008,(01):72-73.
[5]李月红.六经病欲解时述评[J].光明中医,2009,(03):409-410.
[6]谢恬;凌一揆.中医择时用药疗法初探[J].成都中医学院学
[7]Lemmer B. Implications of chronopharmacokinetics for drug deliv2ery:antiasthmatics H22blockers and cardiovascular active drugs[J]. Adv Drug Deliv Rev,1991,6 (1):83.
[8]陈海英,宋登浩,安秀芹,等.择时用药对大鼠胃粘膜炎性细胞影响的实验研究[J].陕西中医,2008,(02):238-239.
[9]陈学习,张英杰,李美霞,等.脾虚证与免疫系统关系研究概况与思考[J].中国当代医药,2010,(34):6-8.
[10]严桂珍,郑家铿,许少峰,等.附子理中汤择时用药对脾阳虚家兔免疫功能的影响[J].中医药学刊,2001,(06):623-624.
[11]姚成增,胡剑北.右归饮择时使用对肾阳虚大鼠睾酮昼夜节律的影响[J].上海中医药杂志,2005,(02):53-55.
[12]韩军,宋建国.中药方剂鸡鸣散的时间药理学实验研究[J].中国临床药理学与治疗学,2008,(07):782-785.
[13]廖品东,张发荣,骆永珍.老年人及肾虚患者红细胞免疫粘附活性的昼夜节律变化[J].中西医结合杂志,1990,10(4):217-8.
[14]王菲,郑杨,肖洪彬,等.择时服用淫羊藿对性激素水平的影响[J].中医杂志,2001,42(10):619--20.
[15]王非,王平,郑杨,等.择时服用右归丸对肾阳虚大鼠性激素水平的影响[J].中国中医药科技,2006,13(6):374.
[16]刘旭光,宋开源,余曙光,等.阴虚阳虚大鼠促肾上腺皮质激素及皮质酮昼夜节律的差异研究[J].四川中医,2002,20(1):6-7.
[17]姚成增,胡剑北.右归饮择时使用对肾阳虚大鼠生长激素昼夜节律的影响[J].皖南医学院学报,2003,22(1):56-8.
[18]许良银,郑真,程宜福.健脾法择时给药对实验性糖尿病小鼠血糖昼夜节律的影响[J].中医杂志,2009,(10):925-927+935.
[19]Barg iello TA, Jackson FR, Young MW. Restor ation o fcircadian behav io ur al rhy thms by g ene tra nsfer inDro so phila [J]. Nat ur e,1984,312(5996):752754.
[20]朱洁,胡剑北.延胡索不同配伍对镇痛作用时辰差异的影响[A].中国中西医结合学会时间生物医学专业委员会.2006全国时间生物医学学术会议论文集[C].中国中西医结合学会时间生物医学专业委员会:,2006:176-177-178-179-180-181-182-183
[21]吴琼,束仁兰,章长阎.延胡索4种炮制品镇痛镇静作用研究[J].安徽中医学院学报,1998,(05):53-54.
[22]陈坤,高献书,卢付河,等.黄芪、参芪促肿瘤生长作用的观察[J].河北医科大学学报,2004,25(1):33-34.
[23]王秀,胡剑北.择时服用黄芪的抗肿瘤作用研究[J].河南中医,2006,(06):29-31.
[25]蒋梅先,曹飞.急性心肌梗死发病的中医时间医学研究[A].中国中西医结合学会时间生物医学专业委员会.2009全国时间生物医学学术会议论文集[C].中国中西医结合学会时间生物医学专业委员会:,2009:33-34-35-36-37-38-39-40-41
[26]刘旭宋开源刘雨星余曙光郝亮罗荣不同时辰针刺对阴虚阳虚大鼠体温昼夜节律影响的研究
[27]张彭三,张凤真,王梅申,陈幽婷,刘露霞.不同时辰电针大鼠足三里穴对血浆中cAMP和cGMP含量的影响[J].徐州医学院学报,1994,(02):95-98.
[28]王哲民,俞昌正,刘照强,任遵华.不同时辰针刺小鼠足三里穴对脑浆亮—脑腓肽水平影响[J].山东中医学院学报,1995,(06):412-413.
[29]林建美,范平国.515例病毒性心肌炎心率昼夜节律的观察[J].浙江中西医结合杂志,1998,(02):74-75.
[30]崔松,陈昕琳,蒋梅先.240例病毒性心肌炎室性早搏日分布的中医病理节律研究[J].中西医结合学报,2005,(05):25-28.
[31]王义周,王庆松,刘妍,王蕾.肾虚证择时用药的研究进展[J].安徽医药,2009,(09):1009-1011.
[1]王莉平,王义善.中医时间医学在现代肿瘤治疗的应用研究[J].实用医药杂志,2008,(06):748-749.
[2]江舟,汪宇辉,关俊文,姚兵,刘雅,刘延友,王正荣.伴有脑血管意外的高血压患者血压近日节律特点分析[J].航天医学与医学工程,2009,(02):102-105.
[3]孙悦,吴涛,诸葛芬,陆科东,倪银华,傅正伟.生物钟信号调控的营养学[J].生命科 学,2009,(02):324-329.
[4]李洪.新生大鼠缺氧缺血性脑损伤后心肌细胞钟基因表达的变化[D].导师:冯星.:苏州大学,2010.
[5]Ramon C. Hermida A, Diana E,et al. Circadian variation of blood pressure:the basis for the chronotherapy of hypertension[J]. Adv Drug Deliv Rev,2007,59,904.
[6]蒲小波,杜一平.血压的近日节律与高血压的时间治疗学[J].重庆医学,2009,(21):2748-2750.
[7]邸丕凡,朱秋茹,赵兴洲,谭丽丽.昼夜规律和性别对健康人窦性心率震荡的影响[J].河北医药,2009,(15):1884-1885.
[8]Hirota T, Fukada Y. Resetting mechanism of central and peripheral circadian clocks in mammals[J]. Zool Sci,2004,21(4):359-368.
[9]Karatsoreos IN, Silver R. The neuroendocrinology of the suprachiasmatic nucleus as a conductor of body time in mammals[J]. Endocrinology,2007,148(12):5640-5647.
[10]Challet E, Caldelas I, Graff C, et al. Synchronization of the molecular clockwork by light and food-related cues in mammals[J]. Biol Chem,2003,384(5):711-719.
[11]陈晨,江舟,王正荣.生物钟基因与心血管疾病的关系[J].四川生理科学杂志,2009,(02):80-83.
[12]孙悦,吴涛,诸葛芬,陆科东,倪银华,傅正伟.生物钟信号调控的营养学[J].生命科学,2009,(02):324-329.
[13]Bell Pedersen D, Cassone VM, Earnest DJ, et al. Circadirhythms from multiple oscillators:les sons from diverse organism[J]. Nat Rev Genet.2005,6(7):544-556.
[14]8 Becker Weimann S, Wolf J, Kramer A, et al. A model of the mammalian circadian oscillator including the REVER Balphamodule[J]. Genome Inform.2004,15(1):3-12.
[15]Cheng H Y, Papp J W, Varlamova O, Dziema H, Russell B, Curfman J P, et al. microRNA modulation of circadian-clock period and entrainment[J]. Neuron,2007,54:813-829.
[16]Na Y J, Sung J H, Lee S C, Lee Y J, Choi Y J, Park W Y, et al.Comprehensive analysis of microRNA-mRNA co-expression in circadian rhythm[J]. Exp Mol Med,2009,41:638-647.
[17]Xu S, Witmer P D, Lumayag S, Kovacs B, Valle D. MicroRNA (miRNA) transcriptome of mouse retina and identification of a sensory organ-specific miRNA cluster[J]. J Biol Chem, 2007,282:25053-25066.
[18]Kojima S, Gatfield D, Esau C C, Green C B. MicroRNA-122 modulates the rhythmic expression profile of the circadian dead enylase nocturnin in mouse liver[J].PLoS One,2010,5:ell264.
[19]Nagel R. Clijsters L, Agami R. The miRNA-192/194 cluster regulates the period gene family and the circadian clock[J].FEBS J,2009,276:5447-5455.
[20]曹栓柱Perl, Per2在体外培养的胶质瘤细胞和正常细胞中的表达的差异性研究[D].导师:夏鹤春.:宁夏医科大学,2010.
[21]Mishima K, Tozawa T, Satoh K, et al. Melatonin secretion rhythm disorders in patients with senile dementia of alzheimer's type with disturbed sleep waking[J]Biol Psychiatry,1999; 45(4):417-21
[22]Bonanni E, Maestri M, Tognoni G, et al. Daytime sleepiness in mild and moderate Alzheimers disease and its relationship with cognitive impairment [J]. J Sleep Res,2005;14(3):311-317.
[23]汪青松,徐芳,许乃银,袁媛,周江宁.轻度认知损害患者昼夜静息-活动和睡眠-觉醒节律研究[J].解放军医学杂志,2006,(12):1194-1196.
[24]方凌燕,刘衍宇,关俊文.阿尔茨海默病与生物节律相互关系的研究进展[J].中国老年学杂志,2011,(08):1486-1488.
[25]蒲小波.高血压患者血压近日节律特点分析及其与靶器官损害的相关性研究[D].导师:杜一平.:泸州医学院,2010.
[26]葛丽娟,吴爱宁.对原发性高血压血压昼夜节律与时间治疗学关系的认识[J].中国社区医师(医学专业半月刊),2009,(23):9.
[27]马建平,付海桥.高血压患者昼夜节律异常与下肢动脉硬化的关系[J].中国误诊学杂志,2012,(04):797.
[28]李西琳,黄丽娜,曹渭斌.接受降压治疗的高血压患者动态血压的影响因素[J].第二军医大学学报,2012,(01):53-57.
[29]周隽,王玮,田青.非杓型血压节律与左心室肥厚的相关性[J].承德医学院学报,2012,(01):91-92.
[30]江舟,汪宇辉,关俊文,姚兵,刘雅,刘延友,王正荣.伴有脑血管意外的高血压患者血压近日节律特点分析[J].航天医学与医学工程,2009,(02):102-105.
[31]贾志越.原发性高血压昼夜节律与心率变异性的关系探讨[J].中西医结合心脑血管病杂志,2012,(02):234.
[32]黄楠,魏伟华,于同德.睡眠呼吸暂停综合征对高血压病患者血压昼夜节律及心率变异性的影响[J].中国循证心血管医学杂志,2012,(01):49-51.
[33]刘学森,徐新娟,珠勒皮亚·司马义,陈玉岚.原发性高血压患者中心动脉压与血压昼夜节律异常变化的相互关系[J].中华高血压杂志,2012,(01):44-49.
[34]孔德贵,马龙乐,祁学文,李义波.焦虑对原发性高血压患者左室肥厚的影响[J].山东医药,2012,(05):65-66.
[35]杜丽珍.24h血压监测在48例心肌梗死患者病情评估中的临床研究[J].现代预防医学,2012,(02):516-517+523.
[36]Martino T A, Tat a N, Bels ham DD, et al. Disturbed diurnal rhythm alters gene expression and exacerbates cardiovascular disease with rescue by resynchronization[J]. Hypertension.2007,49(5):1104-1113.
[37]Portaluppi F, Cortelli P. Provini F, et al. Alteration s of sleep and circadian blood pressure profile[J]. Blood Press Monit.1997,2(6):301-313.
[38]Durgan DJ, Trexler NA, Egbejimi O, et al. The circadian clock within the cardiomyocyte is essential for responsiveness of the heart to fatty acids[J]. J Biol Chem.2006,281(34): 24254-24269.
[39]Bray MS, Shaw CA, Moore MW, et al. Disruption of the circadian clock within the cardiomyocyte influences myocardial contractile function, metabolism, and gene expression[J].Am J Physiol Heart Circ Physiol.2008,294(2):H1036-H1047.
[40]Ohkura N, Oishi K, Fukushima N, et al. Circadian clock molecules CLOCK and C RYs modulate fibrinolytic activity by regulating the PAIl gene expression[J]. J Thr omb Haemost. 2006,4(11):2478-2485.
[41]Takeda N, Maemura K, Horie S, et al. Thrombomodulinis a clock-controlled gene in vascular endothelial cells[J]. J Biol Chem.2007,282(45):32561-32567.
[42]Maemura K, dela Monte SM, Chin MT, et al. CLIF, a novel cycle like factor, regulates the circadian oscillation of plasminogen activator inhibit or 1 gene expression [J]. J Biol Chem.2000,275(47):36847-36851.
[43]Ohkura N, Oishi K, Sakata T, et al. Circadian variations in coagulation and fibrinolytic factor s among four different strains of mice[J]. Chronobiol Int.2007,24(4):651-669.
[44]Schemhammer ES, Kroenke CH, Laden F, et al. Night work and risk of breast cancer[J]. Epidemiology,2006,17(1):108-111.
[45]Lie JA, Roessink J, Kjaerheim K. Breast cancer and night work among Norwegian nurses[J]. Cancer Causes Control,2006,17(1):39-44.
[46]Kubo T, Ozasa K, Mikami K, et al. Prospective cohort study of the risk of prostate cancer among rotating-shift workers:findings from the Japan collaborative cohort study [J]. Am J Epidemiol,2006,164(6):549-555.
[47]Poole EM, Schemhammer ES, Tworoger SS. Rotating night shift work and risk of ovarian cancer[J]. Cancer Epidemiol Biomarkers Prev,2011,20(5):934-938.
[48]Pukkala E, Aspholm R, Auvinen A, et al. Incidence of cancer among commercial airline Pilots[J]. Occup Environ Med,2000,57:175-179.
[49]Sephton SE, Sapolsky RM, Kraemer HC, et al. Diurnal cortisol rhythm as a predictor of breast cancer survival[J]. J Natl Cancer Inst,2000,92(12):994-1000.
[50]Blask DE, Dauchy RT, Sauer LA, et al. Growth and fatty acid metabolism of human breast cancer (MCF-7) xenografts in nude rats:impact of constant light-induced nocturnal melatonin[J]. Breast Cancer Res Treat,2003,79(3):313-320.
[51]Filipski E, King VM, Li X, et al. Disruption of circadian coordination accelerates malignant growth in mice[J]. Pathol Biol(Paris),2003,51(4):216-219.
[52]Filipski E, Delaunary F, King VM, et al. Effects of chronic jet lag on tumor progression in mice[J], Cancer Res,2004,64(21):7879-7885.
[53]Filipski E, Levi F. Circadian Disruption in Experimental Cancer Peocesses [J]. Integr Cancer Ther,2009,8(4):300.
[54]Blask DE, Sauer LA, Dauchy RT. Melatonin as a chronobiotic/anticancer agent:cellular, biochemical, and molecular mechanisms of action and their implications for circadian-based cancer therapy, Curr Top Med Chem,2002,2(2):113-132.
[55]Lee CC. Tumor suppression by the mammalian Period genes[J]. Cancer Causes Control, 2006,17(4):525-530.
[56]Yang X, Wood PA, Oh EY, et al. Down regulation of circadian clock gene Period 2 accelerates breast cancer growth by alering its daily growth rhythm[J].Breast cancer Res Treat, 2009,117(2):423-431.
[57]Sancar A,Lindsey-Boltz LA, Unsal-Kacmaz K, et al. Molecular mechanisms of mammalian DNA repair and the DNA damage checkpoints [J].Ammu Rev Biochem, 2004,73,:39-85.
[58]Grey S, Komatsu N, Baldjyan L, et al.The circadian gene Perl plays an important role in cell growth and DNA damage control in human cancer cells [J]. Mol Cell,2006, 22(3):375-382.
[59]Winter SL, Bosnoyan-Collins L, Pinnaduwage D, et al. Expression of the circadian clock genes Perl and Per2 in sporadic and familial breast cancers[J]. Neoplasia, 2007,9(10):797-800.
[60]Kuo SJ, Chen ST, Yeh KT, et al. Disturbance of circadian gene expression in breast cancer[J]. Virchows ARCH.,2009,454(4):467-474.
[61]魏剑波,吴科,张月辉,杨玲,关俊文,张汝林.自发性蛛网膜下隙出血发病时间的生物节律特征[J].四川医学,2010,(11):1651-1652.
[62]梁鸿卿,黄小妹,张介眉,丁国华,梁伟,马威,何达,熊飞,程力,高秀伦,朱双益.5/6肾切除大鼠肾组织肾素-血管紧张素-醛固酮系统的昼夜节律[J].中国中西医结合肾病杂志,2011,(10):860-863.
[63]张汝林,刘衍宇,张月辉,魏剑波,关俊文.持续植物状态患者血压近日节律的改变[J].广东医学院学报,2009,(04):410-411.
[64]王育良,徐金华,李凯,张传伟.近日节律改变对眼球发育的影响及中医药干预[A].中华中医药学会.全国第九次中医、中西医结合眼科学术年会论文汇编[C].中华中医药学会:,2010:275-276-277.
[65]徐金华.人工光环境对视系统及性激素的影响及中药干预作用的研究[A].中华中医药学会.全国第九次中医、中西医结合眼科学术年会论文汇编[C].中华中医药学会:,2010:274-275.
[66]许伟,徐金华,王育良.李凯.不同光环境下哈萨克族人视力调查[J].国际眼科杂志,2009,(05):944-946.
[1]冯绍文,何小敏,容颖慈,许卫民.卡马西平血药浓度监测的临床意义[J].中国实用医药,2009,(36):41-42.
[2]朱贞,张燕,毛乃颖,刘中华,崔爱利,蒋小泓,陈彪,韩玉霞,詹军,吴立平,许文波.三种不同原理的间接酶联免疫吸附试验方法在严重急性呼吸道综合征诊断中的比较研究[J].中国计划免疫,2005,(03):198-203.
[3]蒋慧娟;陈亮;孙洋;徐强;陈婷;酶联免疫吸附法测定血浆中芍药苷浓度[J].分析化学,2008,(09):1238-1240.
[4]江秀华,秦光明,唐薇,廖淑清,马丽娟.抗癫痫中药制剂服用者抗癫痫西药血药浓度检测[J].药物流行病学杂志,2002,(06):296-298+342.
[1]张文.时辰药理及用药时间[J].中国医药导报,2006,(29):130.
[2]朱勉生.子午流注时空结构解析与运用[J].世界中医药,2009,(01):43-45.
[3]张超铭.《伤寒论》时间医学现象及七日节律现象机理的研究[D].导师:郝万山.:北京中医药大学,2005.
[2]何明丰,高振和.时间医学的研究进展与发展趋势[J].中国中医急症,2004,(03):180-181.
[3]杨晓.时辰医学与中药的时间治疗方法[J].甘肃中医,2009,(08):1-3.
[4]徐福成;樛秀俊.中药的服药时间与临床疗效的观察[J].光明中医,2008,(01):72-73.
[5]李月红.六经病欲解时述评[J].光明中医,2009,(03):409-410.
[6]谢恬;凌一揆.中医择时用药疗法初探[J].成都中医学院学
[7]Lemmer B. Implications of chronopharmacokinetics for drug deliv2ery:antiasthmatics H22blockers and cardiovascular active drugs[J]. Adv Drug Deliv Rev,1991,6 (1):83.
[8]陈海英,宋登浩,安秀芹,等.择时用药对大鼠胃粘膜炎性细胞影响的实验研究[J].陕西中医,2008,(02):238-239.
[9]陈学习,张英杰,李美霞,等.脾虚证与免疫系统关系研究概况与思考[J].中国当代医药,2010,(34):6-8.
[10]严桂珍,郑家铿,许少峰,等.附子理中汤择时用药对脾阳虚家兔免疫功能的影响[J].中医药学刊,2001,(06):623-624.
[11]姚成增,胡剑北.右归饮择时使用对肾阳虚大鼠睾酮昼夜节律的影响[J].上海中医药杂志,2005,(02):53-55.
[12]韩军,宋建国.中药方剂鸡鸣散的时间药理学实验研究[J].中国临床药理学与治疗学,2008,(07):782-785.
[13]廖品东,张发荣,骆永珍.老年人及肾虚患者红细胞免疫粘附活性的昼夜节律变化[J].中西医结合杂志,1990,10(4):217-8.
[14]王菲,郑杨,肖洪彬,等.择时服用淫羊藿对性激素水平的影响[J].中医杂志,2001,42(10):619--20.
[15]王非,王平,郑杨,等.择时服用右归丸对肾阳虚大鼠性激素水平的影响[J].中国中医药科技,2006,13(6):374.
[16]刘旭光,宋开源,余曙光,等.阴虚阳虚大鼠促肾上腺皮质激素及皮质酮昼夜节律的差异研究[J].四川中医,2002,20(1):6-7.
[17]姚成增,胡剑北.右归饮择时使用对肾阳虚大鼠生长激素昼夜节律的影响[J].皖南医学院学报,2003,22(1):56-8.
[18]许良银,郑真,程宜福.健脾法择时给药对实验性糖尿病小鼠血糖昼夜节律的影响[J].中医杂志,2009,(10):925-927+935.
[19]Barg iello TA, Jackson FR, Young MW. Restor ation o fcircadian behav io ur al rhy thms by g ene tra nsfer inDro so phila [J]. Nat ur e,1984,312(5996):752754.
[20]朱洁,胡剑北.延胡索不同配伍对镇痛作用时辰差异的影响[A].中国中西医结合学会时间生物医学专业委员会.2006全国时间生物医学学术会议论文集[C].中国中西医结合学会时间生物医学专业委员会:,2006:176-177-178-179-180-181-182-183
[21]吴琼,束仁兰,章长阎.延胡索4种炮制品镇痛镇静作用研究[J].安徽中医学院学报,1998,(05):53-54.
[22]陈坤,高献书,卢付河,等.黄芪、参芪促肿瘤生长作用的观察[J].河北医科大学学报,2004,25(1):33-34.
[23]王秀,胡剑北.择时服用黄芪的抗肿瘤作用研究[J].河南中医,2006,(06):29-31.
[25]蒋梅先,曹飞.急性心肌梗死发病的中医时间医学研究[A].中国中西医结合学会时间生物医学专业委员会.2009全国时间生物医学学术会议论文集[C].中国中西医结合学会时间生物医学专业委员会:,2009:33-34-35-36-37-38-39-40-41
[26]刘旭宋开源刘雨星余曙光郝亮罗荣不同时辰针刺对阴虚阳虚大鼠体温昼夜节律影响的研究
[27]张彭三,张凤真,王梅申,陈幽婷,刘露霞.不同时辰电针大鼠足三里穴对血浆中cAMP和cGMP含量的影响[J].徐州医学院学报,1994,(02):95-98.
[28]王哲民,俞昌正,刘照强,任遵华.不同时辰针刺小鼠足三里穴对脑浆亮—脑腓肽水平影响[J].山东中医学院学报,1995,(06):412-413.
[29]林建美,范平国.515例病毒性心肌炎心率昼夜节律的观察[J].浙江中西医结合杂志,1998,(02):74-75.
[30]崔松,陈昕琳,蒋梅先.240例病毒性心肌炎室性早搏日分布的中医病理节律研究[J].中西医结合学报,2005,(05):25-28.
[31]王义周,王庆松,刘妍,王蕾.肾虚证择时用药的研究进展[J].安徽医药,2009,(09):1009-1011.
[1]王莉平,王义善.中医时间医学在现代肿瘤治疗的应用研究[J].实用医药杂志,2008,(06):748-749.
[2]江舟,汪宇辉,关俊文,姚兵,刘雅,刘延友,王正荣.伴有脑血管意外的高血压患者血压近日节律特点分析[J].航天医学与医学工程,2009,(02):102-105.
[3]孙悦,吴涛,诸葛芬,陆科东,倪银华,傅正伟.生物钟信号调控的营养学[J].生命科 学,2009,(02):324-329.
[4]李洪.新生大鼠缺氧缺血性脑损伤后心肌细胞钟基因表达的变化[D].导师:冯星.:苏州大学,2010.
[5]Ramon C. Hermida A, Diana E,et al. Circadian variation of blood pressure:the basis for the chronotherapy of hypertension[J]. Adv Drug Deliv Rev,2007,59,904.
[6]蒲小波,杜一平.血压的近日节律与高血压的时间治疗学[J].重庆医学,2009,(21):2748-2750.
[7]邸丕凡,朱秋茹,赵兴洲,谭丽丽.昼夜规律和性别对健康人窦性心率震荡的影响[J].河北医药,2009,(15):1884-1885.
[8]Hirota T, Fukada Y. Resetting mechanism of central and peripheral circadian clocks in mammals[J]. Zool Sci,2004,21(4):359-368.
[9]Karatsoreos IN, Silver R. The neuroendocrinology of the suprachiasmatic nucleus as a conductor of body time in mammals[J]. Endocrinology,2007,148(12):5640-5647.
[10]Challet E, Caldelas I, Graff C, et al. Synchronization of the molecular clockwork by light and food-related cues in mammals[J]. Biol Chem,2003,384(5):711-719.
[11]陈晨,江舟,王正荣.生物钟基因与心血管疾病的关系[J].四川生理科学杂志,2009,(02):80-83.
[12]孙悦,吴涛,诸葛芬,陆科东,倪银华,傅正伟.生物钟信号调控的营养学[J].生命科学,2009,(02):324-329.
[13]Bell Pedersen D, Cassone VM, Earnest DJ, et al. Circadirhythms from multiple oscillators:les sons from diverse organism[J]. Nat Rev Genet.2005,6(7):544-556.
[14]8 Becker Weimann S, Wolf J, Kramer A, et al. A model of the mammalian circadian oscillator including the REVER Balphamodule[J]. Genome Inform.2004,15(1):3-12.
[15]Cheng H Y, Papp J W, Varlamova O, Dziema H, Russell B, Curfman J P, et al. microRNA modulation of circadian-clock period and entrainment[J]. Neuron,2007,54:813-829.
[16]Na Y J, Sung J H, Lee S C, Lee Y J, Choi Y J, Park W Y, et al.Comprehensive analysis of microRNA-mRNA co-expression in circadian rhythm[J]. Exp Mol Med,2009,41:638-647.
[17]Xu S, Witmer P D, Lumayag S, Kovacs B, Valle D. MicroRNA (miRNA) transcriptome of mouse retina and identification of a sensory organ-specific miRNA cluster[J]. J Biol Chem, 2007,282:25053-25066.
[18]Kojima S, Gatfield D, Esau C C, Green C B. MicroRNA-122 modulates the rhythmic expression profile of the circadian dead enylase nocturnin in mouse liver[J].PLoS One,2010,5:ell264.
[19]Nagel R. Clijsters L, Agami R. The miRNA-192/194 cluster regulates the period gene family and the circadian clock[J].FEBS J,2009,276:5447-5455.
[20]曹栓柱Perl, Per2在体外培养的胶质瘤细胞和正常细胞中的表达的差异性研究[D].导师:夏鹤春.:宁夏医科大学,2010.
[21]Mishima K, Tozawa T, Satoh K, et al. Melatonin secretion rhythm disorders in patients with senile dementia of alzheimer's type with disturbed sleep waking[J]Biol Psychiatry,1999; 45(4):417-21
[22]Bonanni E, Maestri M, Tognoni G, et al. Daytime sleepiness in mild and moderate Alzheimers disease and its relationship with cognitive impairment [J]. J Sleep Res,2005;14(3):311-317.
[23]汪青松,徐芳,许乃银,袁媛,周江宁.轻度认知损害患者昼夜静息-活动和睡眠-觉醒节律研究[J].解放军医学杂志,2006,(12):1194-1196.
[24]方凌燕,刘衍宇,关俊文.阿尔茨海默病与生物节律相互关系的研究进展[J].中国老年学杂志,2011,(08):1486-1488.
[25]蒲小波.高血压患者血压近日节律特点分析及其与靶器官损害的相关性研究[D].导师:杜一平.:泸州医学院,2010.
[26]葛丽娟,吴爱宁.对原发性高血压血压昼夜节律与时间治疗学关系的认识[J].中国社区医师(医学专业半月刊),2009,(23):9.
[27]马建平,付海桥.高血压患者昼夜节律异常与下肢动脉硬化的关系[J].中国误诊学杂志,2012,(04):797.
[28]李西琳,黄丽娜,曹渭斌.接受降压治疗的高血压患者动态血压的影响因素[J].第二军医大学学报,2012,(01):53-57.
[29]周隽,王玮,田青.非杓型血压节律与左心室肥厚的相关性[J].承德医学院学报,2012,(01):91-92.
[30]江舟,汪宇辉,关俊文,姚兵,刘雅,刘延友,王正荣.伴有脑血管意外的高血压患者血压近日节律特点分析[J].航天医学与医学工程,2009,(02):102-105.
[31]贾志越.原发性高血压昼夜节律与心率变异性的关系探讨[J].中西医结合心脑血管病杂志,2012,(02):234.
[32]黄楠,魏伟华,于同德.睡眠呼吸暂停综合征对高血压病患者血压昼夜节律及心率变异性的影响[J].中国循证心血管医学杂志,2012,(01):49-51.
[33]刘学森,徐新娟,珠勒皮亚·司马义,陈玉岚.原发性高血压患者中心动脉压与血压昼夜节律异常变化的相互关系[J].中华高血压杂志,2012,(01):44-49.
[34]孔德贵,马龙乐,祁学文,李义波.焦虑对原发性高血压患者左室肥厚的影响[J].山东医药,2012,(05):65-66.
[35]杜丽珍.24h血压监测在48例心肌梗死患者病情评估中的临床研究[J].现代预防医学,2012,(02):516-517+523.
[36]Martino T A, Tat a N, Bels ham DD, et al. Disturbed diurnal rhythm alters gene expression and exacerbates cardiovascular disease with rescue by resynchronization[J]. Hypertension.2007,49(5):1104-1113.
[37]Portaluppi F, Cortelli P. Provini F, et al. Alteration s of sleep and circadian blood pressure profile[J]. Blood Press Monit.1997,2(6):301-313.
[38]Durgan DJ, Trexler NA, Egbejimi O, et al. The circadian clock within the cardiomyocyte is essential for responsiveness of the heart to fatty acids[J]. J Biol Chem.2006,281(34): 24254-24269.
[39]Bray MS, Shaw CA, Moore MW, et al. Disruption of the circadian clock within the cardiomyocyte influences myocardial contractile function, metabolism, and gene expression[J].Am J Physiol Heart Circ Physiol.2008,294(2):H1036-H1047.
[40]Ohkura N, Oishi K, Fukushima N, et al. Circadian clock molecules CLOCK and C RYs modulate fibrinolytic activity by regulating the PAIl gene expression[J]. J Thr omb Haemost. 2006,4(11):2478-2485.
[41]Takeda N, Maemura K, Horie S, et al. Thrombomodulinis a clock-controlled gene in vascular endothelial cells[J]. J Biol Chem.2007,282(45):32561-32567.
[42]Maemura K, dela Monte SM, Chin MT, et al. CLIF, a novel cycle like factor, regulates the circadian oscillation of plasminogen activator inhibit or 1 gene expression [J]. J Biol Chem.2000,275(47):36847-36851.
[43]Ohkura N, Oishi K, Sakata T, et al. Circadian variations in coagulation and fibrinolytic factor s among four different strains of mice[J]. Chronobiol Int.2007,24(4):651-669.
[44]Schemhammer ES, Kroenke CH, Laden F, et al. Night work and risk of breast cancer[J]. Epidemiology,2006,17(1):108-111.
[45]Lie JA, Roessink J, Kjaerheim K. Breast cancer and night work among Norwegian nurses[J]. Cancer Causes Control,2006,17(1):39-44.
[46]Kubo T, Ozasa K, Mikami K, et al. Prospective cohort study of the risk of prostate cancer among rotating-shift workers:findings from the Japan collaborative cohort study [J]. Am J Epidemiol,2006,164(6):549-555.
[47]Poole EM, Schemhammer ES, Tworoger SS. Rotating night shift work and risk of ovarian cancer[J]. Cancer Epidemiol Biomarkers Prev,2011,20(5):934-938.
[48]Pukkala E, Aspholm R, Auvinen A, et al. Incidence of cancer among commercial airline Pilots[J]. Occup Environ Med,2000,57:175-179.
[49]Sephton SE, Sapolsky RM, Kraemer HC, et al. Diurnal cortisol rhythm as a predictor of breast cancer survival[J]. J Natl Cancer Inst,2000,92(12):994-1000.
[50]Blask DE, Dauchy RT, Sauer LA, et al. Growth and fatty acid metabolism of human breast cancer (MCF-7) xenografts in nude rats:impact of constant light-induced nocturnal melatonin[J]. Breast Cancer Res Treat,2003,79(3):313-320.
[51]Filipski E, King VM, Li X, et al. Disruption of circadian coordination accelerates malignant growth in mice[J]. Pathol Biol(Paris),2003,51(4):216-219.
[52]Filipski E, Delaunary F, King VM, et al. Effects of chronic jet lag on tumor progression in mice[J], Cancer Res,2004,64(21):7879-7885.
[53]Filipski E, Levi F. Circadian Disruption in Experimental Cancer Peocesses [J]. Integr Cancer Ther,2009,8(4):300.
[54]Blask DE, Sauer LA, Dauchy RT. Melatonin as a chronobiotic/anticancer agent:cellular, biochemical, and molecular mechanisms of action and their implications for circadian-based cancer therapy, Curr Top Med Chem,2002,2(2):113-132.
[55]Lee CC. Tumor suppression by the mammalian Period genes[J]. Cancer Causes Control, 2006,17(4):525-530.
[56]Yang X, Wood PA, Oh EY, et al. Down regulation of circadian clock gene Period 2 accelerates breast cancer growth by alering its daily growth rhythm[J].Breast cancer Res Treat, 2009,117(2):423-431.
[57]Sancar A,Lindsey-Boltz LA, Unsal-Kacmaz K, et al. Molecular mechanisms of mammalian DNA repair and the DNA damage checkpoints [J].Ammu Rev Biochem, 2004,73,:39-85.
[58]Grey S, Komatsu N, Baldjyan L, et al.The circadian gene Perl plays an important role in cell growth and DNA damage control in human cancer cells [J]. Mol Cell,2006, 22(3):375-382.
[59]Winter SL, Bosnoyan-Collins L, Pinnaduwage D, et al. Expression of the circadian clock genes Perl and Per2 in sporadic and familial breast cancers[J]. Neoplasia, 2007,9(10):797-800.
[60]Kuo SJ, Chen ST, Yeh KT, et al. Disturbance of circadian gene expression in breast cancer[J]. Virchows ARCH.,2009,454(4):467-474.
[61]魏剑波,吴科,张月辉,杨玲,关俊文,张汝林.自发性蛛网膜下隙出血发病时间的生物节律特征[J].四川医学,2010,(11):1651-1652.
[62]梁鸿卿,黄小妹,张介眉,丁国华,梁伟,马威,何达,熊飞,程力,高秀伦,朱双益.5/6肾切除大鼠肾组织肾素-血管紧张素-醛固酮系统的昼夜节律[J].中国中西医结合肾病杂志,2011,(10):860-863.
[63]张汝林,刘衍宇,张月辉,魏剑波,关俊文.持续植物状态患者血压近日节律的改变[J].广东医学院学报,2009,(04):410-411.
[64]王育良,徐金华,李凯,张传伟.近日节律改变对眼球发育的影响及中医药干预[A].中华中医药学会.全国第九次中医、中西医结合眼科学术年会论文汇编[C].中华中医药学会:,2010:275-276-277.
[65]徐金华.人工光环境对视系统及性激素的影响及中药干预作用的研究[A].中华中医药学会.全国第九次中医、中西医结合眼科学术年会论文汇编[C].中华中医药学会:,2010:274-275.
[66]许伟,徐金华,王育良.李凯.不同光环境下哈萨克族人视力调查[J].国际眼科杂志,2009,(05):944-946.
[1]冯绍文,何小敏,容颖慈,许卫民.卡马西平血药浓度监测的临床意义[J].中国实用医药,2009,(36):41-42.
[2]朱贞,张燕,毛乃颖,刘中华,崔爱利,蒋小泓,陈彪,韩玉霞,詹军,吴立平,许文波.三种不同原理的间接酶联免疫吸附试验方法在严重急性呼吸道综合征诊断中的比较研究[J].中国计划免疫,2005,(03):198-203.
[3]蒋慧娟;陈亮;孙洋;徐强;陈婷;酶联免疫吸附法测定血浆中芍药苷浓度[J].分析化学,2008,(09):1238-1240.
[4]江秀华,秦光明,唐薇,廖淑清,马丽娟.抗癫痫中药制剂服用者抗癫痫西药血药浓度检测[J].药物流行病学杂志,2002,(06):296-298+342.
[1]张文.时辰药理及用药时间[J].中国医药导报,2006,(29):130.
[2]朱勉生.子午流注时空结构解析与运用[J].世界中医药,2009,(01):43-45.
[3]张超铭.《伤寒论》时间医学现象及七日节律现象机理的研究[D].导师:郝万山.:北京中医药大学,2005.