碎米花杜鹃提取物原花青素A-1免疫活性研究
|
摘要
碎米花杜鹃(Spiciferum)为杜鹃花科(Ericaceae)杜鹃花属(Rhododendron)植物,为小灌木,主要产于我国云南中部至东南部以及贵州西部等地。生于海拔800-1200米的山坡灌丛、松林或次生林园中。碎米花杜鹃的乙酸乙酯层提取物Proanthocyanidin A-1(PAA-1)是一种原花青素类二聚体化合物。原花青素是植物中广泛存在的一大类多酚化合物的总称。近年来研究发现,原花青素具有抗氧化、保护心血管、抗癌、抗血小板聚集、免疫调节、保护肝肾功能等多种药理活性。原花青素作为天然药物提取的有效成分,其多种药理作用决定了原花青素类制剂的开发在临床方面具有广阔的前景。国内外主要针对原花青素的抗氧化活性以及防治一些如癌症、心血管疾病等一些慢性病的研究,而对于其免疫调节活性的报道却极少。
一种物质研究其是促进还是抑制免疫细胞的增殖,对其免疫调节活性的研究和发现新的药物都是非常重要的。体外研究表明,PAA-1具有很好的免疫调节作用,通过各种浓度(5、25、50、100 mg/L)体外刺激能单独或协同LPS或者Con A、anti-CD3mAb刺激Balb/c小鼠脾淋巴细胞增殖。Con A和LPS作为淋巴细胞的有丝分裂原,能刺激淋巴细胞有丝分裂,所以常被用来刺激T、B淋巴细胞,作为评估机体细胞和体液免疫功能的指标。Con A、anti-CD3mAb直接作用于T淋巴细胞,而LPS直接刺激B淋巴细胞。T淋巴细胞参与细胞免疫,而B淋巴细胞主要参与体液免疫反应。PAA-1可以协同LPS或Con A、anti-CD3mAb体外刺激小鼠脾淋巴细胞增殖,证明PAA-1可提高机体特异性的细胞免疫和体液免疫应答。
自然杀伤细胞(NK细胞)在机体防御系统中发挥重要作用,能通过抗肿瘤和抗病毒而发挥重要作用。NK细胞主要能识别病毒感染细胞,以及肿瘤细胞并对其起到杀伤作用,从而保护机体免受损伤。试验发现,PAA-1通过体外各种浓度刺激能激活NK细胞对YAC-1细胞的杀伤活性,说明PAA-1对于机体的非特异性免疫应答也存在一定的促进作用。
为进一步研究PAA-1体外促进淋巴细胞增殖的机制,运用流式细胞仪检测PAA-1对小鼠脾淋巴细胞表面标志CD4和CD8 T淋巴细胞亚群比例的影响,从分子水平上对其机理进行研究。CD4细胞识别MHC II类分子递呈的抗原,并通过辅助性T细胞Th1介导细胞免疫反应,通过Th2细胞介导体液免疫。CD8细胞识别MHC I类分子递呈的抗原,通过细胞毒性T细胞(Ts)调节细胞免疫反应。实验证明, PAA-1体外刺激不仅增加了CD4~+CD8~+双阳性细胞数量,而且诱导了CD4~+CD8~+向CD4~+以及CD8~+单阳性细胞方向分化增殖,显示PAA-1能刺激T淋巴细胞的分化成熟,从而发挥辅助性或杀伤性的作用。PAA-1体外能显著刺激T淋巴细胞分化成熟,表明PAA-1是通过增加成熟T淋巴细胞的比率而发挥免疫增强作用。
此外,为了进一步了解这种机制,采用双抗夹心ELISA法对Th细胞分泌的多种细胞因子进行了测定。细胞因子是一种蛋白质多肽,是细胞信号转导的分子。它们由多种类型的细胞分泌,并相互之间紧密联系,共同发挥作用。细胞因子在免疫系统中发挥重要作用,对抗各种免疫、炎症以及感染性疾病。当机体受到各种感染侵袭时,各种免疫细胞(如T细胞和巨噬细胞)分泌细胞因子对抗感染。此外,细胞因子还可以激活免疫细胞,刺激它们产生更多的细胞因子。细胞因子分泌量,对机体对抗各种感染的能力密切相关。试验发现,PAA-1各浓度在体外能协同Con A增加Th1细胞分泌的细胞因子(IL-2、IL-12、IFN-γ、TNF-a),却抑制Th2细胞分泌的细胞因子(IL-4、IL-10)。这些结果表明,Th1可能为PAA-1的靶细胞,PAA-1使Th1/Th2的平衡向Th1方向移动,这对许多的Th2占优势的免疫紊乱性疾病的治疗具有重要的意义。
巨噬细胞是参与免疫应答的一种重要细胞,具有抗原加工、提呈和免疫调节等作用,在机体特异性免疫应答中发挥重要作用。巨噬细胞可吞噬消化异物、杀灭多种病原微生物,并吞噬处理机体自身衰老死亡的组织细胞,是机体非特异性免疫的重要因素。PAA-1各种浓度体外能显著提高腹腔巨噬细胞能量代谢水平以及吞噬中性红的能力,说明PAA-1可促进巨噬细胞增殖并增强巨噬细胞的吞噬能力。只有活化的巨噬细胞的才能发挥吞噬作用,对机体的免疫反应才具有意义。巨噬细胞在免疫活化或受刺激时,能释放大量的一氧化氮自由基和活性氧等细胞效应分子,以杀伤入侵病原体和肿瘤细胞。一氧化氮(NO)是一种重要的介质分子,参与机体的多种生理与病理过程,包括神经传递和炎症;在免疫功能的调节中也起着十分广泛而复杂的作用。既是天然免疫中的一个重要免疫分子,能够发挥非特异性杀菌和杀伤肿瘤细胞的作用,又是一种重要的信使分子,可以调节获得性免疫。通过Griess法测定证实PAA-1各种浓度体外能增加小鼠腹腔巨噬细胞NO的分泌量。具有强大的杀灭微生物活性的活性氧杀灭外来入侵物的过程中,氧消耗的突然增长,生成超氧阴离子(O_2~-),从O_2~-开始,在细胞膜上进行的一系列反应导致了过氧化氢(H_2O_2)、羟自由基(·OH)、单线态氧(~1O_2)以及其他活性物质的生成,这一现象即呼吸爆发。呼吸爆发伴随着吞噬作用而产生,是吞噬细胞杀灭被吞噬微生物的另一重要机制。由于超氧阴离子(O_2~-)是呼吸爆发活动中的关键产物,因而O_2~-生成量,成为检测和评价吞噬细胞杀菌功能的重要指标。NBT还原实验证明,通过一定浓度的PAA-1体外刺激,可以增强小鼠腹腔巨噬细胞分泌的活性氧还原NBT的能力。巨噬细胞富含溶酶体酶,如酸性磷酸酶、非特异性酯酶、溶菌酶等,测定这些酶的活性也是衡量巨噬细胞功能的指标之一。经过PAA-1的体外刺激,细胞溶酶体酶的活性也提高了,说明PAA-1能可活化巨噬细胞,增强巨噬细胞的吞噬能力。
体外试验证明了PAA-1的免疫增强作用,要确定其对动物体的免疫调节作用,还应进行临床的体内试验。选用1日龄肉鸡,7日龄时进行新城疫免疫,11日龄时分别添加不同剂量PAA-1(0、5、10、15 mg/kg)10天,在14和21日龄分别采血测新城疫HI抗体效价,21日龄屠宰后测免疫器官胸腺、法氏囊、脾脏指数,结果为PAA-1能提高新城疫HI抗体效价水平,增强免疫器官指数,进一步证明了PAA-1在动物体内的增强机体细胞免疫和体液免疫的作用,为PAA-1开发成为新型的免疫增强剂提供一定的科学与实验技术依据。
Spiciferum are shrubs of Ericaceae and Rhododendron, the main production area is westen part of GUIZHOU, central and south east region of YUNNAN in China. Proanthocyanidin A-1 (PAA-1) extracted from Rhododendron spiciferum in ethylacetate is a Dimer compound of Proanthocyanidins. Proanthocyanidins (PAs) are general of Polyphenols. Recently researchs have found that PAs have many medical benefits including antioxidant, cardiovascular protection, anti-cancer, anti-platelet aggregation, immunomodulation and protection of liver and kidney function. So development of PAs drugs has great clinical prospects. Researchers have focused on potent antioxidant capacity, there have few reports related to immunomodulatory effects of PAs.
In the present studies, the immunomodulatory effects of PAA-1 were investigated in vitro. Different concentrations of 5, 25, 50 or 100 mg/L PAA-1 alone or PAA-1 plus Con A, or anti-CD3 mAb, or PAA-1 plus LPS can stimulate cell proliferation of plenocytes. A number of studys reported that potentiation of Con A, anti-CD3 mAb or LPS-induced proliferation of immunocyte by a certain compound suggested whose important effect in immune function. The evaluation of substances that either promote or inhibit immunocyte proliferation is crucial to the study of immunomodulatory and drug discovery. Con A and anti-CD3 mAb act directly on T cells, while LPS acts on B cells. T cells are involved in cell-mediated immunity whereas B cells are primarily responsible for humoral immunity. Therefore, PAA-1 could enhance both cellular immunity and humoral immunity.
NK cells are a part of innate immune system and play a major role in defending the host from both tumors and virally infected cells. Different concentrations of PAA-1 significantly enhanced NK function to kill YAC-1 target cells. PAA-1 also can enhance the nonspecific immunity.
To research the mechanism of stimulating cell proliferation of plenocytes of PAA-1 from cell level, effects of PAA-1 to ratio of two main lymphocyte T subsets (CD4+ cells or T helpers, and CD8+ cells or T cytotoxic/suppressors) in mice were detected by flow cytometer. CD4 T cells recognize antigens presented by major histocompatibility complex class II (MHC II) and mediate both cellular immune response through Th1 cells and humoral immune response through Th2 cells. CD8 recognizes antigens presented by MHC I and mediates cellular immune responses through cytotoxic T cells. In our study, a significant up regulation of the CD4+, CD8+ and CD4+CD8+ double positive cell populations after PAA-1 treatment was found. It means that PAA-1 possess immune-stimulating capacity.
We found that PAA-1 has a significant stimulatory effect on inducing the release of Th1 cytokines (IL-2, IL-12, IFN-γ, and TNF-α) and decreasing the release of Th2 cytokines (IL-4, IL-10) with Con A by ELISA kit in vitro. The results showed that PAA-1 can exert the effect of immunological regulation by up-adjusting the Th1/Th2 arms of the immune system. PAA-1 might be useful for the correction of Th2 dominant pathological disorders.
Macrophages play an important role in immunity. Different concentration PAA-1 can enhance proliferation of peritoneal macrophages and macrophage phagocytic function on neutral red significantly. Phagocytic activity is accompanied by the production of reactive oxygen (O~(2-)) and NO as well as the release of lysosomal enzymes such as acid phosphatase (AP) and these products is involved in killing and digesting microbial pathogens. NO plays an important role in immunity through bactericidal and antitumor.In vitro PAA-1 can increase NO secreted by macrophage. The higher reduction in NBT assay represented higher activity of oxidase enzyme, reflecting the stimulation of phagocytes in proportional to intracellular killing. The concentration of 50 mg/L PAA-1 can stimulate macrophage secret more O~(2-) to reduce NBT dye. For lysosomal enzyme activity, transformation of p-NPP to the colored compound by the acid phosphatase of the stimulated macrophages was correlated to degranulation in phagocytosis. For lysosomal enzyme activity, the 50 mg/L concentration PAA-1 exhibited the maximum potency. These results showed that PAA-1 can active macrophage, and increase Macrophage phagocytosis.
In vivo different concentrations of 0, 5, 10, 15 mg/kg PAA-1 were fed to 11-day chickens for ten days, HI antibody titer against NDV in chicken and immune organs index were detected in clinical Trials. The results showed that PAA-1 can enhance antibody level of ND and immune organs index of chickens.
All of the above tests provided scientific and experimental foundations for developing new kind immune adjuvant of PAA-1.
一种物质研究其是促进还是抑制免疫细胞的增殖,对其免疫调节活性的研究和发现新的药物都是非常重要的。体外研究表明,PAA-1具有很好的免疫调节作用,通过各种浓度(5、25、50、100 mg/L)体外刺激能单独或协同LPS或者Con A、anti-CD3mAb刺激Balb/c小鼠脾淋巴细胞增殖。Con A和LPS作为淋巴细胞的有丝分裂原,能刺激淋巴细胞有丝分裂,所以常被用来刺激T、B淋巴细胞,作为评估机体细胞和体液免疫功能的指标。Con A、anti-CD3mAb直接作用于T淋巴细胞,而LPS直接刺激B淋巴细胞。T淋巴细胞参与细胞免疫,而B淋巴细胞主要参与体液免疫反应。PAA-1可以协同LPS或Con A、anti-CD3mAb体外刺激小鼠脾淋巴细胞增殖,证明PAA-1可提高机体特异性的细胞免疫和体液免疫应答。
自然杀伤细胞(NK细胞)在机体防御系统中发挥重要作用,能通过抗肿瘤和抗病毒而发挥重要作用。NK细胞主要能识别病毒感染细胞,以及肿瘤细胞并对其起到杀伤作用,从而保护机体免受损伤。试验发现,PAA-1通过体外各种浓度刺激能激活NK细胞对YAC-1细胞的杀伤活性,说明PAA-1对于机体的非特异性免疫应答也存在一定的促进作用。
为进一步研究PAA-1体外促进淋巴细胞增殖的机制,运用流式细胞仪检测PAA-1对小鼠脾淋巴细胞表面标志CD4和CD8 T淋巴细胞亚群比例的影响,从分子水平上对其机理进行研究。CD4细胞识别MHC II类分子递呈的抗原,并通过辅助性T细胞Th1介导细胞免疫反应,通过Th2细胞介导体液免疫。CD8细胞识别MHC I类分子递呈的抗原,通过细胞毒性T细胞(Ts)调节细胞免疫反应。实验证明, PAA-1体外刺激不仅增加了CD4~+CD8~+双阳性细胞数量,而且诱导了CD4~+CD8~+向CD4~+以及CD8~+单阳性细胞方向分化增殖,显示PAA-1能刺激T淋巴细胞的分化成熟,从而发挥辅助性或杀伤性的作用。PAA-1体外能显著刺激T淋巴细胞分化成熟,表明PAA-1是通过增加成熟T淋巴细胞的比率而发挥免疫增强作用。
此外,为了进一步了解这种机制,采用双抗夹心ELISA法对Th细胞分泌的多种细胞因子进行了测定。细胞因子是一种蛋白质多肽,是细胞信号转导的分子。它们由多种类型的细胞分泌,并相互之间紧密联系,共同发挥作用。细胞因子在免疫系统中发挥重要作用,对抗各种免疫、炎症以及感染性疾病。当机体受到各种感染侵袭时,各种免疫细胞(如T细胞和巨噬细胞)分泌细胞因子对抗感染。此外,细胞因子还可以激活免疫细胞,刺激它们产生更多的细胞因子。细胞因子分泌量,对机体对抗各种感染的能力密切相关。试验发现,PAA-1各浓度在体外能协同Con A增加Th1细胞分泌的细胞因子(IL-2、IL-12、IFN-γ、TNF-a),却抑制Th2细胞分泌的细胞因子(IL-4、IL-10)。这些结果表明,Th1可能为PAA-1的靶细胞,PAA-1使Th1/Th2的平衡向Th1方向移动,这对许多的Th2占优势的免疫紊乱性疾病的治疗具有重要的意义。
巨噬细胞是参与免疫应答的一种重要细胞,具有抗原加工、提呈和免疫调节等作用,在机体特异性免疫应答中发挥重要作用。巨噬细胞可吞噬消化异物、杀灭多种病原微生物,并吞噬处理机体自身衰老死亡的组织细胞,是机体非特异性免疫的重要因素。PAA-1各种浓度体外能显著提高腹腔巨噬细胞能量代谢水平以及吞噬中性红的能力,说明PAA-1可促进巨噬细胞增殖并增强巨噬细胞的吞噬能力。只有活化的巨噬细胞的才能发挥吞噬作用,对机体的免疫反应才具有意义。巨噬细胞在免疫活化或受刺激时,能释放大量的一氧化氮自由基和活性氧等细胞效应分子,以杀伤入侵病原体和肿瘤细胞。一氧化氮(NO)是一种重要的介质分子,参与机体的多种生理与病理过程,包括神经传递和炎症;在免疫功能的调节中也起着十分广泛而复杂的作用。既是天然免疫中的一个重要免疫分子,能够发挥非特异性杀菌和杀伤肿瘤细胞的作用,又是一种重要的信使分子,可以调节获得性免疫。通过Griess法测定证实PAA-1各种浓度体外能增加小鼠腹腔巨噬细胞NO的分泌量。具有强大的杀灭微生物活性的活性氧杀灭外来入侵物的过程中,氧消耗的突然增长,生成超氧阴离子(O_2~-),从O_2~-开始,在细胞膜上进行的一系列反应导致了过氧化氢(H_2O_2)、羟自由基(·OH)、单线态氧(~1O_2)以及其他活性物质的生成,这一现象即呼吸爆发。呼吸爆发伴随着吞噬作用而产生,是吞噬细胞杀灭被吞噬微生物的另一重要机制。由于超氧阴离子(O_2~-)是呼吸爆发活动中的关键产物,因而O_2~-生成量,成为检测和评价吞噬细胞杀菌功能的重要指标。NBT还原实验证明,通过一定浓度的PAA-1体外刺激,可以增强小鼠腹腔巨噬细胞分泌的活性氧还原NBT的能力。巨噬细胞富含溶酶体酶,如酸性磷酸酶、非特异性酯酶、溶菌酶等,测定这些酶的活性也是衡量巨噬细胞功能的指标之一。经过PAA-1的体外刺激,细胞溶酶体酶的活性也提高了,说明PAA-1能可活化巨噬细胞,增强巨噬细胞的吞噬能力。
体外试验证明了PAA-1的免疫增强作用,要确定其对动物体的免疫调节作用,还应进行临床的体内试验。选用1日龄肉鸡,7日龄时进行新城疫免疫,11日龄时分别添加不同剂量PAA-1(0、5、10、15 mg/kg)10天,在14和21日龄分别采血测新城疫HI抗体效价,21日龄屠宰后测免疫器官胸腺、法氏囊、脾脏指数,结果为PAA-1能提高新城疫HI抗体效价水平,增强免疫器官指数,进一步证明了PAA-1在动物体内的增强机体细胞免疫和体液免疫的作用,为PAA-1开发成为新型的免疫增强剂提供一定的科学与实验技术依据。
Spiciferum are shrubs of Ericaceae and Rhododendron, the main production area is westen part of GUIZHOU, central and south east region of YUNNAN in China. Proanthocyanidin A-1 (PAA-1) extracted from Rhododendron spiciferum in ethylacetate is a Dimer compound of Proanthocyanidins. Proanthocyanidins (PAs) are general of Polyphenols. Recently researchs have found that PAs have many medical benefits including antioxidant, cardiovascular protection, anti-cancer, anti-platelet aggregation, immunomodulation and protection of liver and kidney function. So development of PAs drugs has great clinical prospects. Researchers have focused on potent antioxidant capacity, there have few reports related to immunomodulatory effects of PAs.
In the present studies, the immunomodulatory effects of PAA-1 were investigated in vitro. Different concentrations of 5, 25, 50 or 100 mg/L PAA-1 alone or PAA-1 plus Con A, or anti-CD3 mAb, or PAA-1 plus LPS can stimulate cell proliferation of plenocytes. A number of studys reported that potentiation of Con A, anti-CD3 mAb or LPS-induced proliferation of immunocyte by a certain compound suggested whose important effect in immune function. The evaluation of substances that either promote or inhibit immunocyte proliferation is crucial to the study of immunomodulatory and drug discovery. Con A and anti-CD3 mAb act directly on T cells, while LPS acts on B cells. T cells are involved in cell-mediated immunity whereas B cells are primarily responsible for humoral immunity. Therefore, PAA-1 could enhance both cellular immunity and humoral immunity.
NK cells are a part of innate immune system and play a major role in defending the host from both tumors and virally infected cells. Different concentrations of PAA-1 significantly enhanced NK function to kill YAC-1 target cells. PAA-1 also can enhance the nonspecific immunity.
To research the mechanism of stimulating cell proliferation of plenocytes of PAA-1 from cell level, effects of PAA-1 to ratio of two main lymphocyte T subsets (CD4+ cells or T helpers, and CD8+ cells or T cytotoxic/suppressors) in mice were detected by flow cytometer. CD4 T cells recognize antigens presented by major histocompatibility complex class II (MHC II) and mediate both cellular immune response through Th1 cells and humoral immune response through Th2 cells. CD8 recognizes antigens presented by MHC I and mediates cellular immune responses through cytotoxic T cells. In our study, a significant up regulation of the CD4+, CD8+ and CD4+CD8+ double positive cell populations after PAA-1 treatment was found. It means that PAA-1 possess immune-stimulating capacity.
We found that PAA-1 has a significant stimulatory effect on inducing the release of Th1 cytokines (IL-2, IL-12, IFN-γ, and TNF-α) and decreasing the release of Th2 cytokines (IL-4, IL-10) with Con A by ELISA kit in vitro. The results showed that PAA-1 can exert the effect of immunological regulation by up-adjusting the Th1/Th2 arms of the immune system. PAA-1 might be useful for the correction of Th2 dominant pathological disorders.
Macrophages play an important role in immunity. Different concentration PAA-1 can enhance proliferation of peritoneal macrophages and macrophage phagocytic function on neutral red significantly. Phagocytic activity is accompanied by the production of reactive oxygen (O~(2-)) and NO as well as the release of lysosomal enzymes such as acid phosphatase (AP) and these products is involved in killing and digesting microbial pathogens. NO plays an important role in immunity through bactericidal and antitumor.In vitro PAA-1 can increase NO secreted by macrophage. The higher reduction in NBT assay represented higher activity of oxidase enzyme, reflecting the stimulation of phagocytes in proportional to intracellular killing. The concentration of 50 mg/L PAA-1 can stimulate macrophage secret more O~(2-) to reduce NBT dye. For lysosomal enzyme activity, transformation of p-NPP to the colored compound by the acid phosphatase of the stimulated macrophages was correlated to degranulation in phagocytosis. For lysosomal enzyme activity, the 50 mg/L concentration PAA-1 exhibited the maximum potency. These results showed that PAA-1 can active macrophage, and increase Macrophage phagocytosis.
In vivo different concentrations of 0, 5, 10, 15 mg/kg PAA-1 were fed to 11-day chickens for ten days, HI antibody titer against NDV in chicken and immune organs index were detected in clinical Trials. The results showed that PAA-1 can enhance antibody level of ND and immune organs index of chickens.
All of the above tests provided scientific and experimental foundations for developing new kind immune adjuvant of PAA-1.
引文
[1]王红英.中药多糖研究进展[J].实用医技杂志,2006,5(6):1021~1022.
[2]薛明,孟宪松.生物活性多糖的免疫研究进展与展望[J].中兽医医药杂志, 1996,(3) : 15~18.
[3]彭新国,李彩玉,邱世翠,等.白术对小鼠免疫功能影响的实验研究[J].时珍国医国药,2001,12(5):396~397.
[4]陈志宝,张爱忠,吴海燕,等.大蒜素对贵妃鸡生产性能及免疫功能影响的初步研究[J].黑龙江畜牧兽医,2004(4):10~11.
[5]宋俊梅,王增兰,丁霄霖.白首乌总甙对小鼠免疫功能的影响[J].食品与生物技术学报,2001,20(6):588~593.
[6]周娅,佟书娟.枸杞多糖对小鼠巨噬细胞内酶活性及NO诱生的影响[J].山东中医杂志,2000,19(6):361~362.
[7]赵鹏,李彬,何为涛,等.三七皂甙对小鼠免疫功能影响的实验研究[J].中国热带医学,2004,4(4):522~524.
[8]李阳,周娅.宁夏贝母总生物碱影响小鼠免疫功能的初步研究[J].宁夏医学院学报,1997,19(3):1~4.
[9]关晓辉,曲娴,杨志萍,等.白术挥发油对小鼠免疫功能的影响[J].北华大学学报(自然科学版),2001,2(2):122~124.
[10]陈超树,吴光,肖艳芬,等.赤灵芝对小鼠非特异性免疫功能的影响[J].广西中医药,2003,26(3):56~57.
[11]柳星,袁媛.大蒜素抗肿瘤的作用机制[J].世界华人消化杂志,2004,12(11):2679~2682.
[12]沈新娥,龚珊,蒋星红,等.复方虫草精华对小鼠免疫功能的影响[J].中国血液流变学杂志,2003,13(4):327~330.
[13]牛新华,邱世翠,丁长玲.白术对小鼠骨髓细胞增殖和白细胞介素-1的影响[J].中国现代医学杂志,2002,12(3):58~60.
[14]郭明雄,孙桂鸿,张文仁,等.柴胡提取物对小鼠的体外免疫效应[J].氨基酸和生物资源,2002,24(4):59~62.
[15]华东,吴明媛,于晓红,等.赤芍总甙对荷瘤鼠细胞免疫功能的影响[J].中医药学报,2004,32(1):47~48.
[16]苗明三.大枣多糖对免疫抑制小鼠腹腔巨噬细胞产生IL-1α及脾细胞体外增殖的影响[J].中药药理与临床,2004,20(4):21~22.
[17]苗明三,方晓艳.当归补血汤多糖对大鼠血虚模型血清EL-2,IL-6,EPO水平的影响[J].中国现代应用药学,2004,21(3):27~29.
[18]庄茂辛,吴耀生.黄芪、党参、人参多糖对豚鼠免疫功能的影响[J].中国药学杂志,1992,27(11):653~655.
[19]操红缨,梁颂名,荣向路,等.二至丸对阴虚模型神经内分泌免疫网络调节作用的研究[J].中药材, 2000,23(3):164~166.
[20]孟宪丽,张艺.淫羊藿总黄酮对老年大鼠神经内分泌免疫调节作用的研究[J].中药药理与临床,1998,14(4):10~11.
[21]刘惠,李丽立,张彬,等.中草药多糖对断奶仔猪生长性能和免疫器官指数的影响[J].养猪,2007(1):5~6.
[22]邓阳勇,伍参荣,扈凤平,等.芦荟多糖对衰老小鼠免疫器官的影响湖南中医药大学学报,2008,28(2):25~27.
[23]郭新华,邱妍,严桂芹,等.板蓝根多糖对鸡新城疫抗体滴度和免疫器官指数的影响[J].饲料工业, 2007,21(16): 50~53.
[24]凌小曼,丁虹,罗顺德.当归多糖对血瘀证动物免疫功能和抗氧化功能的影响[J].中国医院药学杂志, 2002,22 (10) : 584-~586.
[25]张志敏,王建华,赵兴华,等.苦马豆素对小鼠细胞免疫功能的影响[J].西北农林科技大学学报(自然科学版),2008,36(2):61-~66.
[26]王自力,鲁琳,朱晓宇,等.中药复方对鸡免疫器官指数及IL-2表达的动态影响[J].中国兽医科学,2007,37(6):543~546.
[27]霍炳杰,刘亚娴,常靓,等.银翘散在不同煎煮时间下对免疫抑制小鼠外周血T细胞亚群及免疫器官重量的影响[J].江苏中医药,2010,42(3):72~73.
[28]宁康健,吕锦芳,应如海,等.复方杜仲口服液对肉鸡生产性能及免疫器官发育的影响[J].中兽医医药杂志,2006,25(5):20~22.
[29]吴炎,孙晓洁,陈建文,等.黄芪注射液对肝硬化患者免疫功能的影响[J].中国中西医结合杂志,2000,20(12):940~942.
[30]陈立波,王师,刘玉梅,等.人参二醇组皂苷对体外循环心内直视手术患儿免疫功能的影响[J].中国药学杂志,1999,34(1):37~39.
[31]王旭丹,周勇,张丽,等.冬虫夏草对小鼠免疫功能的影响[J].北京中医药大学学报,1998,21(6):34~36.
[32]李明春,梁东升,许自明,等.灵芝多糖体外对小鼠脾细胞lL-2、IL-3mRNA表达的影响[J].解放军药学学报,2001, (3):342-~344.
[33]候慧英,秦荣,王玉珍.蒙药广枣总黄酮对小鼠体液免疫功能的影响[J].中国民族医药杂志,1998,4(4):38~40.
[34]夏莉杰.银杏叶提取物对荷瘤小鼠免疫功能的影响[J].中华现代临床医学杂志,2007,5(12):66~68.
[35]邵兰,黄晴,刘树森.合成鱼腥草素对脾切除动物细胞免疫功能的影响[J].中国药理学通报, 2001,17(1):51~54.
[36]巫世红,胡丰,杨晨,等.绞股蓝的药理作用研究近况[J].广西中医学院学报,2008,11(1):86~88.
[37]杨铁虹,卢保华.当归多糖对小鼠免疫功能的影响[J].中国药理学通报,2003,19(4):448~451.
[38]王敏,刘旭平,张建勤,等.黄芩苷对小鼠T、B淋巴细胞增殖的影响[J].江西医学院学报,2007,47(6):17~19.
[39]王军,于震,李更生,等.地黄甙A对阴虚及免疫功能低下小鼠的药理作用[J].中国药学杂志,2002,37(l):20~23.
[40]熊平源,郭凯文,唐朝辉.淫羊藿对小鼠免疫功能的调节作用[J].数理医药学杂志,2007,20(1):223~225.
[41]石丽莎,单安山,张玮,等.女贞子对蛋鸡育成期生长发育和免疫功能的影响[J].东北农业大学学报,2009,40(10):79~84.
[42]彭光勇,周峰,丁如宁,等.莲必治注射液(穿心莲内酯)对免疫功能的调节作用[J].中国中药杂志,2002,27(2):147~150.
[43]朱华,王孝勋.蛤蚧的研究进展[J].中药材,2002,25(4):295~297.
[44] WuY,ZhangY,WuJA,et al. Effects of Erkang a modified formulation of Chinesefolk medicine Shi-Quan-Da-Bu-Tang on mice[J].J Ethnopharmacol,1998,61(2):153~156.
[45]候林江,刘洪涛.玉屏风散的免疫药理研究进展[J].中国中西医结合杂志,1998,18(11):701~702.
[46]杨雪冰,于柏龙.双黄连对免疫功能低下鼠补体系统的影响[J].中国煤炭工业医学杂志,1999,2(3):275~276.
[47]袁国红,顾立刚.当归补血汤对血细胞及相关免疫因子的作用[J].中国组织工程研究与临床康复,2007,11(28):40~43.
[48]李莉,李东,黄继华,等.注射用清开灵冻干粉抗炎及免疫调节作用研究[J].中药药理与临床,2008, (5):20~21.
[49]唐小云,王志龙,李福娟.小柴胡汤对免疫抑制小鼠的免疫调节作用[J].牡丹江医学院学报,2008,29(3):4~6.
[50]祝红焰,谭允育.八珍汤对60Co照射小鼠骨髓细胞及相关细胞因子影响的实验研究[J].中国免疫学杂志,2000,l6(2):81~82.
[51]王自然.四君子汤及加味四君子汤对商品肉鸡免疫功能的影响[J].西北农林科技大学学报(自然科学版),2008,36(2):72~76.
[52]李春荣,王升启.四物汤及其单药主要活性成分免疫药理研究进展[J].时珍国医国药,2006,(9):1624~1625.
[53]李振波,丘和明,张萍.L7121白血病小鼠IL-2活性、IL-2mRNA表达及复方中药清毒饮对其影响的研究[J].中国免疫学杂志,2000,16(1):25~28.
[54]梁毅,鲁新华,陈如泉.地甘口服液对免疫介导再生障碍性贫血小鼠胸腺细胞增殖周期的影响[J].中国中西医结合杂志,2000,20(9):689~691.
[55]欧敏,董建华,段蕴铀.清肺饮对流感病毒感染小鼠免疫功能的调节作用[J].北京中医药大学学报,1998,21 (6):19-22.
[56]王燕,赵毅.左归饮对老年小鼠抗氧化作用及胸腺脾脏指数的影响[J].中国试验方剂学杂志,2007,13(3):67~69.
[57]刘江,张建平,王林,等.虫草地黄口服液扶正固本作用研究[J].中国药房,2007,18(9):651~653.
[58]邓英杰,李经才.黄芪多糖脂质体的制备和稳定性研究[J].沈阳药科大学学报,1996,13(1):1~4.
[59]刘忞,张均田.人参皂甙Rg1对老年大鼠免疫功能的调节作用[J].药学学报,1995,30(11):818~823.
[60]史玉兰.浅谈中药在机体免疫功能中的作用[J].西南国防医药,1999,9(2):111~112
[61]齐春会,张永祥,赵修南,等.枸杞粗多糖的免疫活性[J].中国药理学与毒理学杂志,2001,15(3):180~184.
[62]刘彦平,毛辉清,李萍.枸杞多糖对小鼠T淋巴细胞亚群和淋巴细胞转化作用的研究[J].青海医学院学报,2000,21(4):4~5.
[63]曲红,王德山.枸杞多糖的药理及临床研究概况[J].山东医药工业,2002,21(4): 36~37.
[64]汪积慧,李鸿梅.枸杞多糖免疫调节作用的研究[J].齐齐哈尔医学院学报,2002, 23(11):1 204
[65]邱世翠,高法彬,彭启海.枸杞对抗体形成细胞的作用研究[J].时珍国医国药,2001,12(7):585-~586.
[66]李海波,梅之南,朱帆.枸杞多糖抗肿瘤作用免疫学机理的探讨[J].中国医院药学杂志,2005,25(2):28~29.
[67]马兴铭,赵进昌.六种多糖对小鼠免疫功能调节作用的比较[J].中药药理与临床,2003,19(4):14~15.
[68]李岩,王丽华,邹英杰.枸杞多糖增强免疫及抗脂质过氧化作用的实验研究[J].中医药学报,2003,31(2):25~26.
[69]佟书娟,王宁萍,王大军.枸杞多糖对小鼠红细胞免疫功能的影响[J].宁夏医学杂志,2000,22(5):262~263.
[70]刘彦平,李积东.枸杞多糖对小鼠NK细胞和白细胞活性的免疫调节作用[J].青海医学院学报,2001,22(1):1~2.
[71]刘美琴,李建中,孔繁祚.灵芝多糖的研究进展[J].微生物学通报,1998,25(3): 173~175.
[72] CaoL Z,Lin Z B.Comparison of the effects of polysaccharidesfrom wood- cultured and bag-cultured Ganderma lucidum on murine spleen lymphocyte proliferation in vitro[J].Acta PharmSin,2003,38(2):92~97.
[73]韩纪举,邓文,亓新国,等灵芝多糖对NK细胞活性影响的研究[J].泰山医学院学报,2002,23(2):155~156.
[74]王慧涵,王怀良.灵芝多糖的药理作用及作用机制[M].药理学进展,人民卫生出版社,2002:139~144.
[75]李明春,雷林生,王庆彪,等.灵芝多糖对小鼠T细胞胞浆游离Ca浓度和胞内pH的影响[J].中国药理学通报,2001,17(2):167~170.
[76]张洁,刘景田,党小军.黄芪多糖对荷瘤小鼠红细胞免疫功能的影响〔J〕.中国免疫学杂志,1995 ,11 (增刊) :315-317.
[77]程良斌.香菇多糖的作用机理及临床应用[J].中西医结合肝病杂志,1997,7(1):59~62.
[78]李南星,费洪宝.反复呼吸道感染患儿细胞免疫检测及香菇多糖作用初探[J].中华儿童保健杂志, 1998, 6(2): 71~73.
[79]金亨燮,崔仁花,李承宪.香菇多糖的化学结构与药理功效[J].延边大学农学学报,2004,26(2):113~114.
[80]叶丽卡,陈济民.淫羊藿多糖的药理研究进展[J].中国中药杂志,2001,26(5): 293~295.
[81]聂红,马安伦,沈佰华,等.复方猪苓多糖对小鼠免疫功能的调节[J].细胞与分子免疫学杂志,2000,16(5):384~386.
[82]鲁进宇,王汉涛,田野苹,等.云芝多糖对小鼠免疫功能的影响[J].中国药学杂志,1995,30(l):10~13.
[83]孔祥峰,胡元亮,李祥瑞,等九种中药成分对新城疫Ⅳ系疫苗免疫雏鸡血清中血凝抑制抗体水平的影响[J].畜牧兽医学报,2004,35(4):468~472.
[84]田志刚,杨贵贞.人参三醇皂甙对人白细胞介素4基因表达的促进效应[J].中国药学杂志,1992,27(1):10~11.
[85]王斌,葛志东,周爱武,等.绞股蓝总皂苷体外对免疫细胞功能的影响[J].中药新药与临床药理,1999,10(1):36~38.
[86] Li SH,Chu Y.Anti-inflammatory effects of total saponins of panax notoginse- ng.[J].Acta Pharmacologica Sinica,1999,20(6):551~554.
[87]惠飞虎,柯昕,赵亮.三七总皂苷对力竭运动大鼠血糖代谢及T淋巴细胞亚群免疫功能的影响[J].陕西中医,2008,9(2):243~244.
[88]谷子林,马学会,武现军,等.大豆黄酮对产蛋鸡免疫功能的影响[J].中国畜牧杂志,2004,40(10):15~17.
[89]马得莹,单安山.大豆黄酮对动物生长性能、内分泌和免疫功能的影响[J].东北农业大学学报,2004, 35 (4 ):505~508.
[90]阎文玫.心叶淫羊藿黄酮类化学成分研究.中国中药杂志,1998,23(12):735~737.
[91]阎文玫.粗毛淫羊藿黄酮类化学成分研究[J].中国中药杂志,1998,23(12):737~738.
[92]郝炳华,陶明,薛晚利,等.淫羊藿总黄酮对免疫抑制小鼠免疫功能的影响[J].中国实验临床免疫学杂志,1999;11:122~124.
[93]张逸凡,于庆海.淫羊藿总黄酮的免疫调节作用[J].沈阳药科大学学报,1999; 16:182~184.
[94]钟飞,蒋韵,吴芬芬,等.沙棘总黄酮对小鼠细胞免疫功能的影响[J].中草药,1989,20(7):43~46.
[95]石枫,郑维发,王莉,等.芫花根总黄酮对小鼠细胞免疫功能的调节作用[J].解放军药学学报,2004,20(4): 241~245.
[96]徐静华,于庆海,魏韶华,等.北豆根总碱对环磷酰胺模型小鼠的免疫调节作用[J].沈阳药科大学学报,1999,16(l):20~23.
[97]张丁,张杰,孟光,等.低聚原花青素及银杏黄酮对小鼠体内脂质过氧化和延缓果蝇衰老实验研究[J].河南预防医学杂志,2002,13(5):257~260.
[98] Koga T.J Agric Food Chem,1999,45(7):1892~1897.
[99] Kobayashi MS.Free Radic Res,2000,32(2):115~117.
[100] Bagchi.D Res Commun Mol Pathol Pharmacol,1998,32(4):509-513.
[101] Yinronglu, Antioxidant and radical scavenging activities of polyphenols from apple pomace[J].Food Chem,2000,68(1):81~85.
[102] Fitzpatrick DF.Bing B,Rohdewald P ,et al.Effect of procyanidins from cocal on glutathione levels in endothelial cells challenged by activated macrophages [J].Cardiovasc Pharmacol,1998,32(4):509~514.
[103] Kim SH,Kang KW,kim KW, et al. Procyanidins in crataegus extract evokeendothelium-dependent vasorelaxation in rat arota[J].Life Sci,2000,67(2):121~123
[104] Facino RM,Carini M,Aldini G,et al.Diet enriched with procyanidins enhances antioxidant activity and reduces myocardila post-ischaemic damage in rats[J].Life Sci, 1999,64(8):627~642.
[105]高军涛,呼俊改,万谦;等.葡萄籽中原花青素类(procyanidins)物质对自由基清除作用和对鼠心肌线粒体脂质过氧化损伤的保护作用的ESR波谱研究[C].第五届全国自由基生物学与自由基医学学术讨论会论文摘要汇编,2000年.
[106]高明堂,汪晨净,时小燕,等.原花青素对大鼠心肌缺血再灌注损伤的保护作用[C] .中国药理学会第八次全国代表大会论文摘要集(第二部分),2002年.
[107]凌智群,谢笔钧.莲房原花青素抗氧化损伤作用的研究[J] .食品科学,2002, 23(7):98~100.
[108]张小郁,田喧.葡萄籽中原花青素对心肌细胞的保护作用[J] .中药药理与临床,2001,17(6):14~16.
[109] Yamakoshi J, Kataoka S, Koga T, et al.Proanthocyanidin rich extract from grape seeds attenuates the development of aortic atherosclerosis in cholesterol fed rabbits [J]. Atherosclerosis, 1999,142(1):139~149.
[110]薛燕维,王峰.葡萄籽原花青素预防大鼠动脉粥样硬化作用机制研究[J] .中国实用医药,2010,(13):44~45.
[111] Huynh TH,Teel RW.Selective induction of apoptosis in human mammary cancer cell (MCF-7) by pycnogenol [J].Anticancer Res,2000,20(4):2417~2420.
[112] Agarwal C,Sharma Y,Agarwal R.Studies of procyanidins on DU145 cells of human prostatic cancer[J].Mol carcinog,2000,28(3):129.
[113]赵万洲,闫新琦,阮君山,等.葡萄籽原花青素抗促癌作用的实验研究[J]中草药,2000,31(12):917~920.
[114]陆茵,孙志广,赵万洲,等.原花青素抗促癌物诱发H2O2释放及脂质过氧化[J]中国药理学通报,2001,17(5):562~565.
[115] Bomser JA,Singletary KW,Wallig MA,et al.Inhibition of TPA-induced tumor promotion in CD-1 mouse epidermis by a polyphenolic fraction from grape seeds[J].Cancer letters, 1999, 135: 151~157.
[116] Huynh HT,Teel RW.Effects of plant-derived phenols on rat liver cytochromeP450 2B1 activity[J]. Anticancer Res,2002,22(3):1699~1703.
[117]张晓晖,穆桂平.葡萄籽原花青素对血小板凝集与实验性血栓形成的影响[J]国际中医中药杂志,2010,32(1):24~26.
[118] Putter M,Grotemeyer KH,Wurthwein G.Inhibition of smoking-induced platelet aggregation by aspirinn and pycnogenol[J] . thromb Res, 1999, 95(4):155~161.
[119] Liu FJ,Zhang YX,Lan BH.Procyanidins from the bark of Hamamelis virginiana exhibit anrimuragenic properties against nitrcaromatic compounds[J].Cell Mol Life Sci,1998,54(10):1168~1175.
[120] Cheshier JE,Ardestam Kaboudanian S,liangB,et al. Immunomodulation by pycnogenol in retrovirus-infected or ethanol fed mice[J].Life Sci,1996 ,58(5):87~96.
[121] Mao TK,Van WJ,Keen CL,et a1.Effect of cocoa flavanols and their related oligomers on the secretion of interleukin-5 in periphera bloodmononuelear cells[J].J Med Food,2002,5(1):17-~22.
[122] Takano F,Takata T,Yoshihara A,et a1. Aqueous extract of peanut skin and its main constituent procyanidin A1 suppress serum IgE and IgG1 levels in mice-immunized with ovalbumin[J].Biol pharm Bull,2007,30(5):922~927.
[123]孙志广,赵万洲,陆茵,等.葡萄籽原花青素对环磷酰胺诱发小鼠骨髓多染红细胞微核形成的抑制作用及其机理探讨[J].时珍国医国药,2000,11(5):386~389.
[124] Stefanovic V,Savic V,Vlahovic P,et al.Studies of proanthocyanidins on experimental acute renal lalure induced by glucerin[J].Ren Fail,2000, 22(3): 255~257.
[125] Avramovic V,Vlahovic P,Mihailovic D,et al.Protective effect of a bioflavonoid proanthocyanidin-BP1 in glycerol-induced acute renal failure in the rat:renal stereological study[J].Ren Fail,1999,21(6):627~630.
[126]田维毅,王文佳,李海峰,等.中性红法检测巨噬细胞吞噬功能的实验条件的优化[J].贵阳中医学院院报,2009,21(2):23~26.
[127]何金生,李瑞珠,宗庭益.MTT还原法检测NK细胞活性的方法学研究[J].中国免疫学杂志, 1996, 12(6):356~358.
[128]贺新怀.中医药免疫学[M].北京:人民军医出版社,2002∶211.
[129]王书奎,周振英.实用流式细胞术彩色图谱[M].上海:第二军医大学出版社, 2004.
[130]王世若,王兴龙,韩文瑜.现代动物免疫学[M].长春:吉林科技出版社, 2001.
[131]茅苏萍,程凯灵,周韵芬.黄芪对单疱病毒性角膜炎患者Th1Th2细胞因子的调节作用[J].中国中西医结合杂志, 2004, 24(2):121~123.
[132] Lou M Q, Lu Y C, Wang W Z, et al.IL-2、TNF-α、IFN-γand anti- CD3/anti-glioma bispecific antibodies cooperatively enhancing T lymphocytes cytotoxicity against human gliomacells[J].Acad J Sec Mil Med Univ, 2001, 22(8):724~726.
[133]茅苏萍,程凯灵.单疱病毒性角膜炎患者外周血几种细胞因子水平的改变及临床意义[J].中国实用眼科杂志, 2001, 19(3):175~177.
[134]郑金华,王健英,左丽.单纯疱疹病毒性角膜炎淋巴细胞活化状态与γ-干扰素、白细胞介素2水平关系的研究[J].贵州医药, 2005, 29(2):102~106.
[135] Hikawa N, Ishikawa Y, Takenaka T. Interleukin-12 p402 homodimer production in sensory dorsal root ganglion neurons [J]. Neuroscience, 2004, 129 (1):75~83.
[136] Ma X, Trinchieri G. Regulation of interleukin212 production in antigen- presenting cells [J]. Adv Immunol, 2001, 79:55~92.
[137] Kataoka TR, Komazawa N, Oboki K, et al. Reduced expression of IL-12 receptor beta and IL-18 receptor alpha genes in natural killer cells and macrophages derived from B62mi/ mi mice [J]. Lab Invest, 2005, 85 (1): 146~153.
[138] Musikacharoen T, Oguma A, Yoshikai Y, et al. Interleu-kin-15 induces IL-12 receptor beta1 gene expression t hrough PU. 1 and IRF 3 by targeting chromatin remodeling [J]. Blood, 2005, 105 (2) : 711~720.
[139] Flieger D, Spengler U, Beier I, et al. Enhancement of antibody dependent cellular cytotoxicity (ADCC) by combination of cytokines [J]. Hybridoma, 1999, 18:63~68.
[140] Meager A. Cytokine regulation of cellular adhesion molecule expression in inflammation [J]. Cytokine Growth Factor Rev, 1999, 10 : 27~39.
[141]毛晓辉,倪殿涛.干扰素γ在支气管哮喘发病中的作用[J].细胞与分子免疫学杂志, 2003, 19(4):415~416.
[142] PierGM, CooperM, JohnsonCP, et al.Reduetion of myoeardial nitrosyl complex formation by a nitrie oxide sea-venger prongs cardiac allograft survival [J]. J Cardiovase Pharmaeol, 2000, 35(l):114~120.
[143] Frida Soria ,Claudia Sierra ,Stephane Bouquelet et al. The effect of sugars and free amino acids from the freshwater prawn Macrobrachium rosenbergii hemolymph on lectin activity and on oxidative burst[J]. Comparative Biochemistry and Physiology,2006,142:212~219.
[144] Xingbin Yang,Yan Zhao,You Lv. In vivo macrophage activation and physicochemical property of the different polysaccharide fractions purified from Angelica sinensis[J]. Carbohydrate Polymers,2008,71:372~379.
[145] Denham S, J Rowland.Inhibition of the reactive proliferation of lymphocytes by activated macrophages:the role of nitric oxide. [J].,Clin.Exp.Immunol, 1992,87:157~162.
[146] Khalid M N. The role of nitric oxide in cardiovascular diseases. Mol Aspects Med,2005,26(1-2):33~65.
[147]张英,王盛民,贺新怀.一氧化氮的免疫功能及中药的调节作用[J].陕西中医.2002,23(12):1120~1121.
[148]魏炜,张洪渊,石安静.育珠蚌酸性磷酸酶活力与免疫反应关系的研究[J].水生生物学报.2001,25(4):413~415.
[149]朱忠勇.实用医学检验学[M].北京:人民军医出版社,1997,第一版368~378.
[150]牟海津,江晓路,刘树青,等.免疫多糖对栉孔陕北酸性磷酸酶、碱性磷酸酶和超氧化物歧化酶活性的影响[J].青岛海洋大学学报.1999,29(3):463~468.
[151]王自力,鲁琳,朱晓宇,等.中药复方对鸡免疫器官指数及IL-2表达的动态影响[J].中国兽医科学,2007,(6):543~545.
[2]薛明,孟宪松.生物活性多糖的免疫研究进展与展望[J].中兽医医药杂志, 1996,(3) : 15~18.
[3]彭新国,李彩玉,邱世翠,等.白术对小鼠免疫功能影响的实验研究[J].时珍国医国药,2001,12(5):396~397.
[4]陈志宝,张爱忠,吴海燕,等.大蒜素对贵妃鸡生产性能及免疫功能影响的初步研究[J].黑龙江畜牧兽医,2004(4):10~11.
[5]宋俊梅,王增兰,丁霄霖.白首乌总甙对小鼠免疫功能的影响[J].食品与生物技术学报,2001,20(6):588~593.
[6]周娅,佟书娟.枸杞多糖对小鼠巨噬细胞内酶活性及NO诱生的影响[J].山东中医杂志,2000,19(6):361~362.
[7]赵鹏,李彬,何为涛,等.三七皂甙对小鼠免疫功能影响的实验研究[J].中国热带医学,2004,4(4):522~524.
[8]李阳,周娅.宁夏贝母总生物碱影响小鼠免疫功能的初步研究[J].宁夏医学院学报,1997,19(3):1~4.
[9]关晓辉,曲娴,杨志萍,等.白术挥发油对小鼠免疫功能的影响[J].北华大学学报(自然科学版),2001,2(2):122~124.
[10]陈超树,吴光,肖艳芬,等.赤灵芝对小鼠非特异性免疫功能的影响[J].广西中医药,2003,26(3):56~57.
[11]柳星,袁媛.大蒜素抗肿瘤的作用机制[J].世界华人消化杂志,2004,12(11):2679~2682.
[12]沈新娥,龚珊,蒋星红,等.复方虫草精华对小鼠免疫功能的影响[J].中国血液流变学杂志,2003,13(4):327~330.
[13]牛新华,邱世翠,丁长玲.白术对小鼠骨髓细胞增殖和白细胞介素-1的影响[J].中国现代医学杂志,2002,12(3):58~60.
[14]郭明雄,孙桂鸿,张文仁,等.柴胡提取物对小鼠的体外免疫效应[J].氨基酸和生物资源,2002,24(4):59~62.
[15]华东,吴明媛,于晓红,等.赤芍总甙对荷瘤鼠细胞免疫功能的影响[J].中医药学报,2004,32(1):47~48.
[16]苗明三.大枣多糖对免疫抑制小鼠腹腔巨噬细胞产生IL-1α及脾细胞体外增殖的影响[J].中药药理与临床,2004,20(4):21~22.
[17]苗明三,方晓艳.当归补血汤多糖对大鼠血虚模型血清EL-2,IL-6,EPO水平的影响[J].中国现代应用药学,2004,21(3):27~29.
[18]庄茂辛,吴耀生.黄芪、党参、人参多糖对豚鼠免疫功能的影响[J].中国药学杂志,1992,27(11):653~655.
[19]操红缨,梁颂名,荣向路,等.二至丸对阴虚模型神经内分泌免疫网络调节作用的研究[J].中药材, 2000,23(3):164~166.
[20]孟宪丽,张艺.淫羊藿总黄酮对老年大鼠神经内分泌免疫调节作用的研究[J].中药药理与临床,1998,14(4):10~11.
[21]刘惠,李丽立,张彬,等.中草药多糖对断奶仔猪生长性能和免疫器官指数的影响[J].养猪,2007(1):5~6.
[22]邓阳勇,伍参荣,扈凤平,等.芦荟多糖对衰老小鼠免疫器官的影响湖南中医药大学学报,2008,28(2):25~27.
[23]郭新华,邱妍,严桂芹,等.板蓝根多糖对鸡新城疫抗体滴度和免疫器官指数的影响[J].饲料工业, 2007,21(16): 50~53.
[24]凌小曼,丁虹,罗顺德.当归多糖对血瘀证动物免疫功能和抗氧化功能的影响[J].中国医院药学杂志, 2002,22 (10) : 584-~586.
[25]张志敏,王建华,赵兴华,等.苦马豆素对小鼠细胞免疫功能的影响[J].西北农林科技大学学报(自然科学版),2008,36(2):61-~66.
[26]王自力,鲁琳,朱晓宇,等.中药复方对鸡免疫器官指数及IL-2表达的动态影响[J].中国兽医科学,2007,37(6):543~546.
[27]霍炳杰,刘亚娴,常靓,等.银翘散在不同煎煮时间下对免疫抑制小鼠外周血T细胞亚群及免疫器官重量的影响[J].江苏中医药,2010,42(3):72~73.
[28]宁康健,吕锦芳,应如海,等.复方杜仲口服液对肉鸡生产性能及免疫器官发育的影响[J].中兽医医药杂志,2006,25(5):20~22.
[29]吴炎,孙晓洁,陈建文,等.黄芪注射液对肝硬化患者免疫功能的影响[J].中国中西医结合杂志,2000,20(12):940~942.
[30]陈立波,王师,刘玉梅,等.人参二醇组皂苷对体外循环心内直视手术患儿免疫功能的影响[J].中国药学杂志,1999,34(1):37~39.
[31]王旭丹,周勇,张丽,等.冬虫夏草对小鼠免疫功能的影响[J].北京中医药大学学报,1998,21(6):34~36.
[32]李明春,梁东升,许自明,等.灵芝多糖体外对小鼠脾细胞lL-2、IL-3mRNA表达的影响[J].解放军药学学报,2001, (3):342-~344.
[33]候慧英,秦荣,王玉珍.蒙药广枣总黄酮对小鼠体液免疫功能的影响[J].中国民族医药杂志,1998,4(4):38~40.
[34]夏莉杰.银杏叶提取物对荷瘤小鼠免疫功能的影响[J].中华现代临床医学杂志,2007,5(12):66~68.
[35]邵兰,黄晴,刘树森.合成鱼腥草素对脾切除动物细胞免疫功能的影响[J].中国药理学通报, 2001,17(1):51~54.
[36]巫世红,胡丰,杨晨,等.绞股蓝的药理作用研究近况[J].广西中医学院学报,2008,11(1):86~88.
[37]杨铁虹,卢保华.当归多糖对小鼠免疫功能的影响[J].中国药理学通报,2003,19(4):448~451.
[38]王敏,刘旭平,张建勤,等.黄芩苷对小鼠T、B淋巴细胞增殖的影响[J].江西医学院学报,2007,47(6):17~19.
[39]王军,于震,李更生,等.地黄甙A对阴虚及免疫功能低下小鼠的药理作用[J].中国药学杂志,2002,37(l):20~23.
[40]熊平源,郭凯文,唐朝辉.淫羊藿对小鼠免疫功能的调节作用[J].数理医药学杂志,2007,20(1):223~225.
[41]石丽莎,单安山,张玮,等.女贞子对蛋鸡育成期生长发育和免疫功能的影响[J].东北农业大学学报,2009,40(10):79~84.
[42]彭光勇,周峰,丁如宁,等.莲必治注射液(穿心莲内酯)对免疫功能的调节作用[J].中国中药杂志,2002,27(2):147~150.
[43]朱华,王孝勋.蛤蚧的研究进展[J].中药材,2002,25(4):295~297.
[44] WuY,ZhangY,WuJA,et al. Effects of Erkang a modified formulation of Chinesefolk medicine Shi-Quan-Da-Bu-Tang on mice[J].J Ethnopharmacol,1998,61(2):153~156.
[45]候林江,刘洪涛.玉屏风散的免疫药理研究进展[J].中国中西医结合杂志,1998,18(11):701~702.
[46]杨雪冰,于柏龙.双黄连对免疫功能低下鼠补体系统的影响[J].中国煤炭工业医学杂志,1999,2(3):275~276.
[47]袁国红,顾立刚.当归补血汤对血细胞及相关免疫因子的作用[J].中国组织工程研究与临床康复,2007,11(28):40~43.
[48]李莉,李东,黄继华,等.注射用清开灵冻干粉抗炎及免疫调节作用研究[J].中药药理与临床,2008, (5):20~21.
[49]唐小云,王志龙,李福娟.小柴胡汤对免疫抑制小鼠的免疫调节作用[J].牡丹江医学院学报,2008,29(3):4~6.
[50]祝红焰,谭允育.八珍汤对60Co照射小鼠骨髓细胞及相关细胞因子影响的实验研究[J].中国免疫学杂志,2000,l6(2):81~82.
[51]王自然.四君子汤及加味四君子汤对商品肉鸡免疫功能的影响[J].西北农林科技大学学报(自然科学版),2008,36(2):72~76.
[52]李春荣,王升启.四物汤及其单药主要活性成分免疫药理研究进展[J].时珍国医国药,2006,(9):1624~1625.
[53]李振波,丘和明,张萍.L7121白血病小鼠IL-2活性、IL-2mRNA表达及复方中药清毒饮对其影响的研究[J].中国免疫学杂志,2000,16(1):25~28.
[54]梁毅,鲁新华,陈如泉.地甘口服液对免疫介导再生障碍性贫血小鼠胸腺细胞增殖周期的影响[J].中国中西医结合杂志,2000,20(9):689~691.
[55]欧敏,董建华,段蕴铀.清肺饮对流感病毒感染小鼠免疫功能的调节作用[J].北京中医药大学学报,1998,21 (6):19-22.
[56]王燕,赵毅.左归饮对老年小鼠抗氧化作用及胸腺脾脏指数的影响[J].中国试验方剂学杂志,2007,13(3):67~69.
[57]刘江,张建平,王林,等.虫草地黄口服液扶正固本作用研究[J].中国药房,2007,18(9):651~653.
[58]邓英杰,李经才.黄芪多糖脂质体的制备和稳定性研究[J].沈阳药科大学学报,1996,13(1):1~4.
[59]刘忞,张均田.人参皂甙Rg1对老年大鼠免疫功能的调节作用[J].药学学报,1995,30(11):818~823.
[60]史玉兰.浅谈中药在机体免疫功能中的作用[J].西南国防医药,1999,9(2):111~112
[61]齐春会,张永祥,赵修南,等.枸杞粗多糖的免疫活性[J].中国药理学与毒理学杂志,2001,15(3):180~184.
[62]刘彦平,毛辉清,李萍.枸杞多糖对小鼠T淋巴细胞亚群和淋巴细胞转化作用的研究[J].青海医学院学报,2000,21(4):4~5.
[63]曲红,王德山.枸杞多糖的药理及临床研究概况[J].山东医药工业,2002,21(4): 36~37.
[64]汪积慧,李鸿梅.枸杞多糖免疫调节作用的研究[J].齐齐哈尔医学院学报,2002, 23(11):1 204
[65]邱世翠,高法彬,彭启海.枸杞对抗体形成细胞的作用研究[J].时珍国医国药,2001,12(7):585-~586.
[66]李海波,梅之南,朱帆.枸杞多糖抗肿瘤作用免疫学机理的探讨[J].中国医院药学杂志,2005,25(2):28~29.
[67]马兴铭,赵进昌.六种多糖对小鼠免疫功能调节作用的比较[J].中药药理与临床,2003,19(4):14~15.
[68]李岩,王丽华,邹英杰.枸杞多糖增强免疫及抗脂质过氧化作用的实验研究[J].中医药学报,2003,31(2):25~26.
[69]佟书娟,王宁萍,王大军.枸杞多糖对小鼠红细胞免疫功能的影响[J].宁夏医学杂志,2000,22(5):262~263.
[70]刘彦平,李积东.枸杞多糖对小鼠NK细胞和白细胞活性的免疫调节作用[J].青海医学院学报,2001,22(1):1~2.
[71]刘美琴,李建中,孔繁祚.灵芝多糖的研究进展[J].微生物学通报,1998,25(3): 173~175.
[72] CaoL Z,Lin Z B.Comparison of the effects of polysaccharidesfrom wood- cultured and bag-cultured Ganderma lucidum on murine spleen lymphocyte proliferation in vitro[J].Acta PharmSin,2003,38(2):92~97.
[73]韩纪举,邓文,亓新国,等灵芝多糖对NK细胞活性影响的研究[J].泰山医学院学报,2002,23(2):155~156.
[74]王慧涵,王怀良.灵芝多糖的药理作用及作用机制[M].药理学进展,人民卫生出版社,2002:139~144.
[75]李明春,雷林生,王庆彪,等.灵芝多糖对小鼠T细胞胞浆游离Ca浓度和胞内pH的影响[J].中国药理学通报,2001,17(2):167~170.
[76]张洁,刘景田,党小军.黄芪多糖对荷瘤小鼠红细胞免疫功能的影响〔J〕.中国免疫学杂志,1995 ,11 (增刊) :315-317.
[77]程良斌.香菇多糖的作用机理及临床应用[J].中西医结合肝病杂志,1997,7(1):59~62.
[78]李南星,费洪宝.反复呼吸道感染患儿细胞免疫检测及香菇多糖作用初探[J].中华儿童保健杂志, 1998, 6(2): 71~73.
[79]金亨燮,崔仁花,李承宪.香菇多糖的化学结构与药理功效[J].延边大学农学学报,2004,26(2):113~114.
[80]叶丽卡,陈济民.淫羊藿多糖的药理研究进展[J].中国中药杂志,2001,26(5): 293~295.
[81]聂红,马安伦,沈佰华,等.复方猪苓多糖对小鼠免疫功能的调节[J].细胞与分子免疫学杂志,2000,16(5):384~386.
[82]鲁进宇,王汉涛,田野苹,等.云芝多糖对小鼠免疫功能的影响[J].中国药学杂志,1995,30(l):10~13.
[83]孔祥峰,胡元亮,李祥瑞,等九种中药成分对新城疫Ⅳ系疫苗免疫雏鸡血清中血凝抑制抗体水平的影响[J].畜牧兽医学报,2004,35(4):468~472.
[84]田志刚,杨贵贞.人参三醇皂甙对人白细胞介素4基因表达的促进效应[J].中国药学杂志,1992,27(1):10~11.
[85]王斌,葛志东,周爱武,等.绞股蓝总皂苷体外对免疫细胞功能的影响[J].中药新药与临床药理,1999,10(1):36~38.
[86] Li SH,Chu Y.Anti-inflammatory effects of total saponins of panax notoginse- ng.[J].Acta Pharmacologica Sinica,1999,20(6):551~554.
[87]惠飞虎,柯昕,赵亮.三七总皂苷对力竭运动大鼠血糖代谢及T淋巴细胞亚群免疫功能的影响[J].陕西中医,2008,9(2):243~244.
[88]谷子林,马学会,武现军,等.大豆黄酮对产蛋鸡免疫功能的影响[J].中国畜牧杂志,2004,40(10):15~17.
[89]马得莹,单安山.大豆黄酮对动物生长性能、内分泌和免疫功能的影响[J].东北农业大学学报,2004, 35 (4 ):505~508.
[90]阎文玫.心叶淫羊藿黄酮类化学成分研究.中国中药杂志,1998,23(12):735~737.
[91]阎文玫.粗毛淫羊藿黄酮类化学成分研究[J].中国中药杂志,1998,23(12):737~738.
[92]郝炳华,陶明,薛晚利,等.淫羊藿总黄酮对免疫抑制小鼠免疫功能的影响[J].中国实验临床免疫学杂志,1999;11:122~124.
[93]张逸凡,于庆海.淫羊藿总黄酮的免疫调节作用[J].沈阳药科大学学报,1999; 16:182~184.
[94]钟飞,蒋韵,吴芬芬,等.沙棘总黄酮对小鼠细胞免疫功能的影响[J].中草药,1989,20(7):43~46.
[95]石枫,郑维发,王莉,等.芫花根总黄酮对小鼠细胞免疫功能的调节作用[J].解放军药学学报,2004,20(4): 241~245.
[96]徐静华,于庆海,魏韶华,等.北豆根总碱对环磷酰胺模型小鼠的免疫调节作用[J].沈阳药科大学学报,1999,16(l):20~23.
[97]张丁,张杰,孟光,等.低聚原花青素及银杏黄酮对小鼠体内脂质过氧化和延缓果蝇衰老实验研究[J].河南预防医学杂志,2002,13(5):257~260.
[98] Koga T.J Agric Food Chem,1999,45(7):1892~1897.
[99] Kobayashi MS.Free Radic Res,2000,32(2):115~117.
[100] Bagchi.D Res Commun Mol Pathol Pharmacol,1998,32(4):509-513.
[101] Yinronglu, Antioxidant and radical scavenging activities of polyphenols from apple pomace[J].Food Chem,2000,68(1):81~85.
[102] Fitzpatrick DF.Bing B,Rohdewald P ,et al.Effect of procyanidins from cocal on glutathione levels in endothelial cells challenged by activated macrophages [J].Cardiovasc Pharmacol,1998,32(4):509~514.
[103] Kim SH,Kang KW,kim KW, et al. Procyanidins in crataegus extract evokeendothelium-dependent vasorelaxation in rat arota[J].Life Sci,2000,67(2):121~123
[104] Facino RM,Carini M,Aldini G,et al.Diet enriched with procyanidins enhances antioxidant activity and reduces myocardila post-ischaemic damage in rats[J].Life Sci, 1999,64(8):627~642.
[105]高军涛,呼俊改,万谦;等.葡萄籽中原花青素类(procyanidins)物质对自由基清除作用和对鼠心肌线粒体脂质过氧化损伤的保护作用的ESR波谱研究[C].第五届全国自由基生物学与自由基医学学术讨论会论文摘要汇编,2000年.
[106]高明堂,汪晨净,时小燕,等.原花青素对大鼠心肌缺血再灌注损伤的保护作用[C] .中国药理学会第八次全国代表大会论文摘要集(第二部分),2002年.
[107]凌智群,谢笔钧.莲房原花青素抗氧化损伤作用的研究[J] .食品科学,2002, 23(7):98~100.
[108]张小郁,田喧.葡萄籽中原花青素对心肌细胞的保护作用[J] .中药药理与临床,2001,17(6):14~16.
[109] Yamakoshi J, Kataoka S, Koga T, et al.Proanthocyanidin rich extract from grape seeds attenuates the development of aortic atherosclerosis in cholesterol fed rabbits [J]. Atherosclerosis, 1999,142(1):139~149.
[110]薛燕维,王峰.葡萄籽原花青素预防大鼠动脉粥样硬化作用机制研究[J] .中国实用医药,2010,(13):44~45.
[111] Huynh TH,Teel RW.Selective induction of apoptosis in human mammary cancer cell (MCF-7) by pycnogenol [J].Anticancer Res,2000,20(4):2417~2420.
[112] Agarwal C,Sharma Y,Agarwal R.Studies of procyanidins on DU145 cells of human prostatic cancer[J].Mol carcinog,2000,28(3):129.
[113]赵万洲,闫新琦,阮君山,等.葡萄籽原花青素抗促癌作用的实验研究[J]中草药,2000,31(12):917~920.
[114]陆茵,孙志广,赵万洲,等.原花青素抗促癌物诱发H2O2释放及脂质过氧化[J]中国药理学通报,2001,17(5):562~565.
[115] Bomser JA,Singletary KW,Wallig MA,et al.Inhibition of TPA-induced tumor promotion in CD-1 mouse epidermis by a polyphenolic fraction from grape seeds[J].Cancer letters, 1999, 135: 151~157.
[116] Huynh HT,Teel RW.Effects of plant-derived phenols on rat liver cytochromeP450 2B1 activity[J]. Anticancer Res,2002,22(3):1699~1703.
[117]张晓晖,穆桂平.葡萄籽原花青素对血小板凝集与实验性血栓形成的影响[J]国际中医中药杂志,2010,32(1):24~26.
[118] Putter M,Grotemeyer KH,Wurthwein G.Inhibition of smoking-induced platelet aggregation by aspirinn and pycnogenol[J] . thromb Res, 1999, 95(4):155~161.
[119] Liu FJ,Zhang YX,Lan BH.Procyanidins from the bark of Hamamelis virginiana exhibit anrimuragenic properties against nitrcaromatic compounds[J].Cell Mol Life Sci,1998,54(10):1168~1175.
[120] Cheshier JE,Ardestam Kaboudanian S,liangB,et al. Immunomodulation by pycnogenol in retrovirus-infected or ethanol fed mice[J].Life Sci,1996 ,58(5):87~96.
[121] Mao TK,Van WJ,Keen CL,et a1.Effect of cocoa flavanols and their related oligomers on the secretion of interleukin-5 in periphera bloodmononuelear cells[J].J Med Food,2002,5(1):17-~22.
[122] Takano F,Takata T,Yoshihara A,et a1. Aqueous extract of peanut skin and its main constituent procyanidin A1 suppress serum IgE and IgG1 levels in mice-immunized with ovalbumin[J].Biol pharm Bull,2007,30(5):922~927.
[123]孙志广,赵万洲,陆茵,等.葡萄籽原花青素对环磷酰胺诱发小鼠骨髓多染红细胞微核形成的抑制作用及其机理探讨[J].时珍国医国药,2000,11(5):386~389.
[124] Stefanovic V,Savic V,Vlahovic P,et al.Studies of proanthocyanidins on experimental acute renal lalure induced by glucerin[J].Ren Fail,2000, 22(3): 255~257.
[125] Avramovic V,Vlahovic P,Mihailovic D,et al.Protective effect of a bioflavonoid proanthocyanidin-BP1 in glycerol-induced acute renal failure in the rat:renal stereological study[J].Ren Fail,1999,21(6):627~630.
[126]田维毅,王文佳,李海峰,等.中性红法检测巨噬细胞吞噬功能的实验条件的优化[J].贵阳中医学院院报,2009,21(2):23~26.
[127]何金生,李瑞珠,宗庭益.MTT还原法检测NK细胞活性的方法学研究[J].中国免疫学杂志, 1996, 12(6):356~358.
[128]贺新怀.中医药免疫学[M].北京:人民军医出版社,2002∶211.
[129]王书奎,周振英.实用流式细胞术彩色图谱[M].上海:第二军医大学出版社, 2004.
[130]王世若,王兴龙,韩文瑜.现代动物免疫学[M].长春:吉林科技出版社, 2001.
[131]茅苏萍,程凯灵,周韵芬.黄芪对单疱病毒性角膜炎患者Th1Th2细胞因子的调节作用[J].中国中西医结合杂志, 2004, 24(2):121~123.
[132] Lou M Q, Lu Y C, Wang W Z, et al.IL-2、TNF-α、IFN-γand anti- CD3/anti-glioma bispecific antibodies cooperatively enhancing T lymphocytes cytotoxicity against human gliomacells[J].Acad J Sec Mil Med Univ, 2001, 22(8):724~726.
[133]茅苏萍,程凯灵.单疱病毒性角膜炎患者外周血几种细胞因子水平的改变及临床意义[J].中国实用眼科杂志, 2001, 19(3):175~177.
[134]郑金华,王健英,左丽.单纯疱疹病毒性角膜炎淋巴细胞活化状态与γ-干扰素、白细胞介素2水平关系的研究[J].贵州医药, 2005, 29(2):102~106.
[135] Hikawa N, Ishikawa Y, Takenaka T. Interleukin-12 p402 homodimer production in sensory dorsal root ganglion neurons [J]. Neuroscience, 2004, 129 (1):75~83.
[136] Ma X, Trinchieri G. Regulation of interleukin212 production in antigen- presenting cells [J]. Adv Immunol, 2001, 79:55~92.
[137] Kataoka TR, Komazawa N, Oboki K, et al. Reduced expression of IL-12 receptor beta and IL-18 receptor alpha genes in natural killer cells and macrophages derived from B62mi/ mi mice [J]. Lab Invest, 2005, 85 (1): 146~153.
[138] Musikacharoen T, Oguma A, Yoshikai Y, et al. Interleu-kin-15 induces IL-12 receptor beta1 gene expression t hrough PU. 1 and IRF 3 by targeting chromatin remodeling [J]. Blood, 2005, 105 (2) : 711~720.
[139] Flieger D, Spengler U, Beier I, et al. Enhancement of antibody dependent cellular cytotoxicity (ADCC) by combination of cytokines [J]. Hybridoma, 1999, 18:63~68.
[140] Meager A. Cytokine regulation of cellular adhesion molecule expression in inflammation [J]. Cytokine Growth Factor Rev, 1999, 10 : 27~39.
[141]毛晓辉,倪殿涛.干扰素γ在支气管哮喘发病中的作用[J].细胞与分子免疫学杂志, 2003, 19(4):415~416.
[142] PierGM, CooperM, JohnsonCP, et al.Reduetion of myoeardial nitrosyl complex formation by a nitrie oxide sea-venger prongs cardiac allograft survival [J]. J Cardiovase Pharmaeol, 2000, 35(l):114~120.
[143] Frida Soria ,Claudia Sierra ,Stephane Bouquelet et al. The effect of sugars and free amino acids from the freshwater prawn Macrobrachium rosenbergii hemolymph on lectin activity and on oxidative burst[J]. Comparative Biochemistry and Physiology,2006,142:212~219.
[144] Xingbin Yang,Yan Zhao,You Lv. In vivo macrophage activation and physicochemical property of the different polysaccharide fractions purified from Angelica sinensis[J]. Carbohydrate Polymers,2008,71:372~379.
[145] Denham S, J Rowland.Inhibition of the reactive proliferation of lymphocytes by activated macrophages:the role of nitric oxide. [J].,Clin.Exp.Immunol, 1992,87:157~162.
[146] Khalid M N. The role of nitric oxide in cardiovascular diseases. Mol Aspects Med,2005,26(1-2):33~65.
[147]张英,王盛民,贺新怀.一氧化氮的免疫功能及中药的调节作用[J].陕西中医.2002,23(12):1120~1121.
[148]魏炜,张洪渊,石安静.育珠蚌酸性磷酸酶活力与免疫反应关系的研究[J].水生生物学报.2001,25(4):413~415.
[149]朱忠勇.实用医学检验学[M].北京:人民军医出版社,1997,第一版368~378.
[150]牟海津,江晓路,刘树青,等.免疫多糖对栉孔陕北酸性磷酸酶、碱性磷酸酶和超氧化物歧化酶活性的影响[J].青岛海洋大学学报.1999,29(3):463~468.
[151]王自力,鲁琳,朱晓宇,等.中药复方对鸡免疫器官指数及IL-2表达的动态影响[J].中国兽医科学,2007,(6):543~545.