磁场对丘脑下部一氧化氮含量的影响及与丘脑下部神经内分泌核团的关系

应用硝酸还原酶反应—分光光度法测定和NADPH-d组织化学技术，对磁场处理后丘脑下部一氧化氮量的变化及其可能的原因进行了研究，发现磁场可促使丘脑下部一氧化氮量(OD值)显著升高，并具有显著滞后效应。NADPH-d阳性神经细胞及NADPH-d和血管加压素(AVP)双染阳性神经细胞集中分布在丘脑下部室旁核、室周核和视上核，但不存在 于视交叉上核，提示室旁核、室周核和视上核一氧化氮能神经细胞是丘脑下部的一氧化氮的主要来源。磁场处理后大鼠丘脑下部一氧化氮含量(OD值)较正常对照组显著升高应归因于这些神经细胞受磁场作用表达增强。一氧化氮和血管加压素的共存可能对磁场调节内分泌具有一定意义。

INFLUENCE OF MAGNETIC FIELD ON NITRIC OXIDE IN HYPOTHALAMUS AND ITS RELATION TO HYPOTHALAMIC NEUROENDOCRINE NUCLEI

By employing nitric acid reductase-spec-trophotometry and NADPH-diaphorase/AVP cytochemistry technique, the effects of magnetic field on NO in hypothalamus and relations to Paraventricular Nucleus ( PVN ), Periventricular Nucleus (PEN), Supraoptic Nucleus (SON) and Suprachiasmatic Nucleus (SCN) were investigated. It was found that the NADPH-d positive neurons and some NADPH-d/AVP dually stained neurons existed in PVN, PEN, SON, but not in SCN, and the magnetic field induced NO (OD) increase there and the high NO (OD) level lasted for 3 hours. The results suggested that NO (OD) increase after the treatment of magnetic field in hypothalamus may result from strong expression of NOergic neurons in the PVN, PEN and SON. The coexistance of NO and AVP may play important role in the regulation of endocrine and neuroendocrine by the magnetic field.