Permeability to bloodbrain burrier of 125Ⅰ-nerve growth factor after focal cerebral ischemia#br#

doi:10.16098/j.issn.0529-1356.2020.03.006

Abstract

Abstract:

Objective To investigate the optimal time and mechanism of nerve growth factor（NGF）crossing the bloodbrain barrier (BBB) under cerebral ischemia in rats through focal cerebral ischemia experiments in rats, and to provide a new way for the clinical application of NGF. Methods A total of 65 healthy Sprague-Dawlay (SD) male rats were prepared by using a modified suture method to prepare focal cerebral ischemia models. Rats were injected with 125Ⅰ-NGF, and the γ count was measured with a γ-ray counter to observe the changes in BBB permeability at different times of ischemia. At the time point at which BBB permeability was greatest after cerebral ischemia (3 days ischemia), the rats were used as the experimental group (n=15). Coronal sections of the rats were subjected to autoradiography, and the imaging site, area and brightness were observed. The changes of blood-brain barrier at different times of cerebral ischemia with transmission electron microscope were observed. Results With the prolongation of cerebral ischemia time, the permeability of BBB increased gradually, and the permeability of BBB was the largest after 3 days of cerebral ischemia, and then weakened gradually. With the same permeability of BBB, the γ count showed that the γ counts of the control group and the experimental group increased with the prolonged medication time. The γ counts of the experimental group at each time point were higher than the control group. Significant difference (P<0.05) was found, and the highest γ count at 4 hours. The result of autoradiography showed that the entire brain was not developed in the control group for 1 hour, and the ventricles and periventricular brain tissues were developed in 4 hours and 7 hours. The area occupied about 4.1% of the cerebral coronal section, and the brightness was obvious. The area was about 6% of the coronal section of the brain, and the brightness was strong. In addition to the development of the ventricles and periventricular brain tissues at 4 hours and 7 hours, in the right frontal lobe (FL), parietal lobe (AL) and temporal lobe, there was a large area in the medulla and the medulla, which covered 36.2% to 47.3% of the coronal section of the brain. The brightness was very strong. Conclusion BBB permeability increases with prolonged cerebral ischemia in rats, of which the permeability is the strongest at 3 days of ischemia; rats with focal cerebral ischemia at 3 days for 4 hours, 125Ⅰ-NGF enters the BBB in the largest amount, in the frontal and parietal. The temporal lobe is most obvious. NGF can pass the blood-brain barrier of focal cerebral ischemia and may become a new breakthrough in clinical drug delivery.

Key words: Focal cerebral ischemia, Blood-brain barrier, Nerve growth factor, Reforming longa method, Autoradiography, Transmission electron microscopy, Rat

CLC Number:

R743

ZHENG Qian MA Xin-yu CAO Zhong-wei. Permeability to bloodbrain burrier of 125Ⅰ-nerve growth factor after focal cerebral ischemia#br#[J]. Acta Anatomica Sinica, 2020, 51(3): 344-351.

References

［1］ Schabitz UR, Sommer C, Zoder W, et al intravenous BDNF reduces infaret size and counlerregulates Bax and Bel-2 expression after temporary focal cerebral ischemia［J］.Stroke, 2003,31(9):2212-2217.

［2］ Levi MR. The nerve growth factor 35 years later ［J］.Science, 2011, 237 (4819):1154-1162.

［3］ Chiaretti A, Falsini B, Aloe L, et al. Neuroprotective role of nerve growth factor in hypoxic ischemic injury［J］. Arch Ital Biol, 2011, 149(2):275-282.

［4］ Longa EZ, Weinstein PR, Carlson S, et al. Reversible middle cerebral artery occlusion without craniectomy in rats［J］. Stroke, 2011, 20(1):84-91.

［5］ Luo Y, Dong WW. Experimental study on focal cerebral ischemia/reperfusion model by Wistar rat insertion method ［J］. Journal of Chongqing Medical University, 2002, 27 (1):1-3.(in Chinese)

罗勇, 董为伟. Wistar大鼠插线法局灶性脑缺血/再灌注模型的实验研究［J］.重庆医科大学学报, 2002, 27（1）:1-3.

［6］ Liu XW, Tang ZhM, Chai BX. Preparation of high purity125Ⅰ-nerve growth factor ［J］. Academy of Military Medical Sciences,1998,11(3):144-148.(in Chinese)

刘秀文,汤仲明,柴彪新.高纯度125Ⅰ-神经生长因子的制备［J］.军事医学科学院院报,1998,11(3):144-148.

［7］ Liu XW, Dai ShJ, Liao Zh, et al. Tissue distribution after epidural and intravenous injection of tigerotoxin-Ⅰ in rats ［J］. Chinese Journal of Pharmacology and Toxicology, 2003, 17(2):146-150. (in Chinese)

刘秀文,戴舒佳,廖智,等.大鼠硬膜外和静脉注射虎纹毒素-Ⅰ后的组织分布［J］.中国药理学与毒理学杂志,2003,17(2):146-150.

［8］ Tang GH, Jiang GH, Zhang Y, et al. Study on the pharmacokinetics of nerve growth factor by iodine-labeled tracer precipitation method ［J］. Journal of China Pharmaceutical University,2003,31(3):180-183. (in Chinese)

唐刚华，姜国辉，张云,等. 碘标记示踪沉淀法研究神经生长因子的药代动力学［J］，中国药科大学学报.2003,31(3):180-183.

［9］ Diao Y, Li YM, Zhou MK, et al. Autoradiography of (99) TC-m-hl91 in ischemic brain of rats ［J］. Chinese Journal of Nuclear Medicine, 2005,5(3):88-91. (in Chinese)

刁尧，李亚明，周明坤,等.（99）TC-m-hl91在大鼠缺血脑内分布的放射自显影观察［J］.中华核医学杂志,2005,5(3):88-91.

［10］ Crupi R, Di Paola R, Esposito E, et al. Middle cerebral artery occlusion by an intraluminal suture method ［J］. Methods Mol Biol, 2018,1727:393-401.

［11］ Hayakawa K, Itoh T, Niwa H, et al. NGF prevention of neurotoxicity induced by cisplatin,vincristine and taxol depends on toxicity of each drug and NGF treatment schedule: in vitro study of adult rat sympathetic ganglion explants［J］.Brain Res,2011,794(2):313-319.

［12］ McCarthy KD, Vellis JD. Preparation of separate troglial and oligeledroglial cell cultures from rat cerebral tissue ［J］.J Cell Biol, 2010,85(3):890-902.

［13］ Aoki T, Sumii T. Blood-brain barrier disruption and matrix metaloproteimase-9 expression and during reperfusion injury mechanical versus embolic focal ischemia in spontaneously nypertensive rats ［J］.Stroke,2010,33(11):2711

［14］ Eriksdotter Jonhagen M, Nordberg A, Amberla K, et al. Intracere-broventricular infusion of nerve growth factor in three patients with Alzheimer’ s disease［J］. Dement Geriatr Cogn Disord, 2008,9(5):246-257.

［15］ Yasunaga A. Experimental cerebral infarction in dog；ultrastructural study of microvasculature in recanalization model ［J］.Neurol Med Chir (Tokyo),2010, 22（3）:185-187.

［16］ Raub TJ. Signal transduction and glial cell modulation of cultured brain microvessel endothelial cell tight junction ［J］. Am J Physiol,2006, 271(2 Pt1):c495-503.

［17］ Herman IM, Pollard TD, Wong AJ. Contractile proteins in endothelial cells［J］.Ann N Y Acad Sci,1982,401:50-60.

［18］ Yang L，Li DC，Chen ShY. Hydrogen water reduces NSE，IL-6，and TNF-αlevels in hypoxic-ischemic encephalopathy［J］. Open Med(Wars)，2016，11(1):399-406.

［19］ Li SJ，Liu W，Wang JL，et al. The role of TNF-α，IL-6，IL-10，and GDNF in neuronal apoptosis in neonatal rat with hypoxic-ischemic Encephalopathy［J］.Eur Rev Med Pharmacol Sci，2014，18(6): 905-909.

［20］ Liu X, Ma X, Wei X, et al. Ting Fan.Neuroprotective effect of licochalcone a against oxygen-glucose deprivation/reperfusion in rat primary cortical neurons by attenuating oxidative stress injury and inflammatory response via the SIRT1/Nrf2 pathway［J］.J Cell Biochem, 2018,119(4):3210-3219.

［21］ Bundgaard M. Tubular invaginations in cerebral endothelium and their relation to smooth-surfaced cisternae in hagfish (Myxine glutinosa)［J］.Cell Tissue Res, 1987, 249 (2):359-365.

［22］ Kim GM，Lewen A，Copin J，et al. The cytosolic antioxclant,copper/zinc superoxide dismutase, attenuates blood-brain barrier disruption and oxidative cellular injury after photothrombotic cortical ischemia in mice［J］. Neuroscience, 2001, 105(4):1007-1018.

［23］ Asahi M, Wang X, Morri T, et al. Effects of matrix metalloproteinase-9 gene Knock-out on the proteolysis of blood-brain barrier and white matter components after cerebral ischemia［J］.J Neurosci,2008,21(19):7724-7732.

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