Benjamin Drenger1, Yakov Fellig2, Dror Ben-David3, Bella Mintz4, Suhel Idrees4, Omer Or3, Leon Kaplan3, Yehuda Ginosar4, Yair Barzilay3. 1. Department of Anesthesiology and Critical Care Medicine. Electronic address: drenger@huji.ac.il. 2. Department of Pathology, Hadassah-Hebrew University Medical Center, Jerusalem, Israel. 3. Department of Orthopedic Surgery, Hadassah-Hebrew University Medical Center, Jerusalem, Israel. 4. Department of Anesthesiology and Critical Care Medicine.
Abstract
OBJECTIVES: To identify the minocycline anti-inflammatory and antiapoptotic mechanisms through which it is believed to exert spinal cord protection during aortic occlusion in the rabbit model. DESIGN: An animal model of aortic occlusion-related spinal cord ischemia. Randomized study with a control group and pre-ischemia and post-ischemia escalating doses of minocycline to high-dose minocycline in the presence of either hyperglycemia, a pro-apoptotic maneuver, or wortmannin, a specific phosphatidylinositol 3-kinase antagonist. SETTING: Tertiary medical center and school of medicine laboratory. PARTICIPANTS: Laboratory animals-rabbits. INTERVENTIONS: Balloon obstruction of infrarenal aorta introduced via femoral artery incision. RESULTS: Severe hindlimb paralysis (mean Tarlov score 0.36±0.81 out of 3) was observed in all the control group animals (9 of 11 with paraplegia and 2 of 11 with paraparesis) compared with 11 of 12 neurologically intact animals (mean Tarlov score 2.58±0.90 [p = 0.001 compared with control]) in the high-dose minocycline group. This protective effect was observed partially during a state of hyperglycemia and was completely abrogated by wortmannin. Minocycline administration resulted in higher neurologic scores (p = 0.003) and a shift to viable neurons and more apoptotic-stained nuclei resulting from reduced necrosis (p = 0.001). CONCLUSIONS: In a rabbit model of infrarenal aortic occlusion, minocycline effectively reduced paraplegia by increasing the number of viable neurons in a dose-dependent manner. Its action was completely abrogated by inhibiting the phosphatidylinositol 3-kinase pathway and was inhibited partially by the pro-apoptotic hyperglycemia maneuver, indicating that the activation of cell salvage pathways and mitochondrial sites are possible targets of minocycline action in an ischemic spinal cord.
OBJECTIVES: To identify the minocycline anti-inflammatory and antiapoptotic mechanisms through which it is believed to exert spinal cord protection during aortic occlusion in the rabbit model. DESIGN: An animal model of aortic occlusion-related spinal cord ischemia. Randomized study with a control group and pre-ischemia and post-ischemia escalating doses of minocycline to high-dose minocycline in the presence of either hyperglycemia, a pro-apoptotic maneuver, or wortmannin, a specific phosphatidylinositol 3-kinase antagonist. SETTING: Tertiary medical center and school of medicine laboratory. PARTICIPANTS: Laboratory animals-rabbits. INTERVENTIONS: Balloon obstruction of infrarenal aorta introduced via femoral artery incision. RESULTS: Severe hindlimb paralysis (mean Tarlov score 0.36±0.81 out of 3) was observed in all the control group animals (9 of 11 with paraplegia and 2 of 11 with paraparesis) compared with 11 of 12 neurologically intact animals (mean Tarlov score 2.58±0.90 [p = 0.001 compared with control]) in the high-dose minocycline group. This protective effect was observed partially during a state of hyperglycemia and was completely abrogated by wortmannin. Minocycline administration resulted in higher neurologic scores (p = 0.003) and a shift to viable neurons and more apoptotic-stained nuclei resulting from reduced necrosis (p = 0.001). CONCLUSIONS: In a rabbit model of infrarenal aortic occlusion, minocycline effectively reduced paraplegia by increasing the number of viable neurons in a dose-dependent manner. Its action was completely abrogated by inhibiting the phosphatidylinositol 3-kinase pathway and was inhibited partially by the pro-apoptotic hyperglycemia maneuver, indicating that the activation of cell salvage pathways and mitochondrial sites are possible targets of minocycline action in an ischemic spinal cord.
Authors: Dae Young Yoo; Su Bin Cho; Hyo Young Jung; Woosuk Kim; Goang-Min Choi; Moo-Ho Won; Dae Won Kim; In Koo Hwang; Soo Young Choi; Seung Myung Moon Journal: Cell Death Dis Date: 2017-10-05 Impact factor: 8.469