Grech Olivia, Rubio-Beltran Eloisa, Stanyer Emily C, Labastida-Ramirez Alejandro, Lavery Gareth G, Hill Lisa J, Holland Philip R, Sinclair Alexandra J
Metabolism and Systems Science, College of Medicine and Health, University of Birmingham, Birmingham B15 2TT, UK.
Biomedical Sciences, College of Medicine and Health, University of Birmingham, Birmingham B15 2TT, UK.
Brain. 2025 Jun 3;148(6):2163-2177. doi: 10.1093/brain/awae415.
Raised intracranial pressure (ICP) is associated with altered cerebral haemodynamics and cephalic pain. The relationship between the algetic response and cortical neurovascular changes in raised ICP is unclear. This study aimed to evaluate this relationship and determine whether lowering ICP (using a glucagon-like peptide-1 receptor agonist) could ameliorate the algetic response. We also sought to explore the role of calcitonin gene-related peptide in cephalic pain driven by raised ICP by inhibiting calcitonin gene-related peptide signalling and quantifying changes in the algetic response. In a rat model of raised ICP, created by intracisternal kaolin injection, mechanical thresholds were measured alongside steady-state potential and cerebral blood flow responses to spreading depolarization. Nuclear magnetic resonance spectroscopy evaluated energetic substrates in animals with raised ICP ex vivo. The glucagon-like peptide-1 receptor (GLP-1R) agonist exenatide and the calcitonin gene-related peptide receptor (CGRP-R) antagonist olcegepant were injected daily, and measurements were repeated. Kaolin increased ICP [median (range) 15.96 (8.97) mmHg, n = 8] versus controls [6.02 (1.79) mmHg, n = 6, P = 0.0007]. Animals with raised ICP exhibited reduced mechanical thresholds [mean (standard deviation) hind paw baseline: 5.78 (2.81) g, Day 7: 3.34 (2.22) g, P < 0.001; periorbital baseline: 6.13 (2.07) g, Day 7: 2.35 (1.91) g, n = 12, P < 0.001]. Depolarization and repolarization durations were increased [depolarization, raised ICP: 108.81 (222.12) s, n = 11, controls: 37.54 (108.38) s, n = 9, P = 0.038; repolarization, raised ICP: 1824.26 (3499.54) s, n = 12, controls: 86.96 (140.05) s, n = 9, P < 0.0001]. Cerebral blood flow change was also reduced [85.55 (30.84)%, n = 9] compared with controls [217.64 (37.70)%, n = 8, P < 0.0001]. Substrates for cellular energetics (ADP, ATP and NAD+) were depleted in rodent brains with raised ICP (P = 0.009, P = 0.018 and P = 0.011, respectively). Exenatide significantly lowered ICP [exenatide: 9.74 (6.09) mmHg, n = 19, vehicle: 18.27 (6.67) mmHg, n = 16, P = 0.004] and rescued changes in mechanical withdrawal. Exenatide recovered characteristic spreading depolarization responses [depolarization duration, exenatide: 56.46 (25.10) s, n = 7, vehicle: 115.98 (58.80) s, n = 6, P = 0.033; repolarization duration, exenatide: 177.55 (562.88) s, n = 7, vehicle: 800.85 (1988.67) s, n = 6, P = 0.002]. In the setting of raised ICP, olcegepant prevented changes in periorbital mechanical thresholds. We conclude that raised ICP disrupted the cortical neurovascular responses, reduced algetic thresholds and depleted crucial energetic substrates. Exenatide reduced ICP, improving algetic thresholds and cortical neurovascular changes. Importantly, olcegepant alleviated the cerebral algesia, suggesting a role for calcitonin gene-related peptide in driving pain responses in elevated ICP. These studies support the rationale that reducing ICP improves cephalic pain in conditions of raised ICP. Furthermore, the data suggest that headache pain in diseases associated with raised ICP could be ameliorated therapeutically though blockade of the calcitonin gene-related peptide pathway.
颅内压升高(ICP)与脑血流动力学改变和头痛相关。ICP升高时痛觉反应与皮质神经血管变化之间的关系尚不清楚。本研究旨在评估这种关系,并确定降低ICP(使用胰高血糖素样肽-1受体激动剂)是否能改善痛觉反应。我们还试图通过抑制降钙素基因相关肽信号传导并量化痛觉反应的变化,来探索降钙素基因相关肽在ICP升高引起的头痛中的作用。在通过脑池内注射高岭土建立的ICP升高大鼠模型中,测量机械阈值以及对扩散性去极化的稳态电位和脑血流反应。通过核磁共振波谱法评估离体ICP升高动物体内的能量底物。每天注射胰高血糖素样肽-1受体(GLP-1R)激动剂艾塞那肽和降钙素基因相关肽受体(CGRP-R)拮抗剂olcegepant,并重复测量。与对照组[6.02(1.79)mmHg,n = 6,P = 0.0007]相比,高岭土使ICP升高[中位数(范围)15.96(8.97)mmHg,n = 8]。ICP升高的动物机械阈值降低[平均(标准差)后爪基线:5.78(2.81)g,第7天:3.34(2.22)g,P < 0.001;眶周基线:6.13(2.07)g,第7天:2.35(1.91)g,n = 12,P < 0.001]。去极化和复极化持续时间增加[去极化,ICP升高:108.81(222.12)s,n = 11,对照组:37.54(108.38)s,n = 9,P = 0.038;复极化,ICP升高:1824.26(3499.54)s,n = 12,对照组:86.96(140.05)s,n = 9,P < 0.0001]。与对照组[217.64(37.70)%,n = 8,P < 0.0001]相比,脑血流变化也减少[85.55(30.84)%,n = 9]。ICP升高的啮齿动物脑内细胞能量代谢底物(ADP、ATP和NAD+)减少(分别为P = 0.009、P = 0.018和P = 0.011)。艾塞那肽显著降低ICP[艾塞那肽:9.74(6.09)mmHg,n = 19,载体:18.27(6.67)mmHg,n = 16,P = 0.004]并挽救了机械性退缩的变化。艾塞那肽恢复了特征性的扩散性去极化反应[去极化持续时间,艾塞那肽:56.46(25.10)s,n = 7,载体:115.98(58.80)s,n = 6,P = 0.033;复极化持续时间,艾塞那肽:177.55(562.88)s,n = 7,载体:800.85(1988.67)s,n = 6,P = 0.002]。在ICP升高的情况下,olcegepant可防止眶周机械阈值的变化。我们得出结论,ICP升高会破坏皮质神经血管反应,降低痛觉阈值并消耗关键的能量底物。艾塞那肽降低ICP,改善痛觉阈值和皮质神经血管变化。重要的是,olcegepant减轻了脑部疼痛,表明降钙素基因相关肽在ICP升高时驱动疼痛反应中起作用。这些研究支持降低ICP可改善ICP升高情况下头痛的理论依据。此外,数据表明,通过阻断降钙素基因相关肽途径,与ICP升高相关疾病中的头痛疼痛可能会得到治疗改善。
