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Effect of convection enhanced delivery on the microstructure of brain extracellular space in aged rats
Received date: 2019-09-02
Online published: 2020-04-18
Supported by
Supported by the Beijing Municipal Science & Technology Commission(Z181100001518004);the National Major Scientific Research Instrument Development Project(61827808);the Program for Training Capital Science and Technology Leading Talents(Z181100006318003)
Objective: To compare the changes of extracellular space (ECS) structure and local drug distribution in adult brain and aged brain at different drug delivery rates in minimally invasive treatment of encephalopathy by convection enhanced delivery (CED) via ECS pathway.Methods: Thirty-six SD male rats were divided into adult rats group (2-8 months, n=18) and aged rats group (18-24 months, n=18) according to the age of the month. According to the drug rates (0.1 μL/min, 0.2 μL/min, and 0.3 μL/min), they were randomly divided into 3 subgroups, 6 in each subgroup. Gadolinium-diethylene triamine pentaacetic acid (Gd-DTPA) with a concentration of 10 mmol/L were introduced into the caudate nucleus of each group of rats by stereotactic injection. Tracer-based magnetic resonance imaging (MRI) was used to dynamically monitor the diffusion and distribution images of the Gd-DTPA in the brain interstitial system (ISS). Using the self-developed MRI image measurement and analysis system software to process and analyze the obtained images, the diffusion coefficient, clearance rate, volume fraction, and half-life of each group of rats in the caudate nucleus ECS could be acquired. The effects and differences of drug clearance and ECS structural function in the brain of aged rats and adult rats were compared and analyzed at different drug delivery rates. Magnetic tracer DECS-mapping technique was used to observe the distribution and drainage of tracer in caudate nucleus.Results: At the injection rate of 0.1 μL/min, the volume fraction in the aged rats was increased compared with that in the adult rats (18.20%±0.04% vs. 17.20%±0.03%, t=3.752, P=0.004), and the degree of tortuosity was decreased (1.63±0.04 vs. 1.78±0.09, t=-3.680, P=0.004), the drug clearance rate was decreased [(1.94±0.68) mm 2/s vs. (3.25±0.43) mm 2/s, t=-3.971, P=0.003], and the molecular diffusion in ECS was increased [(3.99±0.21)×10 -4 mm 2/s vs. (3.36±0.37)×10 -4 mm 2/s, t=3.663, P=0.004]. When the rate of injection increased to 0.2 μL/min, the drug clearance in ECS of the aged rats was slowed down [(2.53±0.45) mmol/L vs. (3.37±0.72) mmol/L, t=-1.828, P=0.021]. However, there were no significant differences in volume fraction,molecular diffusion in ECS and macroscopic drug metabolism parameters. When the rate of injection increased to 0.3 μL/min, the volume fraction in the aged rats was decreased (17.20%±0.03% vs. 18.20%±0.05%, t=-0.869, P=0.045), and the drug clearance rate in ECS was significantly accelerated [(4.04±0.76) mmol/L vs. (3.26±0.55) mmol/L, t=1.786, P=0.014], and there was no significant difference in tortuosity and the rate of molecular diffusion in the ECS. Conclusion: The drug clearance and ECS structural parameters of brain ECS in aged brain with CED administration were changed at different rates, and it has the least effect on ECS in the aged brain at the injection rate of 0.2 μL/min. For the application of CED for the treatment of encephalopathy, we should consider the influence of factors such as age and injection rate, and provide reference for the development of individualized clinical treatment plan for minimally invasive treatment of encephalopathy via ECS pathway.
Yu SONG , Hong-bin HAN , Jun YANG , Ai-bo WANG , Qing-yuan HE , Yuan-yuan LI , Guo-mei ZHAO , Ya-juan GAO , Rui WANG , Yi-xing HAN , Ai-lian LIU , Qing-wei SONG . Effect of convection enhanced delivery on the microstructure of brain extracellular space in aged rats[J]. Journal of Peking University(Health Sciences), 2020 , 52(2) : 362 -367 . DOI: 10.19723/j.issn.1671-167X.2020.02.026
| [1] | Mehta AM, Sonabend AM, Bruce JN . Convection-enhanced deli-very[J]. Neurotherapeutics, 2017,14(2):358-371. |
| [2] | Souweidane MM, Singh R, Zhou Z . Convection-enhanced delivery for diffuse intrinsic pontine glioma treatment[J]. Curr Neuropharmacol, 2017,15(1):116-128. |
| [3] | Lei Y, Han H, Yuan F , et al. Brain interstitial system: anatomy, modeling, in vivo measurement, and application[J]. Prog Neurobiol, 2016,157:230-246. |
| [4] | Nicholson C, Hrabětová S . Brain extracellular space: the final frontier of neuroscience[J]. Biophys J, 2017,113(10):1-10. |
| [5] | Himes BT, Zhang L, Daniels DJ . Treatment strategies in diffuse midline gliomas with the H3K27M mutation: the role of convection-enhanced delivery in overcoming anatomic challenges[J]. Front Oncol, 2019,9:31. |
| [6] | Oertel W, Schulz JB . Current and experimental treatments of Parkinson disease: A guide for neuroscientists[J]. J Neurochem, 2016,139(Suppl 1):325-337. |
| [7] | Chen PY, Yeh CK, Hsu PH , et al. Drug-carrying microbubbles as a theranostic tool in convection-enhanced delivery for brain tumor therapy[J]. Oncotarget, 2017,8(26):42359-42371. |
| [8] | Fan X, Nelson BD, Ai Y , et al. Continuous intraputamenal convection-enhanced delivery in adult rhesus macaques[J]. J Neurosurg, 2015,123(6):1569-1577. |
| [9] | Sugiyama SI, Saito R, Nakamura T , et al. Safety and feasibility of convection-enhanced delivery of nimustine hydrochloride co-infused with free gadolinium for real-time monitoring in the primate brain[J]. Neurol Res, 2012,34(6):581-587. |
| [10] | Hou J, Wang W, Quan X , et al. Quantitative visualization of dynamic tracer transportation in the extracellular space of deep brain regions using tracer-based magnetic resonance imaging[J]. Med Sci Monit, 2017,23:4260-4268. |
| [11] | Han H, Shi C, Fu Y , et al. A novel mri tracer-based method for measuring water diffusion in the extracellular space of the rat brain[J]. IEEE J Biomed Health Inform, 2014,18(3):978-983. |
| [12] | Daneman R, Prat A . The blood-brain barrier[J]. Cold Spring Harb Perspect Biol, 2015,7(1):a020412. |
| [13] | Zhan W, Alamer M, Xu XY . Computational modelling of drug delivery to solid tumour: Understanding the interplay between chemotherapeutics and biological system for optimised delivery systems[J]. Adv Drug Deliv Rev, 2018,132:81-103. |
| [14] | Miners JS, Barua N, Kehoe PG , et al. Aβ-degrading enzymes: potential for treatment of Alzheimer disease[J]. J Neuropathol Exp Neurol, 2011,70(11):944-959. |
| [15] | Han HB, Xia ZL, Chen H , et al. Simple diffusion delivery via brain interstitial route for the treatment of cerebral ischemia[J]. Sci China Life Sci, 2011,54(3):235-239. |
| [16] | Xu F, Han H, Yan J , et al. Greatly improved neuroprotective efficiency of citicoline by stereotactic delivery in treatment of ischemic injury[J]. Drug Deliv, 2011,18(7):461-467. |
| [17] | Bobo RH, Laske DW, Akbasak A , et al. Convection-enhanced delivery of macromolecules in the brain[J]. Proc Natl Acad Sci USA, 1994,91(6):2076-2080. |
| [18] | Chittiboina P, Heiss JD, Warren KE , et al. Magnetic resonance imaging properties of convective delivery in diffuse intrinsic pontine gliomas[J]. J Neurosurg Pediatr, 2014,13(3):276-282. |
| [19] | Miranpuri GS, Kumbier L, Hinchman A , et al. Gene-based therapy of Parkinson's disease: Translation from animal model to human clinical trial employing convection enhanced delivery[J]. Ann of Neurosci, 2012,19(3):133-146. |
| [20] | Whone A, Luz M, Boca M , et al. Randomized trial of intermittent intraputamenal glial cell line-derived neurotrophic factor in Parkinson's disease[J]. Brain, 2019,142(3):512-525. |
| [21] | Souweidane MM, Kim K, Neeta PT , et al. Convection-enhanced delivery for diffuse intrinsic pontine glioma: a single-centre, dose-escalation, phase 1 trial[J]. Lancet Oncol, 2018,19(8):1040-1050. |
| [22] | Bishop NA, Lu T, Yankner BA . Neural mechanisms of ageing and cognitive decline[J]. Nature, 2010,464(7288):529-535. |
| [23] | Aibo W, Rui W, Dehua C , et al. The drainage of interstitial fluid in the deep brain is controlled by the integrity of myelination[J]. Aging Dis, 2019,10(5):937-948. |
| [24] | Syková E, Nicholson C . Diffusion in brain extracellular space[J]. Physiol Rev, 2008,88(4):1277-1340. |
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