TY - JOUR
T1 - Novel methods for intranasal administration under inhalation anesthesia to evaluate nose-to-brain drug delivery
AU - Kanazawa, Takanori
AU - Fukuda, Mitsuyoshi
AU - Suzuki, Naoto
AU - Suzuki, Toyofumi
N1 - Publisher Copyright:
© 2018 Journal of Visualized Experiments.
PY - 2018/11
Y1 - 2018/11
N2 - Intranasal administration has been reported to be a potential pathway for nose-to-brain delivery of therapeutic agents that circumvents the blood-brain barrier. However, there have been few reports regarding not only the quantitative analysis but also optimal administration conditions and dosing regimens for investigations of nose-to-brain delivery. The limited progress in research on nose-to-brain pathway mechanisms using rodents represents a significant impediment in terms of designing nose-to-brain delivery systems for candidate drugs. To gain some headway in this regard, we developed and evaluated two novel methods of stable intranasal administration under inhalation anesthesia for experimental animals. We also describe a method for the evaluation of drug distribution levels in the brain via the nose-to-brain pathway using radio-labeled [ 14 C]-inulin (molecular weight: 5,000) as a model substrate of water-soluble macromolecules. Initially, we developed a pipette-based intranasal administration protocol using temporarily openable masks, which enabled us to perform reliable administration to animals under stable anesthesia. Using this system, [ 14 C]-inulin could be delivered to the brain with little experimental error. We subsequently developed an intranasal administration protocol entailing reverse cannulation from the airway side through the esophagus, which was developed to minimize the effects of mucociliary clearance (MC). This technique led to significantly higher levels of [ 14 C]-inulin, which was quantitatively detected in the olfactory bulb, cerebrum, and medulla oblongata, than the pipette method. This appears to be because retention of the drug solution in the nasal cavity was substantially increased by active administration using a syringe pump in a direction opposite to the MC into the nasal cavity. In conclusion, the two methods of intranasal administration developed in this study can be expected to be extremely useful techniques for evaluating pharmacokinetics in rodents. The reverse cannulation method, in particular, could be useful for evaluating the full potential of nose-to-brain delivery of drug candidates.
AB - Intranasal administration has been reported to be a potential pathway for nose-to-brain delivery of therapeutic agents that circumvents the blood-brain barrier. However, there have been few reports regarding not only the quantitative analysis but also optimal administration conditions and dosing regimens for investigations of nose-to-brain delivery. The limited progress in research on nose-to-brain pathway mechanisms using rodents represents a significant impediment in terms of designing nose-to-brain delivery systems for candidate drugs. To gain some headway in this regard, we developed and evaluated two novel methods of stable intranasal administration under inhalation anesthesia for experimental animals. We also describe a method for the evaluation of drug distribution levels in the brain via the nose-to-brain pathway using radio-labeled [ 14 C]-inulin (molecular weight: 5,000) as a model substrate of water-soluble macromolecules. Initially, we developed a pipette-based intranasal administration protocol using temporarily openable masks, which enabled us to perform reliable administration to animals under stable anesthesia. Using this system, [ 14 C]-inulin could be delivered to the brain with little experimental error. We subsequently developed an intranasal administration protocol entailing reverse cannulation from the airway side through the esophagus, which was developed to minimize the effects of mucociliary clearance (MC). This technique led to significantly higher levels of [ 14 C]-inulin, which was quantitatively detected in the olfactory bulb, cerebrum, and medulla oblongata, than the pipette method. This appears to be because retention of the drug solution in the nasal cavity was substantially increased by active administration using a syringe pump in a direction opposite to the MC into the nasal cavity. In conclusion, the two methods of intranasal administration developed in this study can be expected to be extremely useful techniques for evaluating pharmacokinetics in rodents. The reverse cannulation method, in particular, could be useful for evaluating the full potential of nose-to-brain delivery of drug candidates.
KW - Brain distribution
KW - Hydrophilic macromolecule
KW - Inhalation anesthesia
KW - Intranasal administration
KW - Issue 141
KW - Medicine
KW - Nose-to-brain
KW - Quantitative evaluation
UR - http://www.scopus.com/inward/record.url?scp=85058115440&partnerID=8YFLogxK
U2 - 10.3791/58485
DO - 10.3791/58485
M3 - Article
C2 - 30507914
AN - SCOPUS:85058115440
SN - 1940-087X
VL - 2018
JO - Journal of Visualized Experiments
JF - Journal of Visualized Experiments
IS - 141
M1 - e58485
ER -