Transcranial optical imaging reveals a pathway for optimizing the delivery of immunotherapeutics to the brain
Benjamin A. Plog, Humberto Mestre, Genaro E. Olveda, Amanda M. Sweeney, H. Mark Kenney, Alexander Cove, Kosha Y. Dholakia, Jeffrey Tithof, Thomas D. Nevins, Iben Lundgaard, Ting Du, Douglas H. Kelley, Maiken Nedergaard
Benjamin A. Plog, Humberto Mestre, Genaro E. Olveda, Amanda M. Sweeney, H. Mark Kenney, Alexander Cove, Kosha Y. Dholakia, Jeffrey Tithof, Thomas D. Nevins, Iben Lundgaard, Ting Du, Douglas H. Kelley, Maiken Nedergaard
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Resource and Technical Advance Neuroscience Therapeutics

Transcranial optical imaging reveals a pathway for optimizing the delivery of immunotherapeutics to the brain

Abstract

Despite the initial promise of immunotherapy for CNS disease, multiple recent clinical trials have failed. This may be due in part to characteristically low penetration of antibodies to cerebrospinal fluid (CSF) and brain parenchyma, resulting in poor target engagement. We here utilized transcranial macroscopic imaging to noninvasively evaluate in vivo delivery pathways of CSF fluorescent tracers. Tracers in CSF proved to be distributed through a brain-wide network of periarterial spaces, previously denoted as the glymphatic system. CSF tracer entry was enhanced approximately 3-fold by increasing plasma osmolality without disruption of the blood-brain barrier. Further, plasma hyperosmolality overrode the inhibition of glymphatic transport that characterizes the awake state and reversed glymphatic suppression in a mouse model of Alzheimer’s disease. Plasma hyperosmolality enhanced the delivery of an amyloid-β (Aβ) antibody, obtaining a 5-fold increase in antibody binding to Aβ plaques. Thus, manipulation of glymphatic activity may represent a novel strategy for improving penetration of therapeutic antibodies to the CNS.

Authors

Benjamin A. Plog, Humberto Mestre, Genaro E. Olveda, Amanda M. Sweeney, H. Mark Kenney, Alexander Cove, Kosha Y. Dholakia, Jeffrey Tithof, Thomas D. Nevins, Iben Lundgaard, Ting Du, Douglas H. Kelley, Maiken Nedergaard

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Figure 1

In vivo transcranial brain-wide imaging of CSF influx.

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In vivo transcranial brain-wide imaging of CSF influx. (A). Mice were im...
(A). Mice were imaged through an intact skull using a macroscope. (B) A fluorescent protein tracer (BSA-647 nm) was delivered into the cisterna magna (2 μl/min, 5 minutes) and tracer influx was imaged for 30 minutes from the start of the injection. All mice received i.p. isotonic saline at the onset of the intracisternal injection. (C) Representative time-lapse images of CSF influx over the first 30 minutes following tracer injection in anesthetized (KX) and awake wild-type mice as well as anesthetized Aqp4–/– mice (KX-Aqp4–/–). Images (8-bit pixel depth) are color coded to depict pixel intensity (PI) in arbitrary units (AU). Scale bar: 2 mm. Fluorescence was detected as early as 5 minutes after infusion at the base of the brain approximately 5-6 mm below the dorsal cortical surface. (D) Quantification of mean pixel intensity (MPI) for the 30-minute in vivo imaging series depicted in C (mean ± SEM; n = 5–7 mice/group; repeated-measures 2-way ANOVA, Sidak’s multiple comparisons test; *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001 vs. KX). (E) Representative front-tracking analysis of CSF tracer influx over the imaging session. Fronts are time coded in minutes. (F) Quantification of the influx area over time from analysis E (mean ± SEM; n = 5–7 mice/group; repeated-measures 2-way ANOVA, Sidak’s multiple comparisons test; ****P < 0.0001 KX vs. awake and KX- Aqp4–/–). (G) Average influx speed maps (μm/min) generated from group data in C and E. (H) Representative conventional fluorescence images of brains ex vivo upon removal from the cranium (whole brains; scale bar: 2 mm) and after coronal sectioning to evaluate tracer penetrance deep into the cortical surface (coronal sections; scale bar: 1 mm) in the KX and awake wild-type and KX-anesthetized Aqp4–/– groups. High-magnification images of perivascular tracer were acquired using laser scanning confocal microscopy (immunohistochemical staining; scale bar: 50 μm). (I) Quantification of ex vivo coronal section fluorescence MPI for the KX and awake wild-type and KX-anesthetized Aqp4–/– groups (mean ± SEM; n = 3–8 mice/group; 1-way ANOVA, Tukey’s multiple comparisons test; *P < 0.05, **P < 0.01).