Background <p>The blood–brain barrier (BBB) plays a critical role in maintaining brain homeostasis by tightly regulating molecular transport. However, its integrity is often compromised with aging and in neurodegenerative diseases, contributing to disease pathology. Studying the biological consequences of BBB dysfunction independent of concomitant pathology remains challenging, largely due to the absence of reliable and inducible animal models that avoid unintended side effects such as osmotic effects, neuroinflammation, or vascular damage. In this study, we evaluated the use of Power Doppler ultrasound (PDUS) combined with microbubbles to induce widespread, bilateral BBB opening in the mouse brain.</p> Methods <p>Mice received intravenous infusions of SonoMAC microbubbles during transcranial PDUS application. BBB permeability was assessed via Evans Blue dye extravasation and immunofluorescence analysis of extravasated immunoglobulins. Vessel integrity was evaluated at the ultrastructural level using transmission electron microscopy (TEM).</p> Results <p>PDUS combined with microbubbles successfully induced widespread BBB opening, as evidenced by diffuse Evans Blue staining and immunoglobulin extravasation in coronal sections. Immunoglobulin leakage was detected in all analyzed brain regions, with lower levels in white matter, likely reflecting its lower vascular density. Leakage appeared to primarily originate from capillaries while TEM analysis revealed no overt vascular damage.</p> Conclusions <p>These findings support PDUS with microbubbles as a non-destructive, reproducible method to model widespread BBB dysfunction. This approach offers an in vivo platform to study BBB-related pathophysiological processes such as impaired clearance, protein aggregation, and neurotoxicity, as well as for investigation of therapeutic delivery to the brain parenchyma.</p>

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Induction of subtle blood-brain barrier dysfunction using preclinical diagnostic ultrasound combined with microbubbles

  • Shakira A. van der Panne,
  • Isabella Z. Koster,
  • Anita E. Grootemaat,
  • Nicole N. van der Wel,
  • Mario G. Ries,
  • Helga E. de Vries,
  • Louise van der Weerd,
  • Gustav J. Strijkers,
  • Erik N. T. P. Bakker

摘要

Background

The blood–brain barrier (BBB) plays a critical role in maintaining brain homeostasis by tightly regulating molecular transport. However, its integrity is often compromised with aging and in neurodegenerative diseases, contributing to disease pathology. Studying the biological consequences of BBB dysfunction independent of concomitant pathology remains challenging, largely due to the absence of reliable and inducible animal models that avoid unintended side effects such as osmotic effects, neuroinflammation, or vascular damage. In this study, we evaluated the use of Power Doppler ultrasound (PDUS) combined with microbubbles to induce widespread, bilateral BBB opening in the mouse brain.

Methods

Mice received intravenous infusions of SonoMAC microbubbles during transcranial PDUS application. BBB permeability was assessed via Evans Blue dye extravasation and immunofluorescence analysis of extravasated immunoglobulins. Vessel integrity was evaluated at the ultrastructural level using transmission electron microscopy (TEM).

Results

PDUS combined with microbubbles successfully induced widespread BBB opening, as evidenced by diffuse Evans Blue staining and immunoglobulin extravasation in coronal sections. Immunoglobulin leakage was detected in all analyzed brain regions, with lower levels in white matter, likely reflecting its lower vascular density. Leakage appeared to primarily originate from capillaries while TEM analysis revealed no overt vascular damage.

Conclusions

These findings support PDUS with microbubbles as a non-destructive, reproducible method to model widespread BBB dysfunction. This approach offers an in vivo platform to study BBB-related pathophysiological processes such as impaired clearance, protein aggregation, and neurotoxicity, as well as for investigation of therapeutic delivery to the brain parenchyma.