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Microfluidic interfaces for chronic bidirectional access to the brain

Simone Marcigaglia, Robin De Plus, Charysse Vandendriessche (UGent) , Eleonore Schiltz, Marie-Lynn Cuypers, Jordi Cools, Luis D Hoffman, Roosmarijn Vandenbroucke (UGent) , Maarten Dewilde and Sebastian Haesler
(2024) ADVANCED HEALTHCARE MATERIALS. 13(22).
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Abstract
Two-photon polymerization (TPP) is an additive manufacturing technique with micron-scale resolution that is rapidly gaining ground for a range of biomedical applications. TPP is particularly attractive for the creation of microscopic three-dimensional structures in biocompatible and noncytotoxic resins. Here, TPP is used to develop microfluidic interfaces which provide chronic fluidic access to the brain of preclinical research models. These microcatheters can be used for either convection-enhanced delivery (CED) or for the repeated collection of liquid biopsies. In a brain phantom, infusions with the micronozzle result in more localized distribution clouds and lower backflow compared to a control catheter. In mice, the delivery interface enables faster, more precise, and physiologically less disruptive fluid injections. A second microcatheter design enables repeated, longitudinal sampling of cerebrospinal fluid (CSF) over time periods as long as 250 days. Moreover, further in vivo studies demonstrate that the blood-CSF barrier is intact after chronic implantation of the sampling interface and that samples are suitable for downstream molecular analysis for the identification of nucleic acid- or peptide-based biomarkers. Ultimately, the versatility of this fabrication technique implies a great translational potential for simultaneous drug delivery and biomarker tracking in a range of human neurological diseases. The limited passage of molecules between the blood and the brain poses a major challenge for drug research and therapy. To address this, the authors use ultrahigh resolution additive manufacturing to develop a miniaturized microcatheter platform for faster, more predictable, and physiologically nondisruptive fluid delivery as well as reliable fluid collection, at rates and with long-term stability not reported before.
Keywords
brain disease, cerebrospinal fluid, convection-enhanced delivery, liquid biopsy, CONVECTION-ENHANCED DELIVERY, CENTRAL-NERVOUS-SYSTEM, CEREBROSPINAL-FLUID, NEUROTROPHIC FACTOR, ALZHEIMERS-DISEASE, MOUSE MODEL, CSF, INFUSION, BIOMARKERS, TAU

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Citation

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MLA
Marcigaglia, Simone, et al. “Microfluidic Interfaces for Chronic Bidirectional Access to the Brain.” ADVANCED HEALTHCARE MATERIALS, vol. 13, no. 22, 2024, doi:10.1002/adhm.202400438.
APA
Marcigaglia, S., De Plus, R., Vandendriessche, C., Schiltz, E., Cuypers, M.-L., Cools, J., … Haesler, S. (2024). Microfluidic interfaces for chronic bidirectional access to the brain. ADVANCED HEALTHCARE MATERIALS, 13(22). https://doi.org/10.1002/adhm.202400438
Chicago author-date
Marcigaglia, Simone, Robin De Plus, Charysse Vandendriessche, Eleonore Schiltz, Marie-Lynn Cuypers, Jordi Cools, Luis D Hoffman, Roosmarijn Vandenbroucke, Maarten Dewilde, and Sebastian Haesler. 2024. “Microfluidic Interfaces for Chronic Bidirectional Access to the Brain.” ADVANCED HEALTHCARE MATERIALS 13 (22). https://doi.org/10.1002/adhm.202400438.
Chicago author-date (all authors)
Marcigaglia, Simone, Robin De Plus, Charysse Vandendriessche, Eleonore Schiltz, Marie-Lynn Cuypers, Jordi Cools, Luis D Hoffman, Roosmarijn Vandenbroucke, Maarten Dewilde, and Sebastian Haesler. 2024. “Microfluidic Interfaces for Chronic Bidirectional Access to the Brain.” ADVANCED HEALTHCARE MATERIALS 13 (22). doi:10.1002/adhm.202400438.
Vancouver
1.
Marcigaglia S, De Plus R, Vandendriessche C, Schiltz E, Cuypers M-L, Cools J, et al. Microfluidic interfaces for chronic bidirectional access to the brain. ADVANCED HEALTHCARE MATERIALS. 2024;13(22).
IEEE
[1]
S. Marcigaglia et al., “Microfluidic interfaces for chronic bidirectional access to the brain,” ADVANCED HEALTHCARE MATERIALS, vol. 13, no. 22, 2024.
@article{01J1PKK3WVNJFGJ39E7EC18ZWY,
  abstract     = {{Two-photon polymerization (TPP) is an additive manufacturing technique with micron-scale resolution that is rapidly gaining ground for a range of biomedical applications. TPP is particularly attractive for the creation of microscopic three-dimensional structures in biocompatible and noncytotoxic resins. Here, TPP is used to develop microfluidic interfaces which provide chronic fluidic access to the brain of preclinical research models. These microcatheters can be used for either convection-enhanced delivery (CED) or for the repeated collection of liquid biopsies. In a brain phantom, infusions with the micronozzle result in more localized distribution clouds and lower backflow compared to a control catheter. In mice, the delivery interface enables faster, more precise, and physiologically less disruptive fluid injections. A second microcatheter design enables repeated, longitudinal sampling of cerebrospinal fluid (CSF) over time periods as long as 250 days. Moreover, further in vivo studies demonstrate that the blood-CSF barrier is intact after chronic implantation of the sampling interface and that samples are suitable for downstream molecular analysis for the identification of nucleic acid- or peptide-based biomarkers. Ultimately, the versatility of this fabrication technique implies a great translational potential for simultaneous drug delivery and biomarker tracking in a range of human neurological diseases.

The limited passage of molecules between the blood and the brain poses a major challenge for drug research and therapy. To address this, the authors use ultrahigh resolution additive manufacturing to develop a miniaturized microcatheter platform for faster, more predictable, and physiologically nondisruptive fluid delivery as well as reliable fluid collection, at rates and with long-term stability not reported before.}},
  articleno    = {{2400438}},
  author       = {{Marcigaglia, Simone and De Plus, Robin and Vandendriessche, Charysse and Schiltz, Eleonore and Cuypers, Marie-Lynn and Cools, Jordi and Hoffman, Luis D and Vandenbroucke, Roosmarijn and Dewilde, Maarten and Haesler, Sebastian}},
  issn         = {{2192-2640}},
  journal      = {{ADVANCED HEALTHCARE MATERIALS}},
  keywords     = {{brain disease,cerebrospinal fluid,convection-enhanced delivery,liquid biopsy,CONVECTION-ENHANCED DELIVERY,CENTRAL-NERVOUS-SYSTEM,CEREBROSPINAL-FLUID,NEUROTROPHIC FACTOR,ALZHEIMERS-DISEASE,MOUSE MODEL,CSF,INFUSION,BIOMARKERS,TAU}},
  language     = {{eng}},
  number       = {{22}},
  pages        = {{14}},
  title        = {{Microfluidic interfaces for chronic bidirectional access to the brain}},
  url          = {{http://doi.org/10.1002/adhm.202400438}},
  volume       = {{13}},
  year         = {{2024}},
}
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