Preparation of Silica Nanoparticles Loaded with Nootropics and TheirIn VivoPermeation through Blood-Brain Barrier

The blood-brain barrier prevents the passage of many drugs that target the central nervous system. This paper presents the preparation and characterization of silica-based nanocarriers loaded with piracetam, pentoxifylline, and pyridoxine (drugs from the class of nootropics), which are designed to enhance the permeation of the drugs from the circulatory system through the blood-brain barrier. Their permeation was compared with non-nanoparticle drug substances (bulk materials) by means of anin vivomodel of rat brain perfusion. The size and morphology of the nanoparticles were characterized by transmission electron microscopy. The content of the drug substances in silica-based nanocarriers was analysed by elemental analysis and UV spectrometry. Microscopic analysis of visualized silica nanocarriers in the perfused brain tissue was performed. The concentration of the drug substances in the tissue was determined by means of UHPLC-DAD/HRMS LTQ Orbitrap XL. It was found that the drug substances in silica-based nanocarriers permeated through the blood brain barrier to the brain tissue, whereas bulk materials were not detected in the brain.

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Empirical and Theoretical Characterization of the Diffusion Process of Different Gadolinium-Based Nanoparticles within the Brain Tissue after Ultrasound-Induced Permeabilization of the Blood-Brain Barrier

Contrast Media & Molecular Imaging ◽

10.1155/2019/6341545 ◽

2019 ◽

Vol 2019 ◽

pp. 1-13 ◽

Cited By ~ 5

Author(s):

Allegra Conti ◽

Rémi Magnin ◽

Matthieu Gerstenmayer ◽

Nicolas Tsapis ◽

Erik Dumont ◽

...

Keyword(s):

Diffusion Process ◽

Brain Tissue ◽

Blood Brain Barrier ◽

Diffusion Coefficients ◽

Brain Barrier ◽

Apparent Diffusion Coefficients ◽

Blood Brain ◽

The Brain ◽

And Diffusion

Low-intensity focused ultrasound (FUS), combined with microbubbles, is able to locally, and noninvasively, open the blood-brain barrier (BBB), allowing nanoparticles to enter the brain. We present here a study on the diffusion process of gadolinium-based MRI contrast agents within the brain extracellular space after ultrasound-induced BBB permeabilization. Three compounds were tested (MultiHance, Gadovist, and Dotarem). We characterized their diffusion through in vivo experimental tests supported by theoretical models. Specifically, by estimation of the free diffusion coefficients from in vitro studies and of apparent diffusion coefficients from in vivo experiments, we have assessed tortuosity in the right striatum of 9 Sprague Dawley rats through a model correctly describing both vascular permeability as a function of time and diffusion processes occurring in the brain tissue. This model takes into account acoustic pressure, particle size, blood pharmacokinetics, and diffusion rates. Our model is able to fully predict the result of a FUS-induced BBB opening experiment at long space and time scales. Recovered values of tortuosity are in agreement with the literature and demonstrate that our improved model allows us to assess that the chosen permeabilization protocol preserves the integrity of the brain tissue.

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Clonidine Transport at the Mouse Blood—Brain Barrier by a New H+ Antiporter that Interacts with Addictive Drugs

Journal of Cerebral Blood Flow & Metabolism ◽

10.1038/jcbfm.2009.54 ◽

2009 ◽

Vol 29 (7) ◽

pp. 1293-1304 ◽

Cited By ~ 46

Author(s):

Pascal André ◽

Marcel Debray ◽

Jean-Michel Scherrmann ◽

Salvatore Cisternino

Keyword(s):

Blood Brain Barrier ◽

Brain Perfusion ◽

Brain Parenchyma ◽

Brain Barrier ◽

Blood Brain ◽

Cationic Compounds ◽

Cns Drugs ◽

The Brain

Identifying drug transporters and their in vivo significance will help to explain why some central nervous system (CNS) drugs cross the blood-brain barrier (BBB) and reach the brain parenchyma. We characterized the transport of the drug Clonidine at the luminal BBB by in situ mouse brain perfusion. Clonidine influx was saturable, followed by Michaelis–Menten kinetics ( Km = 0.62 mmol/L, Vmax = 1.76 nmol/sec per g at pH 7.40), and was insensitive to both sodium and trans-membrane potential. In vivo manipulation of intracellular and/or extracellular pH and Trans-stimulation showed that Clonidine was transported by an H+-coupled antiporter regulated by both proton and Clonidine gradients, and that diphenhydramine was also a substrate. Organic cation transporters (Oct1–3), P-gp, and Bcrp did not alter Clonidine transport at the BBB in knockout mice. Secondary or tertiary amine CNS compounds such as oxycodone, morphine, diacetylmorphine, methylenedioxyamphetamine (MDMA), cocaine, and nicotine inhibited Clonidine transport. However, cationic compounds that interact with choline, Mate, Octn, and Pmat transporters did not. This suggests that Clonidine is transported at the luminal mouse BBB by a new H+-coupled reversible antiporter.

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The Potential Roles of Blood–Brain Barrier and Blood–Cerebrospinal Fluid Barrier in Maintaining Brain Manganese Homeostasis

Nutrients ◽

10.3390/nu13061833 ◽

2021 ◽

Vol 13 (6) ◽

pp. 1833

Author(s):

Shannon Morgan McCabe ◽

Ningning Zhao

Keyword(s):

Cerebrospinal Fluid ◽

Blood Brain Barrier ◽

Blood Circulation ◽

Critical Role ◽

Systemic Circulation ◽

Brain Parenchyma ◽

Brain Barrier ◽

Blood Brain ◽

The Brain

Manganese (Mn) is a trace nutrient necessary for life but becomes neurotoxic at high concentrations in the brain. The brain is a “privileged” organ that is separated from systemic blood circulation mainly by two barriers. Endothelial cells within the brain form tight junctions and act as the blood–brain barrier (BBB), which physically separates circulating blood from the brain parenchyma. Between the blood and the cerebrospinal fluid (CSF) is the choroid plexus (CP), which is a tissue that acts as the blood–CSF barrier (BCB). Pharmaceuticals, proteins, and metals in the systemic circulation are unable to reach the brain and spinal cord unless transported through either of the two brain barriers. The BBB and the BCB consist of tightly connected cells that fulfill the critical role of neuroprotection and control the exchange of materials between the brain environment and blood circulation. Many recent publications provide insights into Mn transport in vivo or in cell models. In this review, we will focus on the current research regarding Mn metabolism in the brain and discuss the potential roles of the BBB and BCB in maintaining brain Mn homeostasis.

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Pharmacological Modulation of Blood–Brain Barrier Permeability by Kinin Analogs in Normal and Pathologic Conditions

Pharmaceuticals ◽

10.3390/ph13100279 ◽

2020 ◽

Vol 13 (10) ◽

pp. 279

Author(s):

Dina Sikpa ◽

Lisa Whittingstall ◽

Martin Savard ◽

Réjean Lebel ◽

Jérôme Côté ◽

...

Keyword(s):

Blood Brain Barrier ◽

Brain Barrier ◽

Brain Drug Delivery ◽

Blood Brain ◽

Brain Barrier Permeability ◽

Radiation Induced ◽

B2 Receptors ◽

Peptide Agonist ◽

The Brain

The blood–brain barrier (BBB) is a major obstacle to the development of effective diagnostics and therapeutics for brain cancers and other central nervous system diseases. Peptide agonist analogs of kinin B1 and B2 receptors, acting as BBB permeabilizers, have been utilized to overcome this barrier. The purpose of the study was to provide new insights for the potential utility of kinin analogs as brain drug delivery adjuvants. In vivo imaging studies were conducted in various animal models (primary/secondary brain cancers, late radiation-induced brain injury) to quantify BBB permeability in response to kinin agonist administrations. Results showed that kinin B1 (B1R) and B2 receptors (B2R) agonists increase the BBB penetration of chemotherapeutic doxorubicin to glioma sites, with additive effects when applied in combination. B2R agonist also enabled extravasation of high-molecular-weight fluorescent dextrans (155 kDa and 2 MDa) in brains of normal mice. Moreover, a systemic single dose of B2R agonist did not increase the incidence of metastatic brain tumors originating from circulating breast cancer cells. Lastly, B2R agonist promoted the selective delivery of co-injected diagnostic MRI agent Magnevist in irradiated brain areas, depicting increased vascular B2R expression. Altogether, our findings suggest additional evidence for using kinin analogs to facilitate specific access of drugs to the brain.

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EXTH-02. THE BLOOD BRAIN BARRIER (BBB) PERMEABILITY IS ALTERED BY TUMOR TREATING FIELDS (TTFIELDS) IN VIVO

Neuro-Oncology ◽

10.1093/neuonc/noz175.336 ◽

2019 ◽

Vol 21 (Supplement_6) ◽

pp. vi82-vi82 ◽

Cited By ~ 2

Author(s):

Ellina Schulz ◽

Almuth F Kessler ◽

Ellaine Salvador ◽

Dominik Domröse ◽

Malgorzata Burek ◽

...

Keyword(s):

Brain Tumors ◽

Blood Brain Barrier ◽

Brain Barrier ◽

Dce Mri ◽

Tumor Treating Fields ◽

Blood Brain ◽

Vessel Structure ◽

Bbb Permeability ◽

The Brain

Abstract OBJECTIVE For glioblastoma patients Tumor Treating Fields (TTFields) have been established as adjuvant therapy. The blood brain barrier (BBB) tightly controls the influx of the majority of compounds from blood to brain. Therefore, the BBB may block delivery of drugs for treatment of brain tumors. Here, the influence of TTFields on BBB permeability was assessed in vivo. METHODS Rats were treated with 100 kHz TTFields for 72 h and thereupon i.v. injected with Evan’s Blue (EB) which directly binds to Albumin. To evaluate effects on BBB, EB was extracted after brain homogenization and quantified. In addition, cryosections of rat brains were prepared following TTFields application. The sections were stained for tight junction proteins Claudin-5 and Occludin and for immunoglobulin G (IgG) to assess vessel structure. Furthermore, serial dynamic contrast-enhanced DCE-MRI with Gadolinium contrast agent was performed before and after TTFields application. RESULTS TTFields application significantly increased the EB accumulation in the rat brain. In TTFields-treated rats, the vessel structure became diffuse compared to control cryosections of rat brains; Claudin 5 and Occludin were delocalized and IgG was found throughout the brain tissue. Serial DCE-MRI demonstrated significantly increased accumulation of Gadolinium in the brain, observed directly after 72 h of TTFields application. The effect of TTFields on the BBB disappeared 96 h after end of treatment and no difference in contrast enhancement between controls and TTFields treated animals was detectable. CONCLUSION By altering BBB integrity and permeability, application of TTFields at 100 kHz may have the potential to deliver drugs to the brain, which are unable to cross the BBB. Utilizing TTFields to open the BBB and its subsequent recovery could be a clinical approach of drug delivery for treatment of brain tumors and other diseases of the central nervous system. These results will be further validated in clinical Trials.

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Permeability of the windows of the brain: feasibility of dynamic contrast-enhanced MRI of the circumventricular organs

Fluids and Barriers of the CNS ◽

10.1186/s12987-020-00228-x ◽

2020 ◽

Vol 17 (1) ◽

Author(s):

Inge C. M. Verheggen ◽

Joost J. A. de Jong ◽

Martin P. J. van Boxtel ◽

Alida A. Postma ◽

Frans R. J. Verhey ◽

...

Keyword(s):

Blood Brain Barrier ◽

Gray Matter ◽

Circumventricular Organs ◽

Brain Barrier ◽

Dce Mri ◽

Dynamic Contrast Enhanced ◽

Blood Brain ◽

Contrast Enhanced ◽

The Brain

Abstract Background Circumventricular organs (CVOs) are small structures without a blood–brain barrier surrounding the brain ventricles that serve homeostasic functions and facilitate communication between the blood, cerebrospinal fluid and brain. Secretory CVOs release peptides and sensory CVOs regulate signal transmission. However, pathogens may enter the brain through the CVOs and trigger neuroinflammation and neurodegeneration. We investigated the feasibility of dynamic contrast-enhanced (DCE) MRI to assess the CVO permeability characteristics in vivo, and expected significant contrast uptake in these regions, due to blood–brain barrier absence. Methods Twenty healthy, middle-aged to older males underwent brain DCE MRI. Pharmacokinetic modeling was applied to contrast concentration time-courses of CVOs, and in reference to white and gray matter. We investigated whether a significant and positive transfer from blood to brain could be measured in the CVOs, and whether this differed between secretory and sensory CVOs or from normal-appearing brain matter. Results In both the secretory and sensory CVOs, the transfer constants were significantly positive, and all secretory CVOs had significantly higher transfer than each sensory CVO. The transfer constants in both the secretory and sensory CVOs were higher than in the white and gray matter. Conclusions Current measurements confirm the often-held assumption of highly permeable CVOs, of which the secretory types have the strongest blood-to-brain transfer. The current study suggests that DCE MRI could be a promising technique to further assess the function of the CVOs and how pathogens can potentially enter the brain via these structures. Trial registration: Netherlands Trial Register number: NL6358, date of registration: 2017-03-24

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Solving the challenge of the blood–brain barrier to treat infections caused by Trypanosoma evansi: evaluation of nerolidol-loaded nanospheres in mice

Parasitology ◽

10.1017/s003118201700110x ◽

2017 ◽

Vol 144 (11) ◽

pp. 1543-1550 ◽

Cited By ~ 7

Author(s):

MATHEUS D. BALDISSERA ◽

CARINE F. SOUZA ◽

ALINE A. BOLIGON ◽

THIRSSA H. GRANDO ◽

MARIÂNGELA F. DE SÁ ◽

...

Keyword(s):

Brain Tissue ◽

Blood Brain Barrier ◽

High Performance ◽

Drug Efficacy ◽

Trypanosoma Evansi ◽

Brain Barrier ◽

Active Principle ◽

Diminazene Aceturate ◽

Blood Brain ◽

The Brain

SUMMARYDespite significant advances in therapies against Trypanosoma evansi, its effective elimination from the central nervous system (CNS) remains a difficult task. The incapacity of trypanocidal drugs to cross the blood–brain barrier (BBB) after systemic administrations makes the brain the main refuge area for T. evansi. Nanotechnology is showing great potential to improve drug efficacy, such as nerolidol-loaded nanospheres (N-NS). Thus, the aim of this study was to investigate whether the treatment with N-NS was able to cross the BBB and to eliminate T. evansi from the CNS. High-performance liquid chromatography revealed that N-NS can cross the BBB of T. evansi-infected mice, while free nerolidol (F-N) neither the trypanocidal drug diminazene aceturate (D.A.) were not detected in the brain tissue. Polymerase chain reaction revealed that 100% of the animals treated with N-NS were negatives for T. evansi in the brain tissue, while all infected animals treated with F-N or D.A. were positives. Thus, we concluded that nanotechnology improves the therapeutic efficacy of nerolidol, and enables the transport of its active principle through the BBB. In summary, N-NS treatment can eliminate the parasite from the CNS, and possesses potential to treat infected animals.

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Diphenhydramine as a selective probe to study H+-antiporter function at the blood–brain barrier: Application to [11C]diphenhydramine positron emission tomography imaging

Journal of Cerebral Blood Flow & Metabolism ◽

10.1177/0271678x16662042 ◽

2016 ◽

Vol 37 (6) ◽

pp. 2185-2195 ◽

Cited By ~ 7

Author(s):

Sylvain Auvity ◽

Hélène Chapy ◽

Sébastien Goutal ◽

Fabien Caillé ◽

Benoit Hosten ◽

...

Keyword(s):

Positron Emission Tomography ◽

Blood Brain Barrier ◽

Positron Emission Tomography Imaging ◽

Emission Tomography ◽

Brain Barrier ◽

Tomography Imaging ◽

Blood Brain ◽

Positron Emission ◽

The Brain

Diphenhydramine, a sedative histamine H1-receptor (H1R) antagonist, was evaluated as a probe to measure drug/H+-antiporter function at the blood–brain barrier. In situ brain perfusion experiments in mice and rats showed that diphenhydramine transport at the blood–brain barrier was saturable, following Michaelis–Menten kinetics with a Km = 2.99 mM and Vmax = 179.5 nmol s−1 g−1. In the pharmacological plasma concentration range the carrier-mediated component accounted for 77% of diphenhydramine influx while passive diffusion accounted for only 23%. [14C]Diphenhydramine blood–brain barrier transport was proton and clonidine sensitive but was influenced by neither tetraethylammonium, a MATE1 (SLC47A1), and OCT/OCTN (SLC22A1-5) modulator, nor P-gp/Bcrp (ABCB1a/1b/ABCG2) deficiency. Brain and plasma kinetics of [11C]diphenhydramine were measured by positron emission tomography imaging in rats. [11C]Diphenhydramine kinetics in different brain regions were not influenced by displacement with 1 mg kg−1 unlabeled diphenhydramine, indicating the specificity of the brain positron emission tomography signal for blood–brain barrier transport activity over binding to any central nervous system target in vivo. [11C]Diphenhydramine radiometabolites were not detected in the brain 15 min after injection, allowing for the reliable calculation of [11C]diphenhydramine brain uptake clearance (Clup = 0.99 ± 0.18 mL min−1 cm−3). Diphenhydramine is a selective and specific H+-antiporter substrate. [11C]Diphenhydramine positron emission tomography imaging offers a reliable and noninvasive method to evaluate H+-antiporter function at the blood–brain barrier.

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