Evaluation of TiO2 exposure impact on adult and vulnerable brains / Evaluation des Effets de l'Exposition au TiO2 sur le Cerveau Adulte et Vulnérable

Disdier, Clémence

11 April 2016

La présence croissante de nanoparticules (NPs) dans les produits de la vie quotidienne (alimentation, médicaments, cosmétiques, textiles…) soulève de sérieuses inquiétudes quant à leurs potentiels effets nocifs pour la santé humaine. Les NPs de dioxyde de titane (TiO2) sont produites à l’échelle industrielle et peuvent déjà être trouvées dans plusieurs produits commerciaux tels que les peintures, les cosmétiques ou dans les systèmes de décontamination de l’eau ou de l’air. Dans le passé, les NPs de TiO2 étaient considérées comme inertes, mais, très récemment, l'Agence Internationale pour la Recherche sur le Cancer les a classées comme possiblement cancérogènes (groupe 2B) pour l’homme. De nombreuses études in vitro et in vivo ont démontré la potentielle neuro-toxicité des NPs de TiO2, mais très peu d'études se sont concentrées plus spécifiquement sur la barrière hémato-encéphalique (BHE), protégeant le cerveau. Aujourd'hui, en dépit des avancées constatées, la bio-cinétique et la bio-accumulation des NPs de TiO2 ainsi que les conséquences sur la physiologie de la barrière hémato-encéphalique (BHE) in vivo restent très peu documentées. De plus, dans l’évaluation du risque lié à l’exposition aux NPs, des facteurs de risque tel que l’âge ont jusqu’ici été quasiment ignorés. Dans ce contexte, l’objectif de ce projet est donc d’évaluer chez le rat adulte et âgé, l’impact d’une exposition aux NPs de TiO2 sur les fonctions de la BHE et sur le métabolisme cérébral. Nos résultats ont montré que les NPs de TiO2 s’accumulent dans certains organes et tissus (principalement dans les poumons, la rate et le foie) et ne sont pas distribuées au système nerveux central (SNC) que ce soit après injection intra-veineuse (IV) ou après une inhalation subaiguë à un nano-aérosol de TiO2. Après administration IV, une interaction directe entre NPs et les cellules endothéliales microvasculaires conduit à des altérations fonctionnelles au niveau de la BHE. Malgré l'absence de translocation vers le SNC, la bio-persistance du titane dans les organes périphériques semble être la cause de modulations de perméabilité de la BHE et d’une inflammation cérébrale. L'implication de médiateurs circulants faisant le lien entre la bio-persitance de titane dans les organes périphériques et les modulations observées au niveau cérébral a été démontré en utilisant un modèle in vitro de BHE. Une réponse exacerbée en termes de neuro-inflammation et de modulation de perméabilité de la BHE établit la vulnérabilité du cerveau âgé à la toxicité des NPs inhalées. Ces résultats ont démontré que malgré l'absence de translocation cérébrale, l'exposition aux NPs de TiO2 induit des altérations fonctionnelles de la BHE et une neuro-inflammation qui pourraient conduire à des troubles neurologiques. L’identification des médiateurs et la description des effets neurotoxiques restent encore à préciser. / The overwhelming presence of nanoparticles (NPs) in products including foods, medications, cosmetics, or textiles raises serious concerns about their potential harmful effects on human health. In the wide diversity of NPs, titanium dioxide (TiO2) NPs are among those produced on a large industrial scale and can already be found in several commercial products such as paints, cosmetics or in environmental decontamination systems. In the past, TiO2 NPs was considered inert, but, very recently, the International Agency for Research in Cancer (IARC) has classified TiO2 as possibly carcinogenic (group 2B) to human beings. Numerous in vitro and in vivo studies have shown the potential neuro-toxicity of TiO2 NPs, but very few studies focus on the central nervous system (CNS), Nowadays, notwithstanding the reported advances, the biokinetic and bioaccumulation ofTiO2 NPs and the consequences on the physiology of the blood-brain barrier (BBB) in vivo are unknown. In addition, NPs effect on susceptible population such as the elderly have been mostly ignored. In this context, the target of the present studies is to evaluate the in vivo impact of exposure to NPs on the BBB physiology and brain inflammation which could promote neurotoxicity in young adults and aging. Our results have shown that TiO2 NPs bioaccumulate in organs and tissues (lungs, spleen and liver especially) and don’t translocate to the brain either after IV or subacute inhalation exposure. In IV administration case, the direct interaction between NPs and brain endothelial cells induces BBB functional alterations. Despite the lack of CNS translocation, the biopersistence of titanium in peripheral organs may be indirectly the cause of BBB permeability alteration and brain inflammation. The involvement of circulating mediators linking titanium biopersitence in peripheral organs and brain impact has been demonstrated using an in vitro BBB model. An exacerbated response in term of neuro-inflammation and BBB permeability modulation has established the vulnerability of the aging brain to inhaled NPs toxicity. Taken together, our findings demonstrated that despite lack of brain translocation, exposure to TiO2 NPs induce BBB physiology alteration and neuro-inflammation that may lead to CNS disorders. Thereafter, identification of mediators and description of the neurotoxic effects may complete the assessment of the impact of TiO2 NPs exposure on the brain.

Barrière hémato-Encéphalique

Dioxyde de titane

Nanoparticules

Neuro-Inflammation

Transporteurs ABC

Blood brain barrier

Titanium dioxide

Nanoparticles

Brain inflammation

ABC transporters

Therapeutic approaches for two distinct CNS pathologies

Stumpf, Sina Kristin

25 June 2018

No description available.

570

Pelizaeus-Merzbacher disease

central nervous system

proteolipid protein

leukodystrophy

Glioblastoma multiforme

ketogenic diet

blood-brain barrier

isoflurane

Biologie (PPN619462639)

Sex Differences In the Enduring Neuroinflammatory and Behavioural Sequelae of Systemic Immune Challenge During Puberty

Kolmogorova, Daria

19 May 2021

Puberty is a critical period for sexual maturation during which the sex-specific reorganization and remodelling of the pubertal brain facilitate sex biases in stress sensitivity. Pubertal (i.e., six-week-old) CD-1 mice treated with the bacterial endotoxin lipopolysaccharide (LPS; 1.5 mg/kg body weight, ip) show several sex-specific changes to the neuroendocrine and behavioural systems of several reproductive and non-reproductive functions. One promising explanation for the elusive mechanisms driving the sex-specific outcomes of pubertal immune challenge may lie in the cascade of neuroimmune events induced by this systemic immune stressor. This doctoral thesis tested the hypothesis that sex-specific responses of the pubertal neuroimmune network contribute to sex differences in the enduring outcomes of pubertal immune challenge on hippocampus-dependent cognitive processes. Male and female CD-1 mice are equally vulnerable to enduring impairments in spatial memory following pubertal LPS exposure. Across brain regions for cognition and stress regulation, pubertal LPS treatment alters baseline sex differences in microglial expression and morphology in a sex-dependent manner. The temporary female-specific increase in whole-brain blood-brain barrier permeability during LPS-induced sickness may have facilitated the apparent female bias in LPS-induced changes to pubertal microglia. In the context of sex- and region-specific residual effects of pubertal LPS-induced sickness on microglial expression and morphology, pubertal LPS treatment may accelerate certain neurodevelopmental processes in males but not females. The innate sex differences in the pubertal neuroimmune network highlighted by these studies underscore how a systemic immune challenge precipitates sex biases in immune-mediated disorders of brain and behaviour during adulthood.

Puberty

Lipopolysaccharide

Sex differences

Microglia

CD-1 mouse

Neuroinflammation

Hippocampus

Memory

Learning

Blood-brain barrier

Apoptosis

Cell development

Développements précliniques de nouveaux outils utilisant les ultrasons transcraniens guidés par IRM haut champ pour la délivrance de médicaments dans le cerveau et la stimulation non invasive de circuits neuronaux / Development of preclinical tool using transcranial ultrasound under high field MR-guidance for drug delivery to the brain and non-invasive neurostimulation

Magnin, Rémi

07 January 2016

La Barrière Hémato-Encéphalique (BHE) représente aujourd’hui un obstacle majeur pour le développement de nouveaux traitements des pathologies cérébrales puisqu’elle empêche le passage de la majorité des agents thérapeutiques vers le cerveau. Afin de contourner cet obstacle, une technique proposée dans les années 2000 a montré son potentiel pour perméabiliser la BHE de façon non-invasive, locale et transitoire grâce à l’utilisation conjointe de microbulles circulantes et d’ultrasons focalisés, permettant une augmentation significative de la quantité de molécules délivrée aux tissus cérébraux. Ce protocole peut néanmoins présenter des risques (œdèmes, micro-hémorragies) qu’il est possible de maîtriser grâce à un bon contrôle du faisceau acoustique. A ce titre, l’imagerie par résonance magnétique (IRM) représente un outil de choix permettant à la fois de planifier la procédure, puis de la suivre et enfin d’étudier ses effets grâce à l’utilisation d’agents de contraste et de séquences d’imagerie quantitative (relaxométrie T1 / T2). Durant cette thèse, nous avons développé de nouveaux outils permettant l’étude de la perméabilisation de la BHE chez le rongeur. Dans un premier temps, nous avons développé et validé un système motorisé compatible IRM, permettant de déplacer le transducteur ultrasonore à l’intérieur d’un scanner préclinique à 7T, avec un rétro-contrôle en temps réel du faisceau ultrasonore sur la base des images IRM de la force de radiation acoustique (MR-ARFI). Nous avons montré que ce dispositif permettait de réaliser l’ensemble du protocole de perméabilisation de BHE guidé par IRM en choisissant la structure anatomique à traiter de façon reproductible. Nous avons également montré qu’il pouvait être utilisé pour délivrer des molécules sur des régions étendues du cerveau selon des trajectoires arbitrairement programmées. Dans une seconde partie de cette thèse, nous avons réalisé plusieurs études en vue d’étudier l’innocuité de la technique. Nous avons mis en évidence l’influence de certains paramètres acoustiques sur l’efficacité du protocole (pression acoustique, temps de cycle), puis nous avons réalisé une étude histologique des dommages engendrés par une perméabilisation chez des animaux sains pour plusieurs pressions acoustiques, entre 0 et 14 jours post-ultrasons. Enfin, dans une troisième partie, nous avons étudié la diffusion de différents agents de contraste paramagnétiques dans les tissus cérébraux suivant une perméabilisation focale de la BHE. Nous avons montré que cette technique permettait d’obtenir des mesures précises de la tortuosité des tissus cérébraux de façon non-invasive et que cette tortuosité n’était pas modifiée par les ultrasons, contrairement à ce qui est observé suite à une injection intracérébrale. / By preventing most of the molecules from penetrating the brain in sufficient quantitiy, the Blood Brain Barrier represents a major obstacle for the development of new therapeutic drugs for brain diseases. A new technique introduced in the early 2000’s combining focused ultrasound and circulating microbubbles has however shown promising results, allowing to induce a local and transient permeabilization of the BBB in a non-invasive manner, thus significantly improving the amount of drugs delivered to the Central Nervous System (CNS). However, this protocol may present some risks (oedema, small hemorrages) which can be avoided by a good control of the acoustic beam properties. To do so, Magnetic Resonance Imaging (MRI) represents a very useful tool since it allows planning, monitoring and following the permeabilization effects by using MRI contrast agents and quantitative imaging sequences (T1/T2 relaxometry). During this PhD, we worked on developing new tools for the study of ultrasound induced BBB permeabilization in rodents. The first part of this work consisted in developing a MR compatible motorized device, allowing the displacment of the ultrasound transducer within a 7T preclinic MRI scanner, with a realtime feedback on the acoustic beam position thanks to MR Acoustic Radiation Force Imaging (MR-ARFI). We have shown that this system allowed performing a full BBB permeabilization protocol under MR-guidance, with an accurate and reproducible choice of the targeted anatomical structure. This system was also used to deliver drugs along arbitrary trajectories over extended regions of the brain. Another part of the work was dedicated to study and improve the safety of the procedure. The influence of different acoustic parameters (acoustic pressure, duty cycle) on the permeabilization efficacy was studied, as well as histologic investigations of short and mid-term effects of BBB permeabilization for different acoustic pressures on healthy rats. Finally, we investigated the diffusion process of contrast agents within the brain tissues following BBB permeabilization. We have shown that this technique allowed accurate measurements of brain tissues tortuosity in a non-invasive way, and found that the tortuosity was not modified by the ultrasound application.

Barrière Hémato-Encéphalique

Ultrasons

IRM haut champ

Imagerie quantitative

Blood-Brain barrier

Ultrasound

High field MRI

Quantitative imaging

Treating Metastatic Brain Cancers With Stem Cells

Sadanandan, Nadia, Shear, Alex, Brooks, Beverly, Saft, Madeline, Cabantan, Dorothy Anne Galang, Kingsbury, Chase, Zhang, Henry, Anthony, Stefan, Wang, Zhen Jie, Salazar, Felipe Esparza, Lezama Toledo, Alma R., Rivera Monroy, Germán, Vega Gonzales-Portillo, Joaquin, Moscatello, Alexa, Lee, Jea Young, Borlongan, Cesario V.

24 November 2021

Stem cell therapy may present an effective treatment for metastatic brain cancer and glioblastoma. Here we posit the critical role of a leaky blood-brain barrier (BBB) as a key element for the development of brain metastases, specifically melanoma. By reviewing the immunological and inflammatory responses associated with BBB damage secondary to tumoral activity, we identify the involvement of this pathological process in the growth and formation of metastatic brain cancers. Likewise, we evaluate the hypothesis of regenerating impaired endothelial cells of the BBB and alleviating the damaged neurovascular unit to attenuate brain metastasis, using the endothelial progenitor cell (EPC) phenotype of bone marrow-derived mesenchymal stem cells. Specifically, there is a need to evaluate the efficacy for stem cell therapy to repair disruptions in the BBB and reduce inflammation in the brain, thereby causing attenuation of metastatic brain cancers. To establish the viability of stem cell therapy for the prevention and treatment of metastatic brain tumors, it is crucial to demonstrate BBB repair through augmentation of vasculogenesis and angiogenesis. BBB disruption is strongly linked to metastatic melanoma, worsens neuroinflammation during metastasis, and negatively influences the prognosis of metastatic brain cancer. Using stem cell therapy to interrupt inflammation secondary to this leaky BBB represents a paradigm-shifting approach for brain cancer treatment. In this review article, we critically assess the advantages and disadvantages of using stem cell therapy for brain metastases and glioblastoma. / National Institutes of Health / Revisión por pares

blood brain barrier

brain metastases

endothelial progenitor cell

melanoma

neuroinflammation

stem cell therapy

Optimization of Focused Ultrasound Mediated Blood-Brain Barrier Opening

Ji, Robin

January 2022

Treatment of brain diseases remains extremely challenging partly due to the fact that critical drug delivery is hindered by the blood-brain barrier (BBB), a specialized and highly selective barrier lining the brain vasculature. Focused ultrasound (FUS), combined with systematically administered microbubbles (MBs), has been established as a technique to noninvasively, locally, and transiently open the BBB. The primary mechanism for temporarily opening the BBB using FUS is microbubble cavitation, a phenomenon that occurs when the circulating microbubbles interact with the FUS beam in the brain vasculature. Over the past two decades, many preclinical and clinical applications of FUS-induced BBB opening have been developed, but certain challenges, such as drug delivery route, cavitation control, inflammation onset, and overall accessibility of the technology, have affected its efficient translation to the clinic. This dissertation focuses on optimizing three aspects of FUS-induced BBB opening for therapeutic applications. The first specific aim investigated FUS-induced BBB opening for drug delivery through the intranasal route. Optimal sonication parameters were determined and applied to FUS-enhanced intranasal delivery of neurotrophic factors in a Parkinson’s Disease mouse model. In the second specific aim, cavitation levels affecting the inflammatory response due to BBB opening with FUS were optimized. The relationship between cavitation during FUS-induced BBB opening and the local inflammation was examined, and a cavitation-based controller system was developed to modulate the inflammatory response. In the third specific aim, the devices used for FUS-induced BBB opening were streamlined. A conventional system for FUS-induced BBB opening includes two transducers: one for therapy and another for cavitation monitoring (single element) or imaging (multi-element). In this aim, a single linear array transducer capable of synchronous BBB opening and cavitation imaging was developed, creating a cost-effective and highly accessible “theranostic ultrasound” device. The feasibility of theranostic ultrasound (TUS) was demonstrated in vivo in both mice and non-human primates. In summary, the findings and methodologies in this dissertation optimized FUS-enhanced intranasal delivery across the BBB, developed a cavitation-controlled system to modulate inflammation in the brain, which has been advantageous in reducing pathology and designed a new system for theranostic ultrasound for drug delivery to the brain. Taken altogether, this thesis contributes to the efficient advancement and optimization of FUS-induced BBB opening technology, thus enhancing its clinical adoption in the fight to treat many challenging brain diseases.

Biomedical engineering

Brain--Diseases--Treatment

Ultrasonics in medicine

Parkinson's disease--Treatment

Blood-brain barrier

High-intensity focused ultrasound

Amelioration Of Amyloid Burden In Advanced Human And Mouse Alzheimer's Disease Brains By Oral Delivery Of Myelin Basic Protein Bioencapsulated In Plant Cells

Kohli, Neha

01 January 2012

One of the pathological hallmarks of Alzheimer's disease (AD) is the amyloid plaque deposition in aging brains by aggregation of amyloid-β (Aβ) peptides. In this study, the effect of chloroplast derived myelin basic protein (MBP) fused with cholera toxin subunit B (CTB) was investigated in advanced diseased stage of human and mouse AD brains. The CTB-fusion protein in chloroplasts facilitates transmucosal delivery in the gut by the natural binding ability of CTB pentameric form with GM1 receptors on the intestinal epithelium. Further, bioencapsulation of the MBP within plant cells confers protection from enzymes and acids in the digestive system. Here, 12-14 months old triple transgenic AD mice were fed with CTB-MBP bioencapsulated in the plant cells for 3 months. A reduction of 67.3% and 33.3% amyloid levels in hippocampal and cortical regions, respectively were observed by immunostaining of brain sections with anti- Aβ antibody. Similarly, 70% decrease in plaque number and 40% reduction of plaque intensity was observed through thioflavin S (ThS) staining that specifically stains amyloid in the AD brain. Furthermore, ex vivo 3xTg AD mice brain sections showed up to 45% reduction of ThS stained amyloid levels when incubated with enriched CTB-MBP in a concentration dependent manner. Similarly, incubation of enriched CTB-MBP with ex vivo postmortem human brain tissue sections with advanced stage of AD resulted up to 47% decrease of ThS stained amyloid plaque intensity. Lastly, lyophilization of plant material facilitates dehydration and long term storage of capsules at room temperature, in addition to increasing CTB-MBP concentration by 17 fold. These observations offer a low cost solution for treatment of even advanced stages of the AD by facilitating delivery of therapeutic proteins to central nervous system to address other neurodegenerative disease.

Neurodegenerative disease

amyloid beta

blood brain barrier

bioencapsulation

oral drug delivery

plant made biopharmaceuticals

chloroplast

Biotechnology

Molecular Biology

Development and Characterization of an In-House Custom Bioreactor for the Cultivation of a Tissue Engineered Blood-Brain Barrier

Mirzaaghaeian, Amin Hadi

01 July 2012

The development of treatments for neurological disorders such as Alzheimer’s and Parkinson’s disease begins by understanding what these diseases affect and the consequences of further manifestation. One particular region where these diseases can produce substantial problems is the blood-brain barrier (BBB). The BBB is the selective diffusion barrier between the circulating blood and the brain. The barrier’s main function is to maintain CNS homeostasis and protect the brain from the extracellular environment. The progression of BBB research has advanced to the point where many have modeled the BBB in vitro with aims of further characterizing and testing the barrier. Particularly, the pharmaceutical industry has gained interest in this field of research to improve drug development and obtain novel treatments for patients so the need for an improved model of the BBB is pertinent in their discovery. In the Cal Poly Tissue Engineering lab, an in vitro tissue engineered BBB system has previously been obtained and characterized for the initial investigation of the barrier and its components. However, certain limitations existed with use of the commercial system. Therefore, the focus of this thesis was to improve upon the capabilities and limitations of this commercialized system to allow further expansion of BBB research. The work performed was based on three aims: first to design and develop an in-house bioreactor system that could be used to cultivate the BBB; second, to characterize flow and functional capabilities of the bioreactor; third, to develop protocols for the overall use of the bioreactor, to ultimately allow co-cultures of BAEC and C6 glioma cells, and further the progression toward creating an in vitro model of the BBB. The work of this thesis demonstrates development of an in-house custom bioreactor system that can successfully culture cells. Results showed that the system was reusable, could be sterilized and monitored, was easily used by students trained in the laboratory, and allowed non-destructive scaffold extraction. This thesis also discusses the next set of experiments that will lead to an in vitro model of the BBB.

Blood-Brain Barrier

Bioreactor

Tissue Engineering

Biomedical Devices and Instrumentation

Engineering

Role of P2X7 Receptors in Immune Responses During Neurodegeneration

Oliveira-Giacomelli, Ágatha, Petiz, Lyvia Lintzmaier, Andrejew, Roberta, Turrini, Natalia, Silva, Jean Bezerra, Sack, Ulrich, Ulrich, Henning

27 March 2023

P2X7 receptors are ion-gated channels activated by ATP. Under pathological conditions, the extensive release of ATP induces sustained P2X7 receptor activation, culminating in induction of proinflammatory pathways with inflammasome assembly and cytokine release. These inflammatory conditions, whether occurring peripherally or in the central nervous system (CNS), increase blood-brain-barrier (BBB) permeability. Besides its well-known involvement in neurodegeneration and neuroinflammation, the P2X7 receptor may induce BBB disruption and chemotaxis of peripheral immune cells to the CNS, resulting in brain parenchyma infiltration. For instance, despite common effects on cytokine release, P2X7 receptor signaling is also associated with metalloproteinase secretion and activation, as well as migration and differentiation of T lymphocytes, monocytes and dendritic cells. Here we highlight that peripheral immune cells mediate the pathogenesis of Multiple Sclerosis and Parkinson’s and Alzheimer’s disease, mainly through T lymphocyte, neutrophil and monocyte infiltration. We propose that P2X7 receptor activation contributes to neurodegenerative disease progression beyond its known effects on the CNS. This review discusses how P2X7 receptor activation mediates responses of peripheral immune cells within the inflamed CNS, as occurring in the aforementioned diseases.

info:eu-repo/classification/ddc/610

ddc:610

Simulating hemodynamics in in vitro culture models: Implications on Nano-biointeractions

Sharma, Monita

January 2013

No description available.

Nanotechnology

Biomedical Research

Nanoscience