Neurotoxic effects of malathion and lead acetate on the blood-brain barrier: Disruptive effects caused by different mechanisms examined with an in vitro blood-brain barrier system

Balbuena, Pergentino

23 July 2010

Organophosphates (OP) such as malathion are organic derivatives of phosphoric acid with broad use in everyday life throughout the world, especially as insecticides. Lead particles can accumulate in soil and from there leach into our water supplies. Interaction with the environment offers opportunities for multiple exposures to combinations of different toxicants (such as lead and malathion). Thus, it is important to assess effects that these compounds exert not only on the nervous system, but also on the blood-brain barrier (BBB). The BBB consists of specialized endothelial cells that form the vasculature of the brain; it regulates passage of nutrients, while preventing potentially damaging substances from entering the brain. The main feature of the BBB is the presence of tight junctions between cells, which provide the BBB with its low permeability. The work presented in this dissertation tests the hypothesis that lead and malathion disrupt BBB integrity by affecting tight junctions of the BBB. The hypothesis suggests that disruptions involve changes in protein levels and gene expression as well as activation of transient receptor potential canonical channels (TRPC) that in turn increase intracellular calcium levels affecting tight junction structure. The hypothesis was tested by assessing lead-malathion interactions in an in vitro BBB model. This model was constructed with rat astrocytes and rat brain endothelial cells (RBE4). Assessments of cell toxicity in response to different concentrations of the neurotoxicants tested showed that concentrations between 10-5 µM and 10-6 µM were ideal to assess combinations of neurotoxicants. In general, protein levels of occludin, claudin 5, ZO1, and ZO2 decreased at all times, however, qPCR analysis of gene expression for all the proteins did not correlate with the assessments on protein levels. TRPC channel protein levels increased in response to neurotoxicant insult, which correlated with results for gene expression. This study suggests that at least one of the mechanisms that neurotoxicants lead and malathion utilize to disrupt permeability of the BBB is by affecting tight junction structure. This effect could be regulated by increases in gene expression of TRPC1 and TRPC4 that are associated with increases in the number of TRPC channels on the membrane of endothelial cells of the cerebral microvasculature. / Ph. D.

blood-brain barrier

Malaoxon

Malathion

Lead acetate

neurotoxicity

Investigation of Single-Cell and Blood-Brain Barrier Mechanics after Electroporation and in Primary Brain Cancers

Graybill, Philip Melvin

31 August 2021

Cell-level and tissue-level mechanical properties are key to healthy biological functions, and many diseases and disorder arise or progress due to altered cell and tissue mechanics. Pulse electric field (PEFs), which employ intense external electric fields to cause electroporation, a phenomenon characterized by increased cell membrane permeability, also can cause significant changes to cell and tissue mechanics. Here, we investigate the mechanics of brain and brain cancer cells, specifically focusing on how PEFs impact cell mechanics and PEF-induced blood-brain barrier disruption. In our first study, we investigate single-cell mechanical disruption of glioblastoma cells after reversible electroporation using Nanonet Force Microscopy (NFM). A precise network of extracellular-matrix mimicking nanofibers enabled cell attachment and contraction, resulting in measurable fiber deflections. Cell contractile forces were shown to be temporarily disrupted after reversible electroporation, in an orientation and field-dependent manner. Furthermore, we found that cell response is often a multi-stage process involving a cell-rounding stage, biphasic stage, and a cell re-spreading stage. Additionally, cell viability post-PEFs was orientation-dependent. In another study, we investigated the mechanical properties of brain cancer for various-grade glioma cells (healthy astrocytes, grade II, grade III, and grade IV (glioblastoma) cells). A microfluidic constriction channel caused cell deformation as cells, driven by hydrostatic pressure, entered a narrow constriction. Finite element models of cell deformation and a neural network were used to convert experimental results (cell entry time and cell elongation within the channel) into elastic modulus values (kPa). We found that the that low-grade glioma cells showed higher stiffnesses compared to healthy and grade IV glioma cells, which both showed similar values. These results warrant future studies to investigate these trends further. PEFs can induce Blood-brain barrier (BBB) disruption, an effect we studied using a multiplexed, PDMS microdevice. A monolayer of human cerebral endothelial cells on a semi-permeable membrane was used to model the BBB, and permeability was assessed by the diffusion of a fluorescent dye from an upper to lower channel. A custom tapered channel and branching channel design created a linear gradient in the electric field within the device that enabled six electric field strengths to be tested at once against two unexposed (control) channels. Normalization of permeability by the control channels significantly removed experimental noise. We found that after high-frequency bipolar irreversible electroporation (HFIRE) electric pulses, permeability transiently increased within the first hour after electroporation, in a voltage- and pulse-number dependent manner. However, we found significant electrofusion events after pulsing at high voltages, which reduced monolayer permeability below baseline values. This device enables efficient exploration of a wide range of electroporation parameters to identify the optimal conditions for blood-brain barrier disruption. In another blood-brain barrier study, we incorporate dense, polystyrene nanofiber networks to create ultra-thin, ultra-porous basement-membrane-mimics for In vitro blood-brain barrier models. Fiber networks are fabricated using the non-electrospinning Spinneret-based Tunable Engineered Parameters (STEP) technique. Endothelial cells cultured on one side of the fiber network are in close contact with supporting cell types (pericytes) cultured on the backside of the fibers. Contact-orientation co-cultures have been shown to increase blood-brain barrier integrity, and our nanofiber networks increase the physiological realism of basement-membrane mimics for improve modeling. Finally, we investigate how cell viability post-electroporation is impacted by cell morphology. The impact of cell morphology (shape and cytoskeletal structure) on cell survival after electroporation is not well understood. Linking specific morphological characteristics with cell susceptibility to electroporation will enhance fundamental knowledge and will be widely useful for improving electroporation techniques where cell viability is desirable (gene transfection, electrofusion, electrochemotherapy) or where cell viability is undesirable (tumor ablation, cardiac ablation). Precise control of cell shape and orientation enabled by nanofiber scaffolds provides a convenient and expedient platform for investigating a wide variety of factors (morphological and experimental) on cell viability. Altogether, these investigations shed new light on cell mechanical changes due to disease and pulsed electric fields, and suggest opportunities for improving brain cancer therapies. / Doctor of Philosophy / In biology, structure and function are interrelated. Cells and tissue have structures that enable them to perform their proper function. In the case of disease, cell and tissue properties are altered, leading to dysfunction. Alternatively, healthy structures sometime hinder effective treatments, and therefore can be therapeutically disrupted to improve treatments. In this study, we investigate single-cell and multi-cellular mechanical change due to disease or after pulsed electric fields (PEFs), with a specific focus on the brain. Pulsed electric fields (PEFs) use electrodes to deliver short, intense pulses of electrical energy to disrupt cell membranes and change cell mechanics. We studied as single-cell contractility, cancer cell stiffness, and blood-brain barrier (BBB) disruption by PEFs. We found that PEFs cause significant change to cell shape and mechanics, and can disrupt the BBB. By studying several grades of brain cancers, we found that low-grade brain cancer (gliomas) showed increased stiffness compared to healthy and highly diseased (grade IV) cells. To mimic the BBB, we used microfluidic devices to grow specialized brain cells (endothelial cells) on permeable membranes and nanofibers networks and showed that these devices can mimic structures found in animals/humans. Finally, we studied how cell properties (such as shape) determine whether cells will survive PEFs. Taken together, our investigations improve the understanding of brain mechanics during disease and after PEFs, and suggest the usefulness of PEFs for improved brain cancer therapies.

Pulsed electric fields

blood-brain barrier

electroporation

microfluidics

mechanobiology

cytoskeleton

Blood-Brain Barrier Dysfunction and Repair after Blast-Induced Traumatic Brain Injury

Hue, Christopher Donald

January 2015

Traumatic brain injury (TBI) is the signature injury of modern military conflicts due to widespread use of improvised explosive devices (IEDs) and modern body armor. However, the exact biophysical mechanisms of blast-induced traumatic brain injury (bTBI) and its pathological effects on the blood-brain barrier (BBB) – a structure essential for maintaining brain homeostasis – remain poorly understood. The specific aims of this thesis are to: 1) determine a threshold for primary blast-induced BBB dysfunction in vitro; 2) determine the effect of repeated blast on BBB integrity in vitro; 3) improve BBB recovery in vitro as a potential therapeutic strategy for mitigating effects of blast; and 4) quantify the time course and pore-size of BBB opening in vivo. In this work we utilized a shock tube driven by compressed gas to generate operationally relevant, ideal pressure profiles consistent with IEDs. By multiple measures, the barrier function of an in vitro BBB model was disrupted after exposure to a range of blast-loading conditions. Trans-endothelial electrical resistance (TEER) decreased acutely in a dose-dependent manner that was most strongly correlated with impulse, as opposed to peak overpressure or duration. Significantly increased hydraulic conductivity and solute permeability post-injury further confirmed acute alterations in barrier function. Compromised ZO-1 immunostaining identified a structural basis for BBB breakdown. These results are the first to demonstrate acute disruption of an in vitro BBB model after primary blast exposure; defined tolerance criteria may be important for development of novel helmet designs to help mitigate effects of blast on the BBB. After determining that exposure to a single primary blast caused BBB disruption, we hypothesized that exposure to two consecutive blast injuries would result in exacerbated damage to the BBB in vitro. However, contrary to our hypothesis, repeated mild or moderate primary blast delivered within 24 or 72 hours did not significantly exacerbate reductions in TEER across a brain endothelial monolayer compared to sister cultures receiving a single exposure. Single blast exposure significantly reduced immunostaining of ZO-1 and claudin-5 tight junction proteins, but subsequent exposure did not cause additional damage to tight junctions. The second injury delayed recovery of TEER and hydraulic conductivity in BBB cultures. Extending the inter-injury interval to 72 hours, the effects of repeated injury on the BBB were independent given sufficient recovery time between consecutive exposures. Investigation of repeated blast on the BBB will help identify a temporal window of vulnerability to repeated exposure. Restoration of the BBB after blast injury has emerged as a promising therapeutic target. We hypothesized that treatment with dexamethasone (DEX) after primary blast would potentiate recovery of an in vitro BBB model. DEX treatment resulted in complete recovery of TEER and hydraulic conductivity 1 day after injury, compared with 3 days for vehicle-treated injured cultures. Administration of RU486 (mifepristone) inhibited effects of DEX, confirming that barrier restoration was mediated by glucocorticoid receptor signaling. Potentiated recovery with DEX treatment was accompanied by stronger ZO-1 tight junction immunostaining and expression, suggesting that increased ZO-1 expression was a structural correlate to BBB recovery. This is the first study to provide a mechanistic basis for potentiated functional recovery of an in vitro BBB model due to glucocorticoid treatment after blast injury. Using an in vivo bTBI model, systemic administration of sodium fluorescein (NaFl; 376 Da), Evans blue (EB; 69 kDa when bound to serum albumin) and dextrans (3 – 500 kDa) was used to estimate the pore-size of BBB opening and time required for recovery. Exposure to blast resulted in significant acute extravasation of NaFl, 3 kDa dextran, and EB. However, there was no significant acute extravasation of 70 kDa or 500 kDa dextrans, and minimal to no extravasation of NaFl, dextrans, or EB 1 day after exposure. This work is the first to quantify the time course and size of BBB opening after bTBI, suggesting that the BBB recovered 1 day post-injury. This study supports our hypothesis that transient opening of the BBB may permit serum-components to infiltrate the brain parenchyma and contribute to pathological secondary cascades. This research has shown that BBB damage, demonstrated in vitro and in vivo, is a major mechanism contributing to vascular and neuronal pathology of bTBI at exposure levels above a critical threshold. Compared with published studies on blast-induced damage to the BBB, we have developed primary blast injury tolerance criteria by precisely controlling the biomechanical initiators of injury and measuring resulting alterations to the structure and function of an in vitro BBB model by methods not possible in vivo. We have also developed a potential glucocorticoid treatment to rapidly restore the BBB after injury, which may lead to more promising therapeutic strategies to treat TBI-related pathologies. This work will also guide the development of novel armor designs to protect service members and civilians in order to more effectively address the burden to society of bTBI.

Blood-brain barrier disorders

Brain--Wounds and injuries

Brain--Wounds and injuries--Treatment

Blast injuries

Blood-brain barrier

Biomedical engineering

Biomechanics

Neurosciences

DUAL LOX/COX INHIBITION: A NOVEL STRATEGY TO PREVENT NEUROVASCULAR LEAKAGE IN EPILEPSY

Sokola, Brent S.

01 January 2018

Epilepsy affects 3.4 million patients in the USA and is characterized by recurring seizures. The blood-brain barrier is leaky in epilepsy and may contribute to seizure progression but the mechanisms which cause this leakage are not fully understood. We hypothesized that seizures trigger LOX- and COX-mediated blood-brain barrier leakage and that dual LOX/COX inhibition prevents barrier leakage in vivo. To test this hypothesis, we administered either the dual LOX/COX inhibitor licofelone or a combination of the 5-LOX inhibitor zileuton and the COX-2 inhibitor celecoxib to rats that experienced status epilepticus (SE). Serum and brain capillaries were isolated 48 hours after SE and serum S100β levels were measured and Texas Red™ leakage rates were determined. Dual inhibition of 5-LOX and COX prevented serum S100β elevations observed in SE rats in a dose-dependent manner with licofelone. Inhibition of 5-LOX and COX-2 with zileuton and celecoxib completely prevented serum S100β elevation. Texas Red™ leakage rates for SE rats were also reduced in a dose-depended manner with licofelone and reduced to control rates with zileuton and celecoxib. These data support our hypothesis that seizure-induced blood-brain barrier leakage is mediated by LOX and COX, and inhibition of these enzymes prevents barrier leakage.

blood-brain barrier

epilepsy

blood-brain barrier leakage

barrier dysfunction

5-LOX

COX-2

Pharmacy and Pharmaceutical Sciences

Metabolic encephalopathies the role of ammonia, amino acids and blood-brain barrier derangement /

Jeppsson, Bengt.

January 1981

Thesis (doctoral)--Universitetet i Lund. / Reprints of journal articles inserted in pocket inside back cover.

Examining the protective effects of sesamol on oxidative stress associated blood-brain barrier dysfunction in streptozotocin-induced diabetic rats

VanGilder, Reyna.

January 2009

Thesis (Ph. D.)--West Virginia University, 2009. / Title from document title page. Document formatted into pages; contains xi, 165 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references (p. 131-163).

Metabolic encephalopathies the role of ammonia, amino acids and blood-brain barrier derangement /

Jeppsson, Bengt.

January 1981

Thesis (doctoral)--Universitetet i Lund. / Reprints of journal articles inserted in pocket inside back cover.

A Study of the Interaction of Co-Insult Treatments with Methylmercuric Chloride and X-Irradiation and Demonstration of a Peroxide Induced Protective Mechanism

Earhart, James M.

08 1900

The initial purpose of this work was to investigate the interaction of methylmercuric chloride (MMC) and X-irradiation given as a co-insult upon the rat blood-brain barrier (BBB). The indicators used to determine BBB alterations were mortality and the in vivo tissue uptake of radioactive sulfate administered as 3 5S-sodium sulfate. The results of the interaction studies indicated a neutralization of effects when MMC and X-irradiation were given together. X-irradiation as a single insult generally caused an increase in sulfate uptake by the brain regions monitored, whereas MC treatment generally resulted in decreased sulfate uptake. The neutralization patterns following co-insult treatments were somewhat varied in the different brain regions, exhibiting cancellation of effects in some cases and overriding by one insult in other eases. From the data obtained by this work and in the literature, it is hypothesized that the P-L organelle system of the perivascular glia serves as a trap for MMC, preventing MMC from reaching the neurons. The system appears to proliferate in response to increased peroxides in the body fluids, thereby increasing tolerance to larger doses of MMC.

methylmercuric chloride

X-irradiation

blood-brain barrier

Mercury -- Toxicology.

Blood-brain barrier.

X-rays -- Toxicology.

Hydrogen peroxide.

Alterations in JAK/STAT signaling pathway and blood-brain barrier function mechanisms underlying worsened outcome following stroke in the aged rat /

DiNapoli, Vincent A.,

January 2007

Thesis (Ph. D.)--West Virginia University, 2007. / Title from document title page. Document formatted into pages; contains x, 154 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references (p. 135-149).

MRI and histological analysis of brain metastasis and the effect of systemic inflammation

Hamilton, Alastair M. A.

January 2013

Background: Brain metastasis is a leading cause of cancer mortality and affects 20-40% of all cancer patients. The BBB is responsible for isolation and protection of the brain parenchyma from many diagnostic and therapeutic agents. New molecular agents that target tumour-associated VCAM-1 expression on the brain endothelium show improvements in the early diagnosis of brain metastasis. The vascular endothelium of the CNS plays an important role in the maintenance of the brain microenvironment and possibly aids the extravasation of tumour cells via expression of CAMs. Aims: Using the breast carcinoma-derived 4T1 cell line, syngeneic to BALB/c mice, this work aimed (i) to determine the level of colocalisation between VCAM-1 expression at sites of brain metastasis and the presence of VCAM-MPIO-induced hypointensities in MR datasets; (ii) to describe the normal developmental characteristics of the intracardial BALB/c-4T1 brain metastatic model in the absence of overt inflammation; (iii) to test the effects of an adenovirus-induced systemic inflammatory challenge on metastatic uptake and development in the brain. Results: The level of correspondence of VCAM-MPIO-derived hypointensities with VCAM-1 expression at the tumour site was found to be dependent on the size of metastasis. An improved method for detection of VCAM-MPIO hypointensities using an automated method has been presented. Tumours were found to develop preferentially on venous rather than arteriolar blood vessels, and showed greater and lesser abundance in different anatomical brain regions. Adenovirus injection was found to cause an upregulation of a range of peripheral pro-inflammatory cytokines, and expression of VCAM-1 on cerebral vasculature, preferentially on arteriolar blood vessels. Both pre- and post-treatment with adenovirus caused a two-fold reduction in tumour numbers and altered developmental characteristics of established tumours, although no significant differences were observed in VCAM-MPIO hypointensities in MR datasets. Conclusions: The development of molecular MRI approaches to target VCAM-1 expression at the site of brain metastases has improved the sensitivity of tumour detection. 4T1-GFP metastasis to the brain is specific both to anatomical sites and to regions of the vascular bed, suggesting differences in vascular morphology and/or signalling dynamics in these locations. The changes in tumour number and morphology as a result of systemic inflammation suggest an anti-tumour effect of adenoviral treatment and, given the role of the systemic immune system and its importance in the development of immunotherapies, possible future directions for research.

612.1