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

The Induction of Traumatic Brain Injury by Blood Brain Barrier Disruption

Skopin, Mark D.

10 June 2011

No description available.

Biomedical Engineering

Medicine

Neurosciences

Blood-brain barrier

memory and learning

Barnes circular maze

traumatic brain injury

hyperosmotic solution

controlled cortical impact

Implementation of Spatial Learning Assays for Behavioral Assessment of Neuronal Pathology

Wolfe, Steven A.

09 September 2010

No description available.

Behaviorial Sciences

Biomedical Research

Engineering

Pathology

Physiological Psychology

Traumatic Brain Injury

Blood-Brain Barrier

Spatial Learning

Mannitol

Evaluation of Novel Efflux Transport Inhibitor for the improvement of drug delivery through epithelial cell monolayer

Sonawane, Amit

January 2015

Blood-brain barrier (BBB) is a unique membranous barrier, which segregates brain from the circulating blood. It works as a physical and metabolic barrier between the central nervous system (CNS) and periphery. In mammals, endothelial cells were shown to be of BBB and are characterized by the tight junctions along with efflux system which are responsible for the restriction of movement of molecules within the cells. Efflux system consists of multidrug resistance proteins such as P-glycoprotein (P-gp). P-gp removes substances out back from the brain to the blood before they reach to the brain. So the barrier is impermeable to many compounds such as amino acids, ions, small peptides and proteins, making it the most challenging factor for the development of new drugs for targeting CNS. Curcumin is a bioactive compound that has a number of health promoting benefits such as anti-inflammatory, anticancer, anti-oxidant agent; as well as a role in neurodegenerative diseases, but low oral bioavailability is the major limiting factor. Low water solubility and rapid metabolism are the two important factors responsible for poor bioavailability of curcumin. Galaxolide is a musk compound and previously known for the bioaccumulation of toxic components in the aquatic animals by interference with the activity of multidrug/multixenobiotic resistance efflux transporters (MDR/MXR). The bioavailability of curcumin can be enhanced when administered with galaxolide. This study was carried out to investigate the effect of galaxolide on the permeation of curcumin through the epithelial cell monolayers. MDCKII-MDR1 cell monolayer is used an in vitro blood-brain barrier model while Caco-2 monolayer is used as an in vitro intestinal model, which also expresses the P-glycoprotein. The curcumin and galaxolide were separately solubilised in the DMSO and used in combination to perform permeation study, to determine the effect of galaxolide on curcumin permeation through epithelial cell monolayers. The galaxolide shows an efflux protein inhibition activity and this activity was used to enhance permeation of curcumin through the Caco-2 monolayer. In summary, galaxolide is a novel permeation enhancer molecule, which can be used for the improvement of drug delivery of other bioactive compounds in future. / Department of Social Welfare, Govt. of Maharashtra (India)

Galaxolide

P-Glycoprotein inhibition

Permeability study

Blood-Brain Barrier

Multidrug resistance (MDR)

Curcumin

Mechanisms regulating vascular function after ischemic brain injury

Tuohy, Mary Claire

January 2024

Persistent cerebrovascular dysfunction has been postulated as one mechanism that may contribute to divergent functional trajectories after ischemic stroke. However, how brain endothelial cells (BECs) acutely respond to ischemia and what endogenous signals subsequently regulate vascular normalization remain poorly understood. To spatiotemporally interrogate neuronal activity and hemodynamics in the acute period after ischemic brain injury we used wide-field imaging. Local ischemia consistently provoked a large-amplitude cortical spreading depolarization (CSD) accompanied by strong vasoconstriction, followed by subsequent diverse CSDs with varying hemodynamic responses. Small CSDs with slow depolarization induced vasodilation in well oxygenated cortical tissue. CSDs of larger amplitude with non-sustained depolarization induced biphasic vascular responses. CSDs of large amplitude, characterized by rapid and prolonged depolarization, drove vasoconstriction in deoxygenated cortical tissue with sustained neuronal depolarization. These observations support a model in which vascular responses after acute brain injury are dependent upon the local relationship between CSD features (i.e. slope, duration, and amplitude of depolarization) and the underlying cortical state (i.e. neuronal activity, perfusion, oxygenation). After this acute period, the ischemic brain is characterized by profound changes in immune cell composition and function. To understand how distinct immune signaling pathways regulate blood-brain barrier (BBB) repair and vascular remodeling after ischemic brain injury, I investigated a unique post-ischemic BEC type one interferon (IFN1) signature. Functional assays and single-cell transcriptomic analyses in IFN1 receptor (Ifnar1) inducible EC knockout (iECKO) mice revealed that loss of BEC IFN1 signaling exacerbated post-stroke barrier disruption and resulted in an expansion of BECs enriched in genes involved in angiogenic processes. Conversely, acute administration of exogenous IFNI ameliorated post stroke BBB disruption. In vitro assays supported that IFNI signaling modulates BEC junctional protein stabilization and vascular endothelial growth factor (VEGF) signaling to enhance BEC barrier properties and suppress angiogenic features, respectively. These findings suggest that endogenous BEC IFN signaling after ischemic brain injury restricts angiogenesis to potentially promote acute barrier function. These studies, which span from the systems to molecular level, demonstrate that brain ischemia and post-ischemic sequelae have a profound impact on cerebrovascular dysfunction and recovery. Furthermore, each study introduces a novel framework to investigate how differences in acute BEC responses may contribute to variable vascular trajectories and longitudinal brain function after ischemic insult.

Neurosciences

Immunology

Cerebrovascular disease--Pathophysiology

Endothelial cells

Blood-brain barrier disorders

Cerebral ischemia--Pathophysiology

Cognitive and motor development in HIV infected children : a systematic review

Kgomo, Gretta Tumelo

03 1900

Thesis (MCurr)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: The global epidemic of HIV continues with an estimated 2.2 million children under 15 years of age worldwide living with HIV and 640 000 newly infected in 2004 (WHO, 2009). HIV crosses the blood–brain barrier which may lead to neuronal damage and death. There is controversial evidence within available research on effects of HIV on cognitive and motor development in children because of the limitations imposed by study designs, study populations and study methodological quality. The aims of the review were: - To conduct a systematic review of published research to establish the effects and the prevalence of HIV infection on cognitive and motor development in children. - To critically appraise the methodological quality of published research regarding cognitive and motor development of HIV infected children. The objectives of the review were: - To assess evidence on the cognitive and motor development of HIV-1 infected children - To describe anthropometric outcomes including: weight for age, weight for height, height for age and head circumference in children with a HIV infection. - To assess the methodological quality of studies on the cognitive and motor development of HIV infected children. The following databases were searched for identification of articles; MEDLINE, Google Scholar, AIDSTRIALS, AIDSLINE and CINHAL. The search time frame included published works from inception to July 2011 without language restrictions. Analytical observational trials that assessed at least one outcome (cognitive or motor development or 1 of the anthropometric outcomes) between HIV positive and HIV negative children aged 5 years and below or children with a mean age of less than 5 years were employed. Two review authors independently searched for eligible studies, evaluated methodological quality and extracted the data. Meta-analysis was carried out using Rev Man 5.1 using the risk ratio for categorical data and standard mean difference for continuous data. Fifteen studies with a total of 3 086 participants met the inclusion criteria. HIV infected children were 2.45 times at higher risk of developing cognitive developmental delay than HIV negative children (RR, 95% CI, 1.95, 3.07, P < 0.00001). Infected children scored - 0.54 less than HIV negative children (SMD 95% CI, -0.70, -0.39, 97, p < 0.00001) for cognitive development and -0.68 in motor development (SMD 95% CI, -0.82, -0.55, p< 0.00001). The risk of motor developmental delays was 2.95 times in HIV positive compared with HIV negative children (RR 95% CI, 2.19, 3.99, p < 0.00001). HIV infected children are slower in aspects of cognitive and motor development compared to their HIV negative counterparts. They also showed delays in anthropometric outcomes; weight for age and height for age. Study design influenced results of the studies with children scoring more on cross sectional than cohort studies. There is still need to develop culturally appropriate or standardise neurodevelopment tools as most African studies still rely on international tools. More evidence is needed on the effectiveness of HAART in reducing cognitive and motor delay. / AFRIKAANSE OPSOMMING: Die wêreldwye MIV epidemie duur voort met ongeveer 2.2 miljoen kinders onder 15 jarige ouderdom wat wêreldwyd met MIV leef en 640 000 onlangs in 2004 geïnfekteerd (WHO, 2009). MIV strek oor die bloed-brein grens wat kan lei tot neuronale skade en die dood. Daar is kontroversiële bewys binne beskikbare navorsing oor die effek wat MIV het op kognitiewe en motoriese ontwikkeling in kinders, vanweë die beperkinge wat geplaas word deur studie ontwerpe, studie bevolkings en studie metodologiese kwaliteit. Die doelwitte van die oorsig is om - ‘n sistematiese oorsig van gepubliseerde navorsing te doen om sodoende die effek en voorkoms van MIV infeksie op kognitiewe en motoriese ontwikkeling by kinders vas te stel - ’n kritiese waardering van die metodologiese kwaliteit van gepubliseerde navorsing te doen ten opsigte van die kognitiewe en motoriese ontwikkeling van MIV geïnfekteerde kinders. Die doelwitte van die oorsig is om - assessering te doen van die bewyse van kognitiewe en motoriese ontwikkeling by MIV-1 geïnfekteerde kinders - antropometriese uitkomste te beskryf, insluitend: gewig vir ouderdom, gewig vir hoogte, hoogte vir ouderdom en omtrek van die hoof by kinders met ’n MIV infeksie - die metodologiese kwaliteit te assesseer van studies op die kognitiewe en motoriese ontwikkeling van MIV geïnfekteerde kinders. Die volgende databasisse is nagevors vir die identifisering van artikels: MEDLINE, Google Scholar, AIDSTRIALS, AIDSLINE en CINHAL. Die tydraamwerk vir navorsing het gepubliseerde werk ingesluit vanaf aanvang tot Julie 2011 sonder taalbeperkings. Analitiese waarneembare toetse wat ten minste een uitkoms geassesseer het (kognitiewe of motoriese ontwikkeling of 1 van die antropometriese uitkomste) tussen MIV positiewe en MIV negatiewe kinders van 5 jarige ouderdom en jonger, of kinders met ’n gemiddelde ouderdom van minder as 5 jaar is betrek. Twee oorsig outeurs het onafhanklik vir geskikte studies gesoek, metodologies geëvalueer en data getrek. Meta-analise was uitgevoer deur gebruik te maak van Rev Man 5.1 met behulp van die risiko-ratio vir kategoriese data en die standaard gemiddelde verskil vir aaneenlopende data. Vyftien studies met ’n totaal van 3 086 deelnemers met die insluitingskriteria. MIV geïnfekteerde kinders het 2.45 keer ’n hoër risiko gehad om kognitiewe ontwikkelingsvertraging te ontwikkel as MIV negatiewe kinders (RR, 95% CI, 1.95, 3.07, P< 0.0000). Geïnfekteerde kinders het ’n -0.54 telling behaal, minder as MIV negatiewe kinders (SMD 95% CI, -0.70, -0.39,97 p < 0.00001) vir kognitiewe ontwikkeling en -0.68 vir motoriese ontwikkeling (SMD 95% CI, -0.82, -0.55, p< 0.00001). Die risiko van motoriese ontwikkelingsvertragings was 2.95 keer by MIV positiewe in vergelyking met MIV negatiewe kinders (RR 95% CI, 2.19, 3.99. p < 0.00001). MIV geïnfekteerde kinders is stadiger in aspekte van kognitiewe en motoriese ontwikkeling in vergeyking met hulle MIV negatiewe eweknieë. Hulle het ook vertragings getoon in antropometriese uitkomste; gewig vir ouderdom en hoogte vir ouderdom. Studie ontwerpe het uitslae beïnvloed van die kinders wat ’n hoër telling behaal het met deursnee as in kohort studies. Daar is nog ’n behoefte om kultureel geskikte of gestandaardiseerde neuro-ontwikkelingsinstrumente te ontwikkel, omdat die meeste Afrika-studies nog steeds staat maak op internasionale instrumente. Meer bewyse is nodig aangaande die effektiwiteit van HAART om kognitiewe en motoriese vertraging te verminder.

Cognitive and motor development

HIV children -- Development

HIV crosses the blood–brain barrier

Dissertations -- Nursing

Theses -- Nursing

Motor ability in children

AIDS (Disease) in children

Cognition in children

THE PHARMACOKINETICS OF METAL-BASED ENGINEERED NANOMATERIALS, FOCUSING ON THE BLOOD-BRAIN BARRIER

Dan, Mo

01 January 2013

Metal-based engineered nanomaterials (ENMs) have potential to revolutionize diagnosis, drug delivery and manufactured products, leading to greater human ENM exposure. It is crucial to understand ENM pharmacokinetics and their association with biological barriers such as the blood-brain barrier (BBB). Physicochemical parameters such as size and surface modification of ENMs play an important role in ENM fate, including their brain association. Multifunctional ENMs showed advantages across the highly regulated BBB. There are limited reports on ENM distribution among the blood in the brain vasculature, the BBB, and brain parenchyma. In this study, ceria ENM was used to study the effect of size on its pharmacokinetics. Four sizes of ceria ENMs were studied. Five nm ceria showed a longer half-life in the blood and higher brain association compared with other sizes and 15 and 30 nm ceria had a higher blood cell association than 5 or 55 nm ceria. Because of the long circulation and high brain association of 5 nm ceria compared with other sizes, its distribution between the BBB and brain parenchyma was studied. The in situ brain perfusion technique showed 5 nm ceria (99%) on the luminal surface of the BBB rather than the brain parenchyma. For biomedical applications in the central nervous system (CNS), it is vital to develop stable and biocompatible ENMs and enhance their uptake by taking advantage of their unique properties. Cross-linked nanoassemblies entrapping iron oxide nanoparticles (CNA-IONPs) showed controlled particle size in biological conditions and less toxicity in comparison to Citrate-IONPs. CNA-IONPs considerably enhanced MRI T2 relaxivities and generated heat at mild hyperthermic temperatures (40 ~ 42°C) in the presence of alternating magnetic field (AMF). Numerous researchers showed mild whole body hyperthermia can increase BBB permeability for potential brain therapeutic application. Compared to conventional hyperthermia, AMF-induced hyperthermia increased BBB permeability with a shorter duration of hyperthermia and lower temperature, providing the potential to enhance IONP flux across the BBB with reduced toxicity. Overall, ENMs with optimized physicochemical properties can enhance their flux across the BBB into the brain with desirable pharmacokinetics, which provide great potential for diagnosis and therapy in the CNS.

Metal-based engineered nanomaterials

ENMs

blood-brain barrier (BBB)

ceria ENM

iron oxide nanoparticles

pharmacokinetics

Pharmaceutics and Drug Design

Pharmacy and Pharmaceutical Sciences