Study on the Lead Magnesium Titanate Gate H+ Ion Sensitive Field Effect Transistors

Jan, Pei-Jane

04 July 2001

In this thesis, the a-PMT (amorphous lead magnesium titanate) membranes have been prepared by sol-gel technique as H+ ion sensitive layers. The C-V measurements of the a-PMT/SiO2/Si EIS structures prepared by spin-on coating are used for examining the fabrication parameters and sensing properties. There exhibits the quasi-Nerstain response of 55¡V59 mV/pH in the range of pH 2¡V12, fabricated with the Mg-modified content of 4 mole%, the firing temperature of about 400 ¢J and the thickness of about 0.5

Lead magnesium titanate

Drift

Lifetime

Hysteresis

pH response

pH-ISFET

Pathogen-Specific Adaptations to Conserved Signaling Pathways in Cryptococcus neoformans

Ost, Kyla Selvig

January 2016

<p>Cryptococcus neoformans is an opportunistic fungal pathogen that causes significant disease worldwide. Even though this fungus has not evolved specifically to cause human disease, it has a remarkable ability to adapt to many different environments within its infected host. C. neoformans adapts by utilizing conserved eukaryotic and fungal-specific signaling pathways to sense and respond to stresses within the host. Upon infection, two of the most significant environmental changes this organism experiences are elevated temperature and high pH. </p><p>Conserved Rho and Ras family GTPases are central regulators of thermotolerance in C. neoformans. Many GTPases require prenylation to associate with cellular membranes and function properly. Using molecular genetic techniques, microscopy, and infection models, I demonstrated that the prenyltransferase, geranylgeranyl transferase I (GGTase I) is required for thermotolerance and pathogenesis. Using fluorescence microscopy, I found that only a subset of conserved GGTase I substrates requires this enzyme for membrane localization. Therefore, the C. neoformans GGTase I may recognize its substrate in a slightly different manner than other eukaryotic organisms. </p><p>The alkaline response transcription factor, Rim101, is a central regulator of stress-response genes important for adapting to the host environment. In particular, Rim101 regulates cell surface alterations involved in immune avoidance. In other fungi, Rim101 is activated by alkaline pH through a conserved signaling pathway, but this pathway had yet been characterized in C. neoformans. Using molecular genetic techniques, I identified and analyzed the conserved members of the Rim pathway. I found that it was only partially conserved in C. neoformans, missing the components that sense pH and initiate pathway activation. Using a genetic screen, I identified a novel Rim pathway component named Rra1. Structural prediction and genetic epistasis experiments suggest that Rra1 may serve as the Rim pathway pH sensor in C. neoformans and other related basidiomycete fungi. </p><p> To explore the relevance of Rim pathway signaling in the interaction of C neoformans with its host, I characterized the Rim101-regulated cell wall changes that prevent immune detection. Using HPLC, enzymatic degradation, and cell wall stains, I found that the rim101Δ mutation resulted in increased cell wall chitin exposure. In vitro co-culture assays demonstrated that increased chitin exposure is associated with enhanced activation of macrophages and dendritic cells. To further test this association, I demonstrated that other mutant strains with increased chitin exposure induce macrophage and dendritic cell responses similar to rim101Δ. We used primary macrophages from mutant mouse lines to demonstrate that members of both the Toll-like receptor and C-type lectin receptor families are involved in detecting strains with increased chitin exposure. Finally, in vivo immunological experiments demonstrated that the rim101Δ strain induced a global inflammatory immune response in infected mouse lungs, expanding upon our previous in vivo rim101Δ studies. These results demonstrate that cell wall organization largely determines how fungal cells are detected by the immune system.</p> / Dissertation

Microbiology

Molecular biology

Immunology

Cryptococcus neoformans

fungal pathogen

geranylgeranyl transferase

pH response

Rim101

Study on the pH-sensing characteristics of the hydrogen ion-sensitive field-effect transistors with sol-gel-derived lead titanate series gate

Jan, Shiun-Sheng

15 November 2002

The sol-gel-derived lead titanate (PbTiO3) membrane has been successfully applied as a novel pH-sensing layer to form the PbTiO3 gate ISFET (ion-sensitive field-effect transistor). There exhibit the excellent quasi-Nernstian response of 55-58 mV/pH, good surface adsorption and anticorrosion characteristics via the capacitance- voltage measurement of the electrolyte-insulator-semiconductor structure. At a specific pH concentration, the output and transfer characteristics of the PbTiO3 gate ISFET are very similar to the behaviours of MOSFETs (metal-oxide-semiconductor field-effect transistors), and the pH-ISFET model can be derived by the modified MOSFET model. As it operated in the nonsaturation region, there exhibits a linear pH response of about 55-58 mV/pH. Simultaneously, there exhibit the stable response time of 2-4 minutes, the drift of 0.5-1 mV/h, the hysteresis of 3-5 mV and the reduction rate of about ¡V10 mV/pH-day. On the other hand, as it operated in the saturation region, the pH responses and linearity can be controlled by adjusting the VGS values, e.g. the absolute pH response of 4.2, 24.8 and 31.3 uA/pH and the correlation coefficients of 0.9491, 0.9995 and 0.9996 at VGS= 1, 3 and 5 V can be obtained, respectively. Besides, the PbTiO3 gate ISFET has been modified by doping the Mg2+ and La3+ impurities into the PbTiO3 membrane. As a result, the former is a great benefit to improve the pH-sensing characteristics, which exhibits the pH response of 58-59 mV/pH, the drift of below 0.4 mV/h, the hysteresis of 1-3 mV and the reduction rate of -0.2 mV/pH-day. Finally, a digital pH meter has been successfully developed.

pH response

lead titanate

stable response time

hysteresis

drift

ISFET

sol-gel

lifetime

temperature effect

Mechanisms and Biological Costs of Bacterial Resistance to Antimicrobial Peptides

Lofton Tomenius, Hava

January 2016

The global increasing problem of antibiotic resistance necessarily drives the pursuit and discovery of new antimicrobial agents. Antimicrobial peptides (AMPs) initially seemed like promising new drug candidates. Already members of the innate immune system, it was assumed that they would be bioactive and non-toxic. Their common trait for fundamental, non-specific mode of action also seemed likely to reduce resistance development. In this thesis, we demonstrate the ease with which two species of pathogenic bacteria, the gram-negative Salmonella typhimurium (S. typhimurium), and the gram-positive Staphylococcus aureus (S. aureus), can gain increased tolerance and stable resistance to various AMPs. By serially passaging each bacterial species separately under increasing AMP selection pressure we observed increasing AMP tolerance. Resulting in independent bacterial lineages exposed to four different AMPs (including a two-AMP combination) that exhibited 2 to 16-fold increases in MIC. Substantial cross-resistance between the AMPs was observed. Additionally, the S. aureus mutants were found to be cross-resistant to human beta-defensins 1, 2, 3, and 4. The LPS molecule, with mutations in the waaY, pmrB and phoP genes, was the principal target for S. typhimurium resistance development. The main target for S. aureus remained elusive. Reduced membrane potential was a common change for two of the mutants, but not for the others. All sequenced mutants had one or more mutations in various stress response pathways. Fitness of the resistant mutants was assayed by growth rate analysis and in vitro virulence factor testing (e.g. survival response to bile, superoxide, acidic pH). Furthermore an in vivo survival/virulence test involving a mouse competition experiment (S. typhimurium) and sepsis model (S. aureus) was performed. In the absence of AMPs there was often little or no fitness reduction in the mutants. Our results suggest that AMP resistance mechanisms do not irrevocably weaken either species with regard to virulence characteristics or survival within the host. In light of these findings, we suggest that the progression of therapeutic use of AMPs should proceed with great caution since otherwise we might select for AMP resistant mutants that are more resistant to our innate host defenses and thereby potentially more virulent.

antimicrobial peptides

antibiotic resistance

fitness cost

Salmonella Typhimurium

Staphylococcus aureus

bile

serum

pH response

growth rate

mice

phoP

pmrB

waaY

LPS

LL-37

defensins

membrane potential

Nouveaux systèmes nanométriques et ph dépendant pour le transport de médicaments contre les phénomènes de résistances / pH-responsive nanoscale drug delivery systems for overcoming drug resistance

Liu, Juan

22 November 2016

La résistance aux médicaments constitue un obstacle majeur pour le traitement du cancer. Les systèmes nanoparticulaires de délivrance de médicaments (nanoparticule drug delivery system, NDDS) sont pressentis pour apporter un nouvel espoir dans le traitement du cancer afin de surmonter la résistance aux médicaments en délivrant spécifiquement l’agent anticancéreux dans la lésion tumorale par effet EPR. Cela aura pour effet d’augmenter la concentration locale en médicaments et par conséquent d’améliorer l'efficacité thérapeutique tout en épargnant les tissus sains afin d'éviter les effets secondaires liés à la thérapie. Dans la mesure où la tumeur a souvent un microenvironnement acide, nous souhaiterions en outre doter nos nanoparticules NDDS d’une sensibilité pH-dépendante afin de permettre une délivrance spécifique dans la tumeur. Au cours de cette thèse, nous avons élaboré différents NDDSs sensibles aux variations de pH en employant des stratégies différentes. Ces NDDSs peuvent spécifiquement libérer le médicament au niveau du tissu tumoral et dans les cellules elles-mêmes à des valeurs de pH acides. En augmentant la concentration intracellulaire de médicament, l'objectif de surmonter la résistance aux médicaments pourrait ainsi être atteint. La présente étude a permis de fournir de nouvelles connaissances sur la conception de nano-transporteurs pour surmonter la résistance multidrogue par l’élaboration de NDDS sensibles au pH et constitue donc un exemple illustrant parfaitement le fait que les progrès des nanotechnologies peuvent être avantageusement mis en œuvre pour développer de nouvelles perspectives thérapeutiques. / Drug resistance presents a great hurdle to cancer treatment. Nanotechnology-based drug delivery systems (NDDSs) are widely expected to bring new hope for cancer therapy to overcome drug resistance by specifically delivering anticancer drugs to tumor lesions via the EPR effect, hence increasing local drug concentrations and consequently enhancing therapeutic efficacy, and at the same time, sparing healthy tissues to avoid side effects. As tumors often have an acidic microenvironment, we would like to further endow the NDDS with a pH-responsive drug releasing property for specific tumor targeting. In this thesis, we established different pH-responsive NDDSs by employing different strategies. These NDDSs could specifically control drug release at tumor tissues and within tumor cells in response to acidic pH. By increasing the intracellular drug concentration, the goal of circumventing drug resistance in cancer was achieved. The present study provides new insights into the design of nanocarriers to overcome drug resistance through pH-responsive drug delivery, and illustrates how advances in nanotechnology can be advantageously implemented to enhance therapeutic outcomes.

Traitement du cancer

Résistance aux médicaments

PH-Dépendance

Nano-Transporteur

Cancer therapy

Drug resistance

Nanoparticle-Based drug delivery system

PH-Response

Nanocarrier

540