Browsing by Author "Strobl, Jeannine S."

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    Age and Sex Related Behavioral Changes in Mice Congenitally Infected with Toxoplasma gondii: Role of dopamine and other neurotransmitters in the genesis of behavioral changes due to congenital infection and attempted amelioration with interferon gamma
    Goodwin, David G. (Virginia Tech, 2011-07-12)
    Evidence suggests that the neurotropic parasite Toxoplasma gondii may play a role in the development of cognitive impairments. My hypothesis was that congenital exposure to T. gondii would lead to detectable age and sex related differences in behavior and neurotransmitter levels in mice. The neurotransmitter dopamine and commonly used anti-schizophrenic agents were evaluated against T. gondii in human fibroblast cells. Dopamine caused a significant increase in tachyzoite numbers at 250 nM but not 100 nM and the drugs valproic acid, fluphenazine, thioridazine and trifluoperazine inhibited T. gondii development. The effects T. gondii infection had on behavior were examined using a congenital mouse model. Previous work demonstrated maternal immune stimulation (MIS) with interferon gamma (INF-g) resulted in decreased fetal mortality from congenital T. gondii infections; therefore I examined the effects of INF- g treatment of mothers to determine if protection from the behavioral effects of T. gondii occurred in their offspring. No differences in concentrations of neurotransmitters in the brains of congenitally infected mice were observed. I found that mice infected with T. gondii developed adult onset behavior impairments with decreased rate of learning, increased activity and decreased memory, indicating cognitive impairment for male mice and not female mice. My findings support the evidence T. gondii is a factor in the development of cognitive impairments. My results for T. gondii exposed male mice are consistent with the convention that males have more cognitive impairments in the prodromal stage of schizophrenia. MIS with IFN-g had a minimal effect on behavior post sexual maturity but had a greater effect on pre sexual maturity female mice which exhibited difficulties with spatial memory, coordination and the ability to process stimuli. The results indicate the behavior alterations from IFN- g are transient. When MIS is given prior to congenital infection with T. gondii, we detected no behavior deficits in any group of mice, including male mice post sexual maturity. Based on the results of my study, I must reject the hypothesis that neurotransmitter levels are influenced by congenital toxoplasmosis and accept the hypothesis that congenital T. gondii infection caused cognitive impairments in male mice post sexual maturity.
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    Congenital infection of mice with toxoplasma gondii induces minimal change in behavior and no change in neurotransmitter concentrations
    Goodwin, David G.; Hrubec, Terry C.; Klein, Bradley G.; Strobl, Jeannine S.; Werre, Stephen R.; Han, Qian; Zajac, Anne M.; Lindsay, David S. (American Society of Parasitology, 2012-08-01)
    We examined the effect of maternal Toxoplasma gondii infection on behavior and the neurotransmitter concentrations of congenitally infected CD-I mice at 4 and 8 wk of age when latent tissue cysts would be present in their brains. Because of sex-associated behavioral changes that develop during aging, infected female mice were compared with control females and infected male mice were compared with control males. Only the short memory behavior (distance between goal box and first hole investigated) of male mice congenitally infected with T. gondii was significantly different (P < 0.05) from that of uninfected control males at both 4 and 8 wk by using the Barnes maze test. The other parameters examined in the latter test, i.e., functional observational battery tests, virtual cliff, visual placement, and activity tests, were not significantly different (P > 0.05) at 4 and 8 wk. Concentrations of neurotransmitters and their metabolites (dopamine; 3,4-dihydroxyphenylacetic acid; homovanillic acid; norepinephrine; epinephrine; 3-methoxy-4-hydroxyphenylglycol; serotonin; and 5-hydroxyindoleacetic acid) in the frontal cortex and striatum were not different (P > 0.05) between infected and control mice at 8 wk of age. The exact mechanism for the observed effect on short-term memory in male mice is not known, and further investigation may help elucidate the molecular mechanisms associated with the proposed link between behavioral changes and T gondil infection in animals. We were not able, however, to confirm the widely held belief that changes in neurotransmitters result from chronic T. gondii infection of the brain.
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    Dopamine Stimulates Propagation of Toxoplasma gondii Tachyzoites in Human Fibroblast and Primary Neonatal Rat Astrocyte Cell Cultures
    Strobl, Jeannine S.; Goodwin, David G.; Rzigalinski, Beverly A.; Lindsay, David S. (American Society of Parasitology, 2012-12-01)
    Toxoplasma gondii is an obligate intracellular parasite often found in the brain of humans. Research has shown a correlation between prevalence of antibody titers to T. gondii and psychological illness in humans. Recent studies indicate that individuals seropositive for T. gondii antibodies are more likely to develop psychotic disorders including schizophrenia, which is associated with changes in the dopamine neurotransmitter system. Dopamine in the brain may play a role in proliferation, chemoattraction, infection efficiency, or stage conversion of T. gondii. Because tachyzoites are the first developmental stage to reach the brain, the present study was conducted to determine the effects of dopamine on their development in vitro. In human fibroblast host cells, dopamine was added at either 100 nM or 250 nM to cell culture media, and the numbers of tachyzoites produced at 48 hr were determined and compared to vehicle-treated controls. An increase of tachyzoite numbers and increased destruction in cell monolayer were observed at both concentrations of dopamine. Dopamine used at 250 nM caused a significant (P < 0.05) increase in tachyzoites counts compared to controls. Dopamine antagonists (10 mu M) did not significantly alter dopamine-stimulated tachyzoite production in human fibroblasts. In primary neonatal rat astrocyte cell cultures, dopamine (200 mu M) significantly (P < 0.05) increased numbers of intracellular tachyzoites after 24 hr. The role that this increase plays in tachyzoite production under the stimulus of dopamine in the modulation of neural infection in humans awaits further studies.
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    Evaluation of Five Antischizophrenic Agents Against Toxoplasma gondii in Human Cell Cultures
    Goodwin, David G.; Strobl, Jeannine S.; Lindsay, David S. (American Society of Parasitology, 2011-02-01)
    An increasing interest in the association of the presence of antibodies to Toxoplasma gondii and the development of schizophrenia in patients has been generated over the last several years. Some antischizophrenia agents have been shown to have activity against T gondii in cell culture assays and to ameliorate behavioral changes associated with chronic T gondii infection in rats. In the present study, we examined the effects of commonly used antipsychotic and mood stabilizing agents (haloperidol, clozapine, fluphenazine, trifluoperazine, and thioridazine) for activity against developing tachyzoites of the RH strain of T. gondii in human fibroblast cell cultures. Neither haloperidol nor clozapine had a measurable effect. Fluphenazine had an IC(50) of 1.7 mu M, thioridazine had an IC(50) of 1.2 mu M, and trifluoperazine had an IC(50) of 3.8 mu M. Our study demonstrates that some agents used to treat schizophrenia have the ability to inhibit T. gondii proliferation in cell culture.
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    Identification of Cell Biomechanical Signatures Using Three Dimensional Isotropic Microstructures
    Nikkhah, Mehdi (Virginia Tech, 2010-12-03)
    Micro and nanofabrication technologies have been used extensively in many biomedical and biological applications. Integration of MEMS technology and biology (BioMEMS) enables precise control of the cellular microenvironments and offers high throughput systems. The focus of this research was to develop three dimensional (3-D) isotropic microstructures for comprehensive analysis on cell-substrate interactions. The aim was to investigate whether the normal and cancerous cells differentially respond to their underlying substrate and whether the differential response of the cells leads to a novel label-free technique to distinguish between normal and cancerous cells. Three different generations of 3-D isotropic microstructures comprised of curved surfaces were developed using a single-mask, single-etch step process. Our experimental model included HS68 normal human fibroblasts, MCF10A normal human breast epithelial cells and MDA-MB-231 metastatic human breast cancer cells. Primary findings on the first generation of silicon substrates demonstrated a distinct adhesion and growth behavior in HS68 and MDA-MB-231 cells. MDA-MB-231 cells deformed while the fibroblasts stretched and elongated their cytoskeleton on the curved surfaces. Unlike fibroblasts, MDA-MB-231 cells mainly trapped and localized inside the deep microchambers. Detailed investigations on cytoskeletal organization, adhesion pattern and morphology of the cells on the second generation of the silicon substrates demonstrated that cytoskeletal prestress and microtubules organization in HS68 cells, cell-cell junction and cell-substrate adhesion strength in MCF10A cells, and deformability of MDA-MB-231 cells (obtained by using AFM technique) affect their behavior inside the etched cavities. Treatment of MDA-MB-231 cells with experimental breast cancer drug, SAHA, on the second generation of substrates, significantly altered the cells morphology, cytoarchitecture and adhesion pattern inside the 3-D microstructures. Third generation of silicon substrates was developed for comprehensive analysis on behavior of MDA-MB-231 and MCF10A cells in a co-culture system in response to SAHA drug. Formation of colonies of both cell types was evident inside the cavities within a few hours after seeding the cells on the chips. SAHA selectively altered the morphology and cytoarchitecture in MDA-MB-231 cells. Most importantly, the majority of MDA-MB-231 cells stretched inside the etched cavities, while the adhesion pattern of MCF10A cells remained unaltered. In the last part of this dissertation, using AFM analysis, we showed that the growth medium composition has a pronounced effect on cell elasticity. Our findings demonstrated that the proposed isotropic silicon microstructures have potential applications in development of biosensor platforms for cell segregation as well as conducting fundamental biological studies.
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    The impact of sphingosine kinase inhibitor-loaded nanoparticles on bioelectrical and biomechanical properties of cancer cells
    Babahosseini, Hesam; Srinivasaraghavan, Vaishnavi; Zhao, Zongmin; Gillam, Francis; Childress, Elizabeth; Strobl, Jeannine S.; Santos, Webster L.; Zhang, Chenming; Agah, Masoud (The Royal Society of Chemistry, 2015-11-19)
    Cancer progression and physiological changes within the cells are accompanied by alterations in the biophysical properties. Therefore, the cell biophysical properties can serve as promising markers for cancer detection and physiological activities. To aid in the investigation of the biophysical markers of cells, a microfluidic chip has been developed which consists of a constriction channel and embedded microelectrodes. Single-cell impedance magnitudes at four frequencies and entry and travel times are measured simultaneously during their transit through the constriction channel. This microchip provides a high-throughput, label-free, automated assay to identify biophysical signatures of malignant cells and monitor the therapeutic efficacy of drugs. Here, we monitored the dynamic cellular biophysical properties in response to sphingosine kinase inhibitors (SphKIs), and compared the effectiveness of drug delivery using poly lactic-co-glycolic acid (PLGA) nanoparticles (NPs) loaded with SphKIs versus conventional delivery. Cells treated with SphKIs showed significantly higher impedance magnitudes at all four frequencies. The bioelectrical parameters extracted using a model also revealed that the highly aggressive breast cells treated with SphKIs shifted electrically towards that of a less malignant phenotype; SphKI-treated cells exhibited an increase in cell-channel interface resistance and a significant decrease in specific membrane capacitance. Furthermore, SphKI-treated cells became slightly more deformable as measured by a decrease in their channel entry and travel times. We observed no significant difference in the bioelectrical changes produced by SphKI delivered conventionally or with NPs. However, NPs-packaged delivery of SphKI decreased the cell deformability. In summary, this study showed that while the bioelectrical properties of the cells were dominantly affected by SphKIs, the biomechanical properties were mainly changed by the NPs.
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    A Microfabricated Bioimpedance Sensor with Enhanced Sensitivity for Early Breast Cancer Detection
    Srinivasaraghavan, Vaishnavi (Virginia Tech, 2011-12-01)
    Bioimpedance is the term given to the complex impedance value that is characteristic of the resistance that biological cells offer to the flow of electric current. The objective of this study is to analyze the differences in the bioimpedance of highly metastatic MDA-MB-231 and normal MCF 10A breast epithelial cells and use this information to detect a very small number of breast cancer cells present in a background of normal breast cells and other cells that are typically present in a human biopsy sample.To accomplish this, a bioimpedance sensor with flat gold microelectrodes on a silicon substrate was designed and fabricated. Suberoylanilide hydroxamic acid (SAHA), an FDA-approved anti-cancer agent was used to improve the sensitivity of the bioimpedance sensor towards cancer cells by selectively modifying their cytoarchitecture.
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    Scalable nanolaminated SERS multiwell cell culture assay
    Ren, Xiang; Nam, Wonil; Ghassemi, Parham; Strobl, Jeannine S.; Kim, Inyoung; Zhou, Wei; Agah, Masoud (Springer Nature, 2020)
    This paper presents a new cell culture platform enabling label-free surface-enhanced Raman spectroscopy (SERS) analysis of biological samples. The platform integrates a multilayered metal-insulator-metal nanolaminated SERS substrate and polydimethylsiloxane (PDMS) multiwells for the simultaneous analysis of cultured cells. Multiple cell lines, including breast normal and cancer cells and prostate cancer cells, were used to validate the applicability of this unique platform. The cell lines were cultured in different wells. The Raman spectra of over 100 cells from each cell line were collected and analyzed after 12 h of introducing the cells to the assay. The unique Raman spectra of each cell line yielded biomarkers for identifying cancerous and normal cells. A kernel-based machine learning algorithm was used to extract the high-dimensional variables from the Raman spectra. Specifically, the nonnegative garrote on a kernel machine classifier is a hybrid approach with a mixed nonparametric model that considers the nonlinear relationships between the higher-dimension variables. The breast cancer cell lines and normal breast epithelial cells were distinguished with an accuracy close to 90%. The prediction rate between breast cancer cells and prostate cancer cells reached 94%. Four blind test groups were used to evaluate the prediction power of the SERS spectra. The peak intensities at the selected Raman shifts of the testing groups were selected and compared with the training groups used in the machine learning algorithm. The blind testing groups were correctly predicted 100% of the time, demonstrating the applicability of the multiwell SERS array for analyzing cell populations for cancer research.