Matching Items (5)
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- All Subjects: Microfluidics
- Language: English
- Creators: Nikkhah, Mehdi
Description
Tumor-stroma interactions significantly influence cancer cell metastasis and disease progression. These interactions partly comprise crosstalk between tumor and stromal fibroblasts, but the key molecular mechanisms within the crosstalk governing cancer invasion are still unclear. Here we develop a 3D in vitro organotypic microfluidic to model tumor-stroma interaction by mimicking the spatial organization of the tumor microenvironment on a chip. We co-culture breast cancer and patient-derived fibroblast cells in 3D tumor and stroma regions respectively and combine functional assessments, including cancer cell migration, with transcriptome profiling to unveil the molecular influence of tumor-stroma crosstalk on invasion. This led to the observation that cancer associated fibroblasts enhanced invasion in 3D by inducing the expression of a novel gene of interest, GPNMB, in breast cancer cells resulting in increased migration speed. Importantly, knockdown of GPNMB blunted the influence of CAFs on enhancing cancer invasion. Overall, these results demonstrate the ability of our model to recapitulate patient specific tumor microenvironment to investigate cellular and molecular consequences of tumor-stroma interactions.
ContributorsBarrientos, Eric Salvador (Author) / Nikkhah, Mehdi (Thesis director) / Veldhuizen, Jaime (Committee member) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2019-05
Description
After more than 40 years since the signing of the National Cancer Act in 1970, cancer remains a formidable challenge. Cancer is currently the second most common cause of death in the United States, and worldwide cancer cases are projected to rise 50% between 2012 and 2030 [1-2]. While researchers have dramatically expanded our understanding of the biology of cancer, they have also revealed the staggering complexity and difficulty of developing successful treatments for the disease. More complex assays involving three dimensional cell culture offer the potential to model complex interactions, such as those involving the extracellular matrix (ECM), chemical concentration gradients, and the impact of vascularization of a tissue mass. Modern cancer assays thus promise to be both more accurate and more complex than previous models. One promising newly developed type of assay is microfluidics. Microfluidic devices consist of a silicone polymer stamp bonded to a glass slide. The stamp is patterned to produce a network of channels for cell culture. These devices allow manipulation of liquids on a sub-millimeter level, allowing researchers to produce a tightly controlled 3D microenvironment for cell culture. Our lab previously developed a microfluidic device to measure cancer cell invasion in response to a variety of signals and conditions. The small volume associated with microfluidics offers a number of advantages, but simultaneously make it impractical to use certain traditional cell analysis procedures, such as Western Blotting. As a result, measuring protein expression of cells in the microfluidic device was a continuing challenge. In order to expand the utility of microfluidic devices, it was therefore very enticing to develop a means of measuring protein expression inside the device. One possible solution was identified in the technique of In-Cell-Western blotting (ICW). ICW consists of using infrared-fluorescently stained antibodies to stain a protein of interest. This signal is measured using an infrared laser scanner, producing images that can be analyzed to quantitatively measure protein expression. ICW has been well validated in traditional 2D plate culture conditions, but has not been applied in conjunction with microfluidic devices. This project worked to evaluate In-Cell-Western blotting for use in microfluidic devices as a method of quantifying protein expression in situ.
ContributorsKratz, Alexander Franz (Author) / Nikkhah, Mehdi (Thesis director) / Truong, Danh (Committee member) / School of Life Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
Evolving knowledge about the tumor microenvironment (TME) is driving innovation in designing novel therapies against hard-to-treat breast cancer. Addressing the immune elements within the tumor microenvironment (TME) has emerged as a highly encouraging strategy for treating cancer. Although current immunotherapies have made advancements in reinstating the body's ability to fight tumors, the search for effective cancer treatments to combat tumor evasion remains a formidable challenge. In line with this objective, there is a pressing need to better understand the complex tumor-immune dynamics and crosstalk within the TME. To evaluate the cancer-immune interaction, this study aimed at investigating the crosstalk between naïve macrophages and cytotoxic T cells in driving tumor progression using an organotypic 3D ex vivo tumor on-a-chip model. The presented microfluidic platform consists of two distinct regions namely: The tumor region and the stroma region separated by trapezoidal microposts to ensure interconnectivity between regions thereby incorporating high spatial organization. In the established triculture platform, the complex Tumor Immune Microenvironment was successfully recapitulated by incorporating naïve macrophage and T cells within an appropriate 3D matrix. Through invasion and morphometric analyses, definitive outcomes were obtained that underscore the significant contribution of macrophages in facilitating tumor progression. Furthermore, the inclusion of T cells led to a notable decrease in the migratory speed of cancer cells and macrophages, underscoring the reciprocal communication between these two immune cell populations in the regulation of tumor advancement. Overall, this study highlights the complexity of TME and underscores the critical role of immune cells in regulating cancer progression.
ContributorsManoharan, Twinkle Jina Minette (Author) / Nikkhah, Mehdi (Thesis advisor) / Acharya, Abhinav P (Committee member) / Wang, Shaopeng (Committee member) / Arizona State University (Publisher)
Created2023
Description
Glioblastoma Multiforme (GBM) is a grade IV astrocytoma and the most aggressive form of cancer that begins within the brain. The two-year average survival rate of GBM in the United States of America is 25%, and it has a higher incidence in individuals within the ages of 45 - 60 years. GBM Tumor formation can either begin as normal brain cells or develop from an existing low-grade astrocytoma and are housed by the perivascular niche in the brain microenvironment. This niche allows for the persistence of a population of cells known as glioma stem cells (GSC) by supplying optimum growth conditions that build chemoresistance and cause recurrence of the tumor within two to five years of treatment. It has therefore become imperative to understand the role of the perivascular niche on GSCs through in vitro modelling in order to improve the efficiency of therapeutic treatment and increase the survival rate of patients with GBM.
In this study, a unique three dimensional (3D) microfluidic platform that permitted the study of intercellular interactions between three different cell types in the perivascular niche of the brain was developed and utilized for the first time. Specifically, human endothelial cells were embedded in a fibrin matrix and introduced into the vascular layer of the microfluidic platform.
After spontaneous formation of a vascular layer, Normal Human Astrocytes and Patient derived GSC were embedded in a Matrigel® matrix and incorporated in the stroma and tumor regions of the microfluidic device respectively.
Using the established platform, migration, proliferation and stemness of GSCs studies were conducted. The findings obtained indicate that astrocytes in the perivascular niche significantly increase the migratory and proliferative properties of GSCs in the tumor microenvironment, consistent with previous in vivo findings.
The novel GBM tumor microenvironment developed herein, could be utilized for further
in-depth cellular and molecular level studies to dissect the influence of individual factors within the tumor niche on GSCs biology, and could serve as a model for developing targeted therapies.
In this study, a unique three dimensional (3D) microfluidic platform that permitted the study of intercellular interactions between three different cell types in the perivascular niche of the brain was developed and utilized for the first time. Specifically, human endothelial cells were embedded in a fibrin matrix and introduced into the vascular layer of the microfluidic platform.
After spontaneous formation of a vascular layer, Normal Human Astrocytes and Patient derived GSC were embedded in a Matrigel® matrix and incorporated in the stroma and tumor regions of the microfluidic device respectively.
Using the established platform, migration, proliferation and stemness of GSCs studies were conducted. The findings obtained indicate that astrocytes in the perivascular niche significantly increase the migratory and proliferative properties of GSCs in the tumor microenvironment, consistent with previous in vivo findings.
The novel GBM tumor microenvironment developed herein, could be utilized for further
in-depth cellular and molecular level studies to dissect the influence of individual factors within the tumor niche on GSCs biology, and could serve as a model for developing targeted therapies.
ContributorsAdjei-Sowah, Emmanuella Akweley (Author) / Nikkhah, Mehdi (Thesis advisor) / Plaisier, Christopher (Committee member) / Mehta, Shwetal (Committee member) / Arizona State University (Publisher)
Created2020
Description
Synthetic biology is a novel method that reengineers functional parts of natural genes of interest to build new biomolecular devices able to express as designed. There is increasing interest in synthetic biology due to wide potential applications in various fields such as clinics and fuel production. However, there are still many challenges in synthetic biology. For example, many natural biological processes are poorly understood, and these could be more thoroughly studied through model synthetic gene networks. Additionally, since synthetic biology applications may have numerous design constraints, more inducer systems should be developed to satisfy different requirements for genetic design.
This thesis covers two topics. First, I attempt to generate stochastic resonance (SR) in a biological system. Synthetic bistable systems were chosen because the inducer range in which they exhibit bistability can satisfy one of the three requirements of SR: a weak periodic force is unable to make the transition between states happen. I synthesized several different bistable systems, including toggle switches and self-activators, to select systems matching another requirement: the system has a clear threshold between the two energy states. Their bistability was verified and characterized. At the same time, I attempted to figure out the third requirement for SR – an effective noise serving as the stochastic force – through one of the most widespread toggles, the mutual inhibition toggle, in both yeast and E. coli. A mathematic model for SR was written and adjusted.
Secondly, I began work on designing a new genetic system capable of responding to pulsed magnetic fields. The operators responding to pulsed magnetic stimuli in the rpoH promoter were extracted and reorganized. Different versions of the rpoH promoter were generated and tested, and their varying responsiveness to magnetic fields was recorded. In order to improve efficiency and produce better operators, a directed evolution method was applied with the help of a CRISPR-dCas9 nicking system. The best performing promoters thus far show a five-fold difference in gene expression between trials with and without the magnetic field.
This thesis covers two topics. First, I attempt to generate stochastic resonance (SR) in a biological system. Synthetic bistable systems were chosen because the inducer range in which they exhibit bistability can satisfy one of the three requirements of SR: a weak periodic force is unable to make the transition between states happen. I synthesized several different bistable systems, including toggle switches and self-activators, to select systems matching another requirement: the system has a clear threshold between the two energy states. Their bistability was verified and characterized. At the same time, I attempted to figure out the third requirement for SR – an effective noise serving as the stochastic force – through one of the most widespread toggles, the mutual inhibition toggle, in both yeast and E. coli. A mathematic model for SR was written and adjusted.
Secondly, I began work on designing a new genetic system capable of responding to pulsed magnetic fields. The operators responding to pulsed magnetic stimuli in the rpoH promoter were extracted and reorganized. Different versions of the rpoH promoter were generated and tested, and their varying responsiveness to magnetic fields was recorded. In order to improve efficiency and produce better operators, a directed evolution method was applied with the help of a CRISPR-dCas9 nicking system. The best performing promoters thus far show a five-fold difference in gene expression between trials with and without the magnetic field.
ContributorsHu, Hao (Author) / Wang, Xiao (Thesis advisor) / Stabenfeldt, Sarah (Committee member) / Brafman, David (Committee member) / Arizona State University (Publisher)
Created2016