Development and Evaluation of Relaxation-Based Measures of Myelin Content and Microstructure in Rodent Brains

West, Kathryn Louise

17 November 2016

Advanced neuroimaging techniques provide the possibility to non-invasively understand and monitor white matter during development and disease. While data from quantitative MRI techniques, such as multiexponential T2 (MET2) and quantitative magnetization transfer (qMT), correlate with myelin content, neither provide an absolute measure of the myelin volume fraction (MVF). Additionally, in preclinical studies, despite time-intensity and small tissue samples, histology remains the gold standard for quantitatively assessing changes in myelin content and white matter microstructural properties, such as myelin thickness and the g-ratio (ratio of axon radius to myelinated fiber radius). Therefore, the work in this dissertation first established and validated methods for MVF imaging from MET2 and qMT against quantitative electron microscopy. We show strong agreement in adult, control mice along with three mouse models of white matter disease. Next, we applied MVF imaging in mice during normal development and observe good agreement between MET2 and qMT and with expected myelin development. To further investigate specific changes in myelin microstructure, recent methods proposed measuring the g-ratio from MRI (gMRI). We revised the model and displayed with quantitative histology that gMRI provides an axon-area-weighted g-ratio. Calculating gMRI requires an accurate measure of MVF; thus, we utilize our MVF imaging techniques to measure gMRI in mouse brain and detect changes in g-ratio with disease in agreement with quantitative histology. In short, we develop and validate measures of MVF and g-ratio from MRI which have the potential to non-invasively provide more specific and thorough assessment of white matter not obtainable with currently used methods.

Biomedical Engineering

Investigation of physiological and pathological vascular functions using engineered systems

Yoon, Christine

28 February 2019

The vasculature is a highly complex, hierarchical system that performs a variety of functions in both physiological and pathological contexts. To maintain tissue homeostasis for example, the endothelium which lines all vascular structures generates a semi-permeable barrier that controls the exchange of fluids, ions, and solutes between the blood and tissue. During phases of tissue growth and wound repair, the vasculature undergoes angiogenesis, the development of new blood vessels, to provide adequate oxygen and nutrients to the new and healing tissues. In pathological situations such as cancer, blood vessels have been demonstrated to support tumor growth and provide access to the circulatory system for metastatic progression. This dissertation focuses on elucidating new mechanisms that are involved in regulating these three dynamic functions of the vasculature. In Chapter 2, we discuss preliminary work connecting the Notch signaling pathway with the ability for endothelial cells to mechanically couple to their substrate, a property that is known to regulate endothelial barrier function. Using traditional methods in two-dimensional traction force microscopy, we observed reductions in traction stresses generated by endothelial monolayers treated with a Notch inhibitor. This was accompanied by a decrease in cell- matrix tethering through focal adhesions. In Chapter 3, we utilized an engineered model of angiogenesis to probe the role of endothelial cell contractility in the formation of new vascular sprouts. Through these studies, we established an essential role of non-muscle myosin II in maintaining multicellularity during sprout morphogenesis. And in Chapter 4, we described the adaptation of a cranial window model for studying melanoma brain metastases and demonstrated the utility of this system to monitor dynamic interactions between cancer cells and the brain vasculature. Together, the work in this dissertation provides new insights into and techniques for probing outstanding questions regarding various key functions of the vasculature. / 2021-02-28T00:00:00Z

Biomedical engineering

A versatile low-cost microcontroller-based 4-channel potentiostat platform for electrochemical biosensor development

Addokhi, Abdurrahman

04 June 2019

Electrochemical biosensors provide high specificity of analyte detection in different body fluids. A potentiostat is the instrument used to control the applied potential and measure current flow in the electrochemical cell, where the analyte detection reaction occurs. Advances in electronics and microcontrollers have enabled such sophisticated instruments to be built at a very low cost with sufficient performance. We report the analysis, design, and prototyping of a low-cost 4-channel potentiostat that is fully integrated into one PCB connected to an Arduino Uno board, as an Arduino shield, which could be used for both biosensor development and applications. As an Arduino-based instrument, the MATLAB-based software of the potentiostat is relatively easily modified for different biosensor requirements, providing great versatility for end users. We believe that this design will be valuable for electrochemical biosensors researchers as well as students interested in electrochemistry. The reported low-cost architecture could also be adopted to create low-cost diagnostic instruments for resource-limited settings.

Biomedical engineering

Fluorescent pH Microsensors as Indicators for Extracellular pH

Unknown Date

Using the Layer by Layer (LbL) technique combined with microcontact printing, novel pH sensors were developed in order to detect the extracellular pH (pHe) of the cancerous cell lines K562 and HeLa. Key to this process was the utilization of fluorescence microscopy which allowed for direct measurement of the fluorescence intensity observed from the pH sensors made possible by the integration of fluorescent molecules into the polymer layers, namely Fluorescein Isothiocyanate and Rhodamine Isothiocyanate. In this work eight pH sensor types were analyzed and statistically validated. By subjecting the pH sensors to the pH buffers, pH 5, pH 6, pH 7, and pH 8 a standard curve was also able to be developed. Results found that both Nine Layer pH Sensor formulations, with FITC as the pH sensitive fluorophore, showed significant differences between pH value sets, such as between pH 6 and pH 7 and between pH 7 and pH 8, at **p<0.01 using T-Test analysis. These Nine Layer pH Sensors were then deemed suitable for cell seeding analysis since cells are known to exhibit extracellular pH’s between the ranges of pH 6 and pH 8. Cell seeding analysis of pH sensors revealed that no significant difference occurred with either cell type used, K562 or HeLa. In this analysis, cells were cultured over top of the pH sensor and allowed to bind ~2 nm away from the pH sensing fluorescent layer. It was hoped that the proximity of the layer to the cell would allow for a comparison between cell bound fluorescent striped regions and non-cell bound fluorescent striped regions. It was theorized that these cell bound regions would exhibit dimmed fluorescent stripes directly underneath the cells as the non-cell bound regions would exhibit greater fluorescence intensity comparatively. These two cancer cell lines are known to exhibit slightly acidic extracellular pH’s in the range of pH 6.7 to pH 6.8 while being cultured in media with known pH values of pH 7.4 or greater. This difference in pH values would then theoretically result in fluorescence intensity differences on the fluorescent stripes. In analyzing the pH sensors, it was seen that they did not possess the sensitivity needed to detect pHe, as they simply were only able to detect the pH of the bulk fluid and not pH directly surrounding the cells. Any visible fluorescence intensity change resulted from cell autofluorescence. Future work would then center around reducing interference from cell autofluorescence as well as determining the cause for the lack of sensitivity. It seems that manipulation of the polymer layers would possibly allow for greater diffusion of cell metabolites through the polymer matrix thus resulting in greater access to the fluorophore. It also seems that FITC may not be an adequate fluorophore and more sensitive molecule may need to be selected. Key words: Layer by Layer, microcontact printing, extracellular pH (pHe), K562, HeLa, Fluorescein Isothiocyanate, Rhodamine Isothiocyanate, fluorophore, T-Test. / A Thesis submitted to the Department of Chemical and Biomedical Engineering in partial fulfillment of the requirements for the degree of Master of Science. / Summer Semester 2017. / May 22, 2017. / extracellular pH (pHe), Layer by Layer, microcontact printing / Includes bibliographical references. / Jingjiao Guan, Professor Directing Thesis; Bruce Locke, Committee Member; Ravindran Chella, Committee Member.

Biomedical engineering

MakerFluidics: low cost microfluidics for synthetic biology

Silva, Ryan Jay

02 November 2017

Recent advancements in multilayer, multicellular, genetic logic circuits often rely on manual intervention throughout the computation cycle and orthogonal signals for each chemical “wire”. These constraints can prevent genetic circuits from scaling. Microfluidic devices can be used to mitigate these constraints. However, continuous-flow microfluidics are largely designed through artisanal processes involving hand-drawing features and accomplishing design rule checks visually: processes that are also inextensible. Additionally, continuous-flow microfluidic routing is only a consideration during chip design and, once built, the routing structure becomes “frozen in silicon,” or for many microfluidic chips “frozen in polydimethylsiloxane (PDMS)”; any changes to fluid routing often require an entirely new device and control infrastructure. The cost of fabricating and controlling a new device is high in terms of time and money; attempts to reduce one cost measure are, generally, paid through increases in the other. This work has three main thrusts: to create a microfluidic fabrication framework, called MakerFluidics, that lowers the barrier to entry for designing and fabricating microfluidics in a manner amenable to automation; to prove this methodology can design, fabricate, and control complex and novel microfluidic devices; and to demonstrate the methodology can be used to solve biologically-relevant problems. Utilizing accessible technologies, rapid prototyping, and scalable design practices, the MakerFluidics framework has demonstrated its ability to design, fabricate and control novel, complex and scalable microfludic devices. This was proven through the development of a reconfigurable, continuous-flow routing fabric driven by a modular, scalable primitive called a transposer. In addition to creating complex microfluidic networks, MakerFluidics was deployed in support of cutting-edge, application-focused research at the Charles Stark Draper Laboratory. Informed by a design of experiments approach using the parametric rapid prototyping capabilities made possible by MakerFluidics, a plastic blood--bacteria separation device was optimized, demonstrating that the new device geometry can separate bacteria from blood while operating at 275% greater flow rate as well as reduce the power requirement by 82% for equivalent separation performance when compared to the state of the art. Ultimately, MakerFluidics demonstrated the ability to design, fabricate, and control complex and practical microfluidic devices while lowering the barrier to entry to continuous-flow microfluidics, thus democratizing cutting edge technology beyond a handful of well-resourced and specialized labs.

Biomedical engineering

Small volume drug release testing using ultrasonic agitation: development, characterization, and applications

Acevedo, Andrew James

28 February 2019

The first standardized methods for in vitro drug release testing of solid dosage forms were first introduced in the 1960s. Drug release testing has since become an important analytical measure along all stages of the drug development process. Despite the expanded role of dissolution testing and innovations in the types of dosage forms reaching the market, the fundamental methods and approaches to dissolution testing have not changed from their original introduction. This lack of innovation and one-size-fits-all approach to drug release testing has led to inefficiencies in testing and limited the scope of applications where this type of information could have an impact. In order to meet this need, we have designed, characterized, and implemented a small volume drug release test using ultrasonic agitation to screen for differences in dosage form composition. Our approach aims to supplement official methods for use during multiple stages of the drug development process. The hydro-acoustic environment in the system was characterized as a function of input power and position of the acoustic source. Drug release behavior from tablets was also studied over these system parameters, and a preliminary mechanistic explanation is made linking the two. The interplay between fragmentation and diffusion on solid dissolution processes was then explored through a deterministic partial differential equation model. This model provides the first instance of time-evolving particle size distributions in a dissolution model. In the final sections of this dissertation, uses of the ultrasonic agitation mediated drug screening method are demonstrated at two different parts of the drug development process – during early formulation development for the study of composite microparticle matrix structure on drug release behavior and post market surveillance for the screening of substandard tablets. / 2020-02-28T00:00:00Z

Biomedical engineering

Clinical feasibility of diffuse optical spectroscopic imaging in sarcoma

Peterson, Hannah Marie

04 June 2019

Sarcomas are broadly defined as cancers that form in the bone, soft tissue, or connective tissue. While they represent only 1% of all cancers in the United States, sarcomas constitute 12% of all childhood cancers. Five-year survival has not changed in over 40 years. The only clinically accepted indicator of pathologic response and disease-free survival is percent tumor-cell necrosis at time of surgery---there are no established prognostic markers before surgery. Unfortunately, 40--70% of patients have a poor pathologic response and attempts to modify treatment to improve their outcomes have been unsuccessful. Diffuse Optical Spectroscopic Imaging (DOSI) is a non-invasive, functional imagining technique that has been previously implemented to predict pathologic response in patients with breast cancer. Specifically, DOSI combines frequency amplitude modulated near-infrared light and broadband continuous wave light to measure quantitative concentrations of oxyhemoglobin, deoxyhemoglobin, water, and lipids. This project developed and validated DOSI as a new non-invasive measurement modality to track treatment for sarcomas. For the first time, the optical properties and functional hemodynamic information of the distal femur, tibia, and humerus were characterized in normal volunteers. DOSI demonstrated the ability to measure optical properties and functional information at several sarcoma locations throughout the course of treatment. It was able to differentiate between healthy and sarcoma tissues within a patient. Improvements made to the instrumentation will facilitate future measurements in this patient population. In the future, DOSI may provide a way to monitor treatment response and improve patient outcomes. / 2019-12-04T00:00:00Z

Biomedical engineering

Induced pluripotent stem cell reporter systems for smooth muscle cell sheet engineering

Kwong, George

03 July 2018

Smooth muscle cells exist in many different locations within the body, including blood vessels and airways, where their principal function is contraction and relaxation. The heterogeneity of smooth muscle cells has been related to their embryological origins and could have implications in many diseases, including atherosclerosis, pulmonary hypertension, and asthma. Many of these diseases require an expandable cell source of smooth muscle cells for regenerative medicine or disease modeling. Here, we have developed Acta2hrGFP and ACTA2eGFP (GFP reporters for smooth muscle α-actin) reporter mouse and human induced pluripotent stem cells lines to track and isolate populations of smooth muscle-like cells. iPSCs were patterned to a KDR-expressing (kinase insert domain receptor) mesodermal progenitor, which was further specified towards a smooth muscle-like lineage through exposure to platelet derived growth factor (PDGF-BB) and transforming growth factor (TGF-β). The Acta2hrGFP+ or ACTA2eGFP+ cells were enriched for characteristic markers of smooth muscle cells, and these cells expressed low levels of contractile markers, reminiscent of an immature or synthetic smooth muscle cell. Aligned smooth muscle-like cell sheets were generated using these iPSC-derived populations in an enzymatically degradable hydrogel system. The cell sheets displayed mechanical behavior similar to native blood vessels, with the Acta2hrGFP+ cell sheets displaying a higher ultimate tensile strength than Acta2hrGFP- cell sheets. Furthermore, we performed global transcriptomic profiling of primary adult mouse lung vascular (Acta2hrGFP+ Cspg4DsRed+) and airway (Acta2hrGFP+ Cspg4DsRed-) smooth muscle cells from a double transgenic reporter mouse, where we identified distinct gene signatures of lung vascular SMCs and airway SMCs, with Hhip and Acta2 co-expression distinguishing airway SMCs from lung vascular SMCs. When comparing our miPSC-derived Acta2hrGFP+ cells to these primary SMC signatures, the in vitro derived cells cluster closer to aortic SMCs and lung vascular SMCs, but their transcriptomic signatures still remain significantly distinct. In addition, we have generated an Acta2hrGFP Cspg4DsRed reporter mouse iPSC line, which can be used to understand the signaling pathways involved in specification of these different smooth muscle cell subtypes. Thus, we have developed systems for isolating smooth muscle-like populations which have potential in tissue engineering applications, and we have identified gene signatures of adult lung vascular and airway smooth muscle cells to begin to address the heterogeneity of smooth muscle cell lineages.

Biomedical engineering

In Situ Polymerizing Collagen for the Development of 3D Printed Tissue Engineering Scaffolds

Glover, Christopher John

08 March 2019

<p> Natural materials have been processed and utilized as scaffold materials in the field of tissue engineering for many years. One natural material often utilized is collagen since it is the main structural protein in mammalian tissues and exhibits microstructures suitable for the survival and proliferation of many different cell lineages. However, a common challenge with fibrillized collagen is the difficulty associated with trying to process it into specific three-dimensional designs for the development of scaffolds aimed at regenerating particular tissue types. This project consists of utilizing a custom platform capable of 3D printing <i>in situ</i> polymerizing collagen into user-defined morphologies for the development of 3D collagen-based scaffolds. Various anti-inflammatory compounds such as gold nanoparticles and curcumin were also incorporated into the scaffolds post printing in order to further tailor the cellular responses to the scaffolds. Scanning electron microscopy and neutron activation analysis were performed to verify and quantify the attachment of the gold nanoparticles, respectively. Differential scanning calorimetry was utilized to examine and optimize the stability of the scaffolds after crosslinking. Lastly, water soluble tetrazolium salt and reactive oxygen species assays were performed to assess the biocompatibility of the scaffolds using L929 murine fibroblasts. The results exhibited the viability of the platform to become an effective technique to manufacture and process custom scaffolds for tissue engineering applications.</p><p>

Biomedical engineering

Neural mechanisms underlying specific visual tasks during self-motion

Geng, Yansong

10 July 2017

Object movement detection during observers’ self-motion is critical in navigation. Given ample optical available variables, which of them would be used would help us reveal the strategies being employed. In this work, using functional magnetic resonance imaging (fMRI) methods, we investigated the neural substrate underlying specific visual motion related tasks, such as time to passage (TTP), depth parallax, and collision. Using a visual search paradigm implemented with MATLAB, we developed a psychophysical task to investigate how the target characteristics (initial depth, initial eccentricity, and independent velocity), spatial attention, and heading estimation would affect visual search, for better understanding the mechanisms involved in object movement detection during self-motion. The fMRI analysis shows that: 1. Bilateral precentral sulcus (PreCS), postcentral sulcus (PostCS) and bilateral hMT are strongly activated during the TTP task. 2. Cortical regions along the dorsal visual processing pathway, including bilateral hMT, superior parietal gyrus (SPG), PostCS, PreCS and superior frontal gyrus (SFG), play important roles in our depth perception test. 3. In the collision test, similar activation pattern has been found in normal controls and stroke patients with visual deficits, intraparietal sulcus (IPS), SPG, supplementary area (SMA) and premotor regions are highly activated. The psychophysical results in visual search tasks indicate targets located in central visual field and target placed closer to the observer are easier to detect, looming distractor demands attention, the detrimental effect increases with the increasing of the target eccentricity level, no preference has been found in visual search among different heading directions in this test. In summary, cortical regions along visual motion processing pathway are highly involved in object movement detection during self-motion, the observers will take flexible strategies when different optical cues are provided.

Biomedical engineering