Nanoengineered Hydrogel Scaffolds for Enhanced Maturation and Functionality of hiPSC-derived Cardiac Tissues

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Description
Cardiovascular diseases (CVDs), including myocardial infarction (MI), are the major cause of death globally. Considerable research has been devoted in recent years to developing in vitro cardiac tissue models utilizing human induced pluripotent stem cells (hiPSCs) for regenerative medicine, disease

Cardiovascular diseases (CVDs), including myocardial infarction (MI), are the major cause of death globally. Considerable research has been devoted in recent years to developing in vitro cardiac tissue models utilizing human induced pluripotent stem cells (hiPSCs) for regenerative medicine, disease modeling, and drug discovery applications. Notably, electroconductive hydrogel scaffolds have shown great promise in the development of functional hiPSC-derived cardiac tissues for both in vitro and in vivo cardiac research. However, the underlying mechanism(s) by which these nanoparticles contribute to the function and fate of stem cell-derived cardiac tissues have not been fully investigated. To address these knowledge gaps, this Ph.D. dissertation focuses on the mechanistic analysis of the impact of nanoengineered electroconductive hydrogel scaffolds on 2D and 3D hiPSC-derived cardiac tissues. Specifically, within the first phase of the project, hydrogel scaffolds were nanoengineered using either electroconductive or non-conductive nanoparticles to dissect the role of electroconductivity features of gold nanorods (GNRs) in the functionality of isogenic 2D hiPSC-derived cardiac patches. Extensive biological and electrophysiological assessments revealed that, while biophysical cues from the presence of nanoparticles could potentially play a role in cardiac tissue development, electroconductivity cues played a major role in enhancing the functional maturation of hiPSC-derived cardiac tissues in 2D cell-seeded cardiac patches. This dissertation further describes the application of GNRs in developing a biomimetic 3D electroconductive Heart-on-a-chip (eHOC) model. The 3D eHOC model was then leveraged to comprehensively investigate the cellular and molecular responses of isogenic human cardiac tissues to the electroconductive microenvironment through single-cell RNA sequencing (scRNAseq), an aspect not addressed in previous studies. The enhanced functional maturation of the 3D eHOC was demonstrated through extensive tissue-level and molecular-level assays. It was revealed that the GNR-based electroconductive microenvironment contributes to cardiac tissue development through the enrichment of calcium handling and cardiac contractile pathways.Overall, these findings offer additional insights into the role of electroconductive hydrogel scaffolds in regulating the functionalities of hiPSC-derived cardiac tissues. Furthermore, the proposed 3D eHOC platform could also serve as a more physiologically representative model of the in vivo microenvironment for in vitro applications, such as drug testing and disease modeling studies.
Date Created
2024
Agent

Optical Imaging-Based Digital Nanobiosensor for Point-of-Care Cardiac Biomarker Testing

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Description
Cardiovascular diseases are the number one cause of death worldwide. Cardiac biomarkers can provide objective and quantitative information to facilitate early diagnosis and guide treatment of cardiovascular diseases. Even though a variety of methods have been developed for cardiac biomarker

Cardiovascular diseases are the number one cause of death worldwide. Cardiac biomarkers can provide objective and quantitative information to facilitate early diagnosis and guide treatment of cardiovascular diseases. Even though a variety of methods have been developed for cardiac biomarker detection, a point-of-care testing (POCT) for cardiac biomarkers with high sensitivity, specificity and precision is still missing. To fulfil this unmet need, novel digital biosensing methods based on optical imaging and nanomaterials are developed in this dissertation for high-sensitivity POCT of cardiac biomarkers.First, a high-sensitivity and POC-compatible optical imaging-based digital immunoassay is developed for rapid detection of low-abundance biomarkers. This technology was established on a model analyte IL-6 and can be adapted to various other protein targets. The digital immunoassay was also utilized as the reference method for evaluating the digital nanobiosensors developed afterwards. Second, a microfluidic digital nanobiosensor (MDNB) is developed for POC-compatible detection of heart failure biomarker NT-proBNP from 7 µL of whole blood. Using the MDNB, detection in a clinically relevant concentration range was achieved with a 10-minute assay time. With a high potential utility in outpatient and possibly even home settings, the MDNB could become a POC device for decentralized detection of NT-proBNP to assist heart failure patient management. Lastly, the development of a digital immunogold-linked apta-sorbent assay (DILASA) for rapid high-sensitivity detection of heart attack biomarker cardiac troponin is introduced. Reliable detection of 10 ng/L cTnT in human plasma was achieved with a 15-minute assay time using DILASA. It is expected that with further optimization and development, DILASA will be a promising candidate approach for realizing a high-sensitivity POCT of cTnT.
Date Created
2024
Agent

The Impact of FOXM1 Knockout on FGF1 and CHIR99021-Induced Cell Proliferation in Human Pluripotent Stem Cell-Derived Cardiomyocytes

Description
As the need for whole heart transplantation to treat heart failure grows faster than the supply, alternative methods are in increasing demand. Transplantation of cardiomyocytes to replace injured myocardium after MI has shown promise. Myocardium is notoriously ineffective at proliferating after switching from

As the need for whole heart transplantation to treat heart failure grows faster than the supply, alternative methods are in increasing demand. Transplantation of cardiomyocytes to replace injured myocardium after MI has shown promise. Myocardium is notoriously ineffective at proliferating after switching from hyperplastic to hypertrophic growth. FOXM1 has been established as having a strong role in cell cycle regulation in cancerous tumors and cardiomyocytes, and these experiments show the relationship between FOXM1 and iPSC-derived cardiomyocyte proliferation and attempt to improve a treatment option for heart failure through manipulation of this gene. Our experiment concludes that FOXM1 knockdown increases iPSC-CM cell proliferation, and can be further explored to better increase cardiomyocyte proliferation.
Date Created
2024-05
Agent

The Impact of FOXM1 Knockout on FGF1 and CHIR99021-Induced Cell Proliferation in Human Pluripotent Stem Cell-Derived Cardiomyocytes

Description
As the need for whole heart transplantation to treat heart failure grows faster than the supply, alternative methods are in increasing demand. Transplantation of cardiomyocytes to replace injured myocardium after MI has shown promise. Myocardium is notoriously ineffective at proliferating after switching from

As the need for whole heart transplantation to treat heart failure grows faster than the supply, alternative methods are in increasing demand. Transplantation of cardiomyocytes to replace injured myocardium after MI has shown promise. Myocardium is notoriously ineffective at proliferating after switching from hyperplastic to hypertrophic growth. FOXM1 has been established as having a strong role in cell cycle regulation in cancerous tumors and cardiomyocytes, and these experiments show the relationship between FOXM1 and iPSC-derived cardiomyocyte proliferation and attempt to improve a treatment option for heart failure through manipulation of this gene. Our experiment concludes that FOXM1 knockout increases iPSC-CM cell proliferation, and can be further explored to better increase cardiomyocyte proliferation.
Date Created
2024-05
Agent

Optimizing Hydrogel Matrix for Cell Transplantation: A Synergistic Approach Using Nanoprobe Siloxane and 3D Printed Spiral Molds

Description
In this comprehensive research, we have pursued a dual investigation within the scope of tissue engineering: firstly, to investigate the retention of nanoprobe siloxane emulsions in bio-compatible hydrogel matrices in order to be able to measure oxygen saturation within the

In this comprehensive research, we have pursued a dual investigation within the scope of tissue engineering: firstly, to investigate the retention of nanoprobe siloxane emulsions in bio-compatible hydrogel matrices in order to be able to measure oxygen saturation within the hydrogel; secondly, to refine the design of 3D printed hydrogel molds to enhance structural integrity of hydrogels for cell encapsulation. We evaluated the retention capabilities of these nanoemulsions, tagged with fluorescent dyes, across varying concentrations, and further advanced the mold design to prevent hydrogel unraveling and ensure complete filling. The findings suggest pivotal implications for the application of these hydrogels in cell transplantation and set a methodological precedent for future empirical studies.
Date Created
2024-05
Agent

Development of a Hydrogel Macroencapsulation Device for Improved Long-Term Islet Survival Using Injection Molding and Oxygen Modeling-Aided Design

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Description
Allogeneic islet transplantation has the potential to reverse Type 1 Diabetes in patients. However, limitations such as chronic immunosuppression, islet donor numbers, and islet survival post-transplantation prevent the widespread application of allogeneic islet transplantation as the treatment of choice. Macroencapsulation

Allogeneic islet transplantation has the potential to reverse Type 1 Diabetes in patients. However, limitations such as chronic immunosuppression, islet donor numbers, and islet survival post-transplantation prevent the widespread application of allogeneic islet transplantation as the treatment of choice. Macroencapsulation devices have been widely used in allogeneic islet transplantation due to their capability to shield transplanted cells from the immune system as well as provide a supportive environment for cell viability, but macroencapsulation devices face oxygen transport challenges as their geometry increases from preclinical to clinical scales. The goal of this work is to generate complex 3D hydrogel macroencapsulation devices with sufficient oxygen transport to support encapsulated cell survival and generate these devices in a way that is accessible in the clinic as well as scaled manufacturing. A 3D-printed injection mold has been developed to generate hydrogel-based cell encapsulation devices with spiral geometries. The spiral geometry of the macroencapsulation device facilitates greater oxygen transport throughout the whole device resulting in improved islet function in vivo in a syngeneic rat model. A computational model of the oxygen concentration within macroencapsulation devices, validated by in vitro analysis, predicts that cells and islets maintain a greater viability and function in the spiral macroencapsulation device. To further validate the computational model, pO2 Reporter Composite Hydrogels (PORCH) are engineered to enable spatiotemporal measurement of oxygen tension within macroencapsulation devices using the Proton Imaging of Siloxanes to map Tissue Oxygenation Levels (PISTOL) magnetic resonance imaging approach. Overall, a macroencapsulation device geometry designed via computational modeling of device oxygen gradients and validated with magnetic resonance (MR) oximetry imaging enhances islet function and survival for islet transplantation.
Date Created
2023
Agent

Investigating Immunomodulatory Properties of Trophoblasts on NK-92 Cells

Description

This study was conducted to determine how 3D cultured trophoblasts' secreted factors impact NK-92 activation and cytotoxicity during early pregnancy. In this study, 6 week gestational age human cytotrophoblast stem cells (iCTB) were cultured in 2D, 3D matrigel, and 3D

This study was conducted to determine how 3D cultured trophoblasts' secreted factors impact NK-92 activation and cytotoxicity during early pregnancy. In this study, 6 week gestational age human cytotrophoblast stem cells (iCTB) were cultured in 2D, 3D matrigel, and 3D synthetic hydrogels composed of 20 kDa 4-arm poly(ethylene glycol)-maleimide (PEG-Mal) modified with a GFOGR adhesive ligand (1 mM) and crosslinked with dithiothreitol (DTT), a non-degradable crosslinker. On day six, trophoblast supernatants were collected to investigate the influence of trophoblast organoid secreted factors on activated NK cell phenotype, measured by CD107a expression and levels of IFNγ secretion. Here we demonstrate that NK-92 cells possess a dNK2-like phenotype, and that supernatants of cytotrophoblasts cultured in 2D and synthetic hydrogels, but not matrigel, reduce activated NK-92 cytokine secretion.

Date Created
2023-05
Agent

Breast Implant Illness: An Understudied Disease

Description
Breast implant illness (BII) is a controversial disease that results in a cluster of various symptoms. As a result, patients frequently diagnose themselves based on what they learn from social media and online articles. Our thesis analyzes BII, including its frequency, common symptoms, potential causes, and treatment options.
Date Created
2022-12
Agent

Breast Implant Illness: An Understudied Disease

Description
Breast implant illness (BII) is a controversial disease that results in a cluster of various symptoms. As a result, patients frequently diagnose themselves based on what they learn from social media and online articles. Our thesis analyzes BII, including its frequency, common symptoms, potential causes, and treatment options.
Date Created
2022-12
Agent

Light-Activated Sealants for Internal Organ Repair and Healing

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Description

The current clinical gold standards for tissue sealing include sutures, staples, and glues, however several adverse effects limit their use. Sutures and staples inherently cause additional trauma to tissue surrounding the wound, and glues can be lacking in adhesion and

The current clinical gold standards for tissue sealing include sutures, staples, and glues, however several adverse effects limit their use. Sutures and staples inherently cause additional trauma to tissue surrounding the wound, and glues can be lacking in adhesion and are potentially inflammatory. All three also introduce risk of infection. Light-activated tissue sealing, particularly the use of near-infrared light, is an attractive alternative, as it localizes heat, thereby preventing thermal damage to the surrounding healthy tissue. Previous work identified a glutaraldehyde-crosslinked chitosan film as a lead sealant for gastrointestinal incision sealing, but in vivo testing resulted in tissue degradation in and around the wound. The suggested causes for this degradation were excess acetic acid, endotoxins in the chitosan, and thermal damage. A basic buffer wash protocol was developed to remove excess acid from the films following fabrication. UV-Vis spectroscopy demonstrated that following the wash, films had the same concentration of Indocyanine green as unwashed films, allowing them to absorb light at the same wavelength, therefore showing the wash did not affect the film’s function. However subsequent washes led to degradation of film mass of nearly 20%. Standard chitosan films had significantly greater mass gain (p = 0.028) and significantly less subsequent loss (p= 0.012) than endotoxin free chitosan-films after soaking in phosphate buffered saline for varying durations , while soaking duration had no effect (p = 0.332). Leak pressure testing of films prepared with varying numbers of buffer washes, laser temperature, and lasering time revealed no significant interaction between any of the 3 variables. As such, it was confirmed that proceeding with in vivo testing with the buffer wash, various lasering temperatures, and laser times would not affect the sealing performance of the films. Future investigation will involve characterization of additional materials that may be effective for sealing of internal wounds, as well as drug loading of agents that may hasten the healing process.

Date Created
2022-05
Agent