자료유형 | 학위논문 |
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서명/저자사항 | Strategies to Model and Develop Therapeutics for Ventilator Induced Lung Injury. |
개인저자 | Bobba, Christopher M. |
단체저자명 | The Ohio State University. Biomedical Engineering. |
발행사항 | [S.l.]: The Ohio State University., 2019. |
발행사항 | Ann Arbor: ProQuest Dissertations & Theses, 2019. |
형태사항 | 176 p. |
기본자료 저록 | Dissertations Abstracts International 81-06B. Dissertation Abstract International |
ISBN | 9781687970510 |
학위논문주기 | Thesis (Ph.D.)--The Ohio State University, 2019. |
일반주기 |
Source: Dissertations Abstracts International, Volume: 81-06, Section: B.
Advisor: Ghadiali, Samir |
이용제한사항 | This item must not be sold to any third party vendors. |
요약 | Insults to the lung, such as pneumonia, sepsis, aspiration, or trauma, can reduce respiratory function through the acute respiratory distress syndrome (ARDS). These patients require mechanical ventilation (MV) to maintain adequate gas exchange. However, MV exposes the lung to a variety of injurious mechanical forces. This phenomenon is called ventilator induced lung injury (VILI). Minimizing injury during MV in patients with ARDS is a primary goal of critical care medicine. Successful clinical trials have focused on the physical aspects of MV application, such as reducing tidal volume and improving V/Q matching. Thorough understanding of pulmonary mechanics and how they differ during MV is critical for improving lung function during ventilation.In addition to altered whole lung mechanics, these high mechanical forces present during VILI can trigger cell death and activate mechanotransduction mechanisms within lung cells. Typical in vitro models include applying force to epithelial and/or endothelial cells. Most studies neglect the role of the resident immune cell within the lung, the alveolar macrophage. Studying the effect of mechanical force on alveolar macrophages may reveal mechanotransduction pathways amenable to targeted therapy.Refinements to in vitro modeling techniques will also enhance the translatability of bench findings. Current models are only capable of applying one type of mechanical force, often to cells submerged in culture. The alveolar-capillary barrier is an intricate structure, with a thin air-liquid barrier composed of an endothelial and epithelial cell. Another cell, the alveolar macrophage, resides on top of epithelial cells on the air side of the barrier. During VILI this barrier can experience stretching, compression, or air-liquid interface shear. Developing an in vitro model capable of applying each of these forces together or independently, in the presence of all relevant cell types, would advance the in vitro study of VILI. In this dissertation, we studied the injurious effect of MV using multiscale models of VILI, spanning in vitro, in vivo and ex vivo techniques.Ex vivo lung perfusion (EVLP) is a clinical technique to improve lung function prior to lung transplant. There is a paucity of information regarding optimal ventilatory strategies to minimize VILI during EVLP. We investigated the role of altered pressure-flow waveforms present during positive and negative pressure ventilation using a rat model of EVLP. When applying identical tidal volume, positive end expiratory pressure and respiratory rate, lungs undergoing negative pressure ventilation demonstrated more favorable lung mechanics and reduced cytokine secretion, however, these changes were also dependent on respiratory flow waveforms, which could be driving injury. Our findings indicate that the pressure-flow waveforms present during ventilation, regardless of ventilatory mode (i.e. positive or negative pressure ventilation) may be the driver of VILI during EVLP.We also explored the role of the alveolar macrophage in perpetuating VILI. Using an in vitro model, we showed that primary human alveolar macrophages respond in a pro-inflammatory manner to the application of oscillatory compressive stress. We identified miR-146a as a mechanosensitive miRNA upregulated in response to mechanical force. In a critically ill patient cohort, miR-146a was also increased in the BAL of patients undergoing mechanical ventilation. Previous studies suggest that this microRNA downregulates inflammation, therefore its upregulation during ventilation may be initiation of a negative feedback loop or an insufficient compensatory response to injurious mechanical forces. When miR-146a is overexpressed prior to force application in vitro, alveolar macrophages lose their force induced increase in pro-inflammatory cytokine secretion. We then turned to in vivo models of VILI to further define the role of the alveolar macrophage and miR-146a in mediating injury during MV. Mice lacking alveolar macrophages demonstrate reduced lung injury from ventilation, suggesting that AMs contribute to injury during MV, and mice lacking miR-146a experience greater injury from MV, presumably due to loss of an important negative feedback loop. Nanoparticle mediated delivery of pre-miR-146a in vivo mitigated lung injury and inflammation during mechanical ventilation. Altogether these data support the hypothesis that AMs play an important role in VILI and that miR-146a delivery may be a viable therapeutic approach to treating VILI.Lastly, we developed devices to 1) better model VILI in vitro, and 2) measure surfactant activity following VILI. The ventilator-on-a-chip is device capable of applying oscillatory mechanical stretch or pressure at an air-liquid interface. A thin electrospun membrane serves as the basement membrane upon which epithelial cells (on the air-side) and endothelial cells can be cultured to model an alveolar-capillary barrier. Transmembrane impedance measurements can be taken during culture to monitor changes to barrier integrity during cell monolayer growth and during dysfunction due to mechanical force. Separately, a constrained drop surfactometer was developed capable of measuring air-liquid surface tension for samples retrieved from lungs following VILI. This device may be able to detect surfactant dysfunction following VILI.The findings from this dissertation will impact the field of VILI in several ways. Identification of a targetable mechanotransduction mechanism in alveolar macrophages opens up an avenue for potential therapy. Development of devices to model the alveolar-capillary barrier and study surfactant dysfunction will help identify future mechanisms of barrier dysfunction from MV and ARDS. |
일반주제명 | Biomedical engineering. Physiology. Public health. Health sciences. |
언어 | 영어 |
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