Vibration of branched circular cylindrical shells as applied to airway walls a thesis submitted to Auckland University of Technology in fulfilment of the requirement for the degree of Doctor of Philosophy, March 2005.

Au, Pui Ming.

January 2005

Thesis (PhD) -- Auckland University of Technology, 2005. / Also held in print (180 leaves, ill., 30 cm.) in Akoranga Theses Collection (T 611.2 AU)

Vibration. Airway (Medicine). Asthma.

A pathophysiologic study of airway inflammation in bronchiectasis /

Ip, Sau-man, Mary.

January 1991

Thesis (M.D.)--University of Hong Kong, 1992. / Includes bibliographical references (leaves 186-206).

Airway (Medicine) Bronchiectasis.

A pathophysiologic study of airway inflammation in bronchiectasis

Ip, Sau-man, Mary.

January 1991

Thesis (M.D.)--University of Hong Kong, 1992. / Includes bibliographical references (leaves 186-206) Also available in print.

Airway (Medicine) Bronchiectasis.

Regulation of anion secretion in human airway epithelial cells /

Wang, Dong.

January 2009

Includes bibliographical references (p. 85-103).

Airway pressure release ventilation : a systematic experimental approach /

Neumann, Peter,

January 2000

Thesis (D.M.S.)--Uppsala University, 2000. / "Acta Universitatis Upsaliensis." Extra abstract sheet inserted. Includes bibliographical references (p. 50-57).

The control of respiration and upper airway muscle activity in healthy young men and women /

Jordan, Amy Selina.

January 2002

Thesis (Ph.D.)--University of Adelaide, Dept. of Physiology, 2002. / "May 2002." Bibliography: leaves 123-144.

Airway Basal Cells in Development, Injury-Repair, and Homeostasis

Yang, Ying

January 2019

Basal cells (BCs) are multipotent tissue-specific stem cells of a variety of organs including the skin, digestive and respiratory tract. BCs are broadly identified by expression of Krt5, Krt14 and the transcription factor p63. In the adult airways, BCs are not only important for normal maintenance but also crucial for epithelial repair after injury. However, the embryonic origin of these adult stem cells remains elusive. Previous reports showed that p63+ cells appear early during airway development, but these do not express markers of adult BCs, raising the question whether these cells represent BC precursors. Moreover, little was known whether embryonic BCs have an impact in the adult pool of progenitors that mediate responses of the lung to injury or pulmonary diseases. The goal of this thesis is to address these gaps of knowledge using a variety of technologies, including functional and lineage tracing analysis in vivo in mouse genetic models, injury modeling, high-throughput profiling and gene regulation approaches. This thesis is to comprehensively characterize airway BCs in development, injury-repair, and homeostasis. These studies revealed a previously unrecognized broader role of embryonic p63+ cells in the establishment of the stem cell pools of the lung pre and postnatally. Surprisingly, lineage analysis showed that early in development these cells were able to generate all epithelial cell types of the airways and alveolar compartment. However, as development proceeds, they underwent two sequential lineage segregation events to finally generate two regionally distinct adult stem cell pools. One of these became the well-known BCs that populate extrapulmonary airways through an undescribed maturation process from the perinatal stage to adulthood, and the other was identified as a rare stem cell pool in the pseudostratified epithelium of intrapulmonary airways which maintained immature and quiescent throughout lifetime. Moreover, the latter responded uniquely to lung injury induced by H1N1 viral infection. Recent studies have demonstrated that BC-like p63+ Krt5+ cell clusters (“Krt5+ pods”) are ectopically present in the areas of severe alveolar injury by H1N1 viral infection. The presence of these pods has been associated with pathological scars in several human pulmonary diseases including idiopathic pulmonary fibrosis (IPF) and acute respiratory distress syndrome (ARDS). However, their cellular origin has been intensely debated. This thesis showed that this rare progenitor pool is established during embryonic development when airways are still branching. Further characterization demonstrated a p63 gene dosage dependency in the specification/maintenance of this rare progenitor pool. By utilizing multiple lineage-tracing lines, an underappreciated diversity of this pool was revealed by showing a novel subpopulation carrying secretory lineage marker spatially restricted to intrapulmonary airways. Further molecular characterization and genetic manipulation of this rare progenitor pool may provide valuable cues to understand the pathogenesis about pulmonary disorders and to develop effective therapies. Moreover, the molecular signatures of tracheal embryonic E18.5 preBCs and adult TrBCs were generated through high-throughput profiling, which provided hints about the genetic regulation of airway BC maturation process and generated potential molecular landmarks for the in vitro ES/iPS cell differentiation towards airway BCs. In addition, single cell RNA-sequencing analyses revealed heterogeneity of adult BCs in the tracheal and esophageal epithelia. Lastly, candidate master regulators of their differentiation programs in homeostatic and metaplastic states were identified through unbiased systems biology algorithms, which will be further validated in functional assays in the near future. Taken together, the studies in this thesis comprehensively characterized airway BCs in development, injury-repair and homeostasis. This thesis work showed the newly identified p63+ airway progenitors before E10.5 are multipotent for all lung epithelial lineages and this multipotency gets restricted to proximal fate at E10.5. In the adult injury-repair, this thesis work for the first time revealed that the H1N1-induced Krt5+ pods are generated by bronchial p63+ Krt5- progenitors, which originate from a subpopulation of E13.5 intrapulmonary p63+ progenitors. At homeostasis, this thesis work uncovered a previously underappreciated heterogeneity of BCs in both airways and esophagus, and provided molecular foundations for further explorations into the mechanistic perspectives of BC cellular identity maintenance.

Airway (Medicine)

Stem cells

Homeostasis

Regulation of airway narrowing by dynamic and static mechanical loads

Noble, Peter Beresford

January 2006

[Truncated abstract] The extent to which an airway narrows is strongly influenced by mechanical loads on airway smooth muscle (ASM). This thesis considers both dynamic and static mechanical loads. Dynamic load describes the time varying load on airways produced by oscillatory breathing movements. Static load is that present at a fixed lung volume ie. without breathing. In the intact lung static load principally comprises the pressure across the airway wall, that is transmural pressure (Ptm), and elastic after-load arising from distortion of airway and lung tissue by the narrowing airway. The experiments performed in this thesis were designed to answer several outstanding questions relating to how dynamic and static loads regulate airway narrowing. Dynamic load from breathing movements cyclically stretches ASM, which produces a number of physiological and cellular effects. For example in ASM strips a period of cyclical stretch reduces subsequent ASM contraction. However the response of the whole airway to dynamic load may differ from isolated ASM where non-muscle tissue also contributes. The first aim of this thesis was to characterise the response of the whole airway to dynamic load and determine whether the airway wall modifies the effects produced by ASM length cycling. Static after-loads restrict ASM shortening providing a limit to airway narrowing. Two primary sources of airway wall load include cartilage and the mucosal membrane which contribute to airway compliance. The relative importance of cartilage and mucosa to airway wall compliance and airway narrowing is unclear. ... Results demonstrate that airway narrowing is restricted by Ptm but not by parenchymal elastic after-load. The major findings of this thesis are: (1) dynamic loads produced by breathing movements regulate airway responsiveness through cyclical airway expansion and elongation; (2) the reported effects of cyclical stretch on ASM contraction differs in situ 8 possibly due to modification by one or more biomechanical or physiological properties of the airway wall; (3) parenchymal elastic after-loads, previously thought to be important during bronchoconstriction, do not restrict airway narrowing. Given the absence of an effect of parenchymal elastic after-load on airway narrowing, the static mechanical load on ASM therefore comprises Ptm and airway wall stiffness, with important contributions from cartilage and mucosa depending on lung volume.

Airway (Medicine) -- Physiology

Airway (Medicine) -- Muscles

Airway narrowing

Mechanical load

Asthma

Novel genes associated with airway smooth muscle proliferation in asthma

Lau, Justine Y.

January 2008

Thesis (Ph. D.)--University of Sydney, 2009. / Title from title screen (viewed Aug. 11, 2009) Submitted in fulfilment of the requirements for the degree of Doctor of Philosophy to the Discipline of Pharmacology, Faculty of Medicine. Degree awarded 2009; thesis submitted 2008. Includes bibliographical references. Also available in print form.

EFFECTS OF AIRWAY SUCTION ON FUNCTIONAL RESIDUAL CAPACITY AND ARTERIAL OXYGEN TENSION IN NORMAL DOGS.

Muenchau, Theresa Ann.

January 1983

No description available.

Airway (Medicine)

Respiration -- Regulation.

Pulmonary function tests.