Studies of lung function

This thesis outlines the candidate's contribution to the study of Respiratory Physiology in two main areas 1. The effect of lung morphometry on lung function and 2. Reflex control of pattern of breathing.The work that makes up this thesis is laid out in largely chronological order describing the evolution of the investigations.The effect of bronchial tree structure on function was investigated using a number of new techniques developed by the author. These include a method of modelling the bronchial tree to previously unobtained detail in the form of a hollow cast. This enabled gas transit times to airways of 2-3 mm diameter to be measured and the contribution made by architecture, tissue compliance and the gradient of pleural pressure to the distribution of ventilation to be apportioned. This was the first time transit times to individual airways had been measured. Using these techniques the effect of bronchial tree structure on the phenomenon of separation of gas mixtures into their components during breathing, and the effect of the beating heart on the mixing of gases during breathing was quantified. The author's contributions to the investigation of neural control of breathing follow. A fortuitous observation that SO₂ blocks pulmonary stretch receptors (PSR) in rabbits, which took place while developing an animal model of bronchitis, lead to the observation of a non PSR mechanism determining inspiratory time (ti). Investigation of the action of rapidly adapting pulmonary receptors (RAR) using SO₂ confirmed their role in provoking sighs or augmented breaths and demonstrated that they terminated expiratory duration (tn) with a constant latency. A consistent effect of RARs on inspiration proved elusive until it was discovered that after provoking an augmented breath ft is refractory to the direct effects of RAR activity for about 2 minutes. This observation lead to the development of a theoretical model of control of ft via a central linking. This explained our observation of a non-PSR effect restricting ft after SO₂ block. Further investigations confirmed a role for RAR in control of breathing in conscious dogs. The action of RAR in initiating inspiration was demonstrated using PSR block. The same technique was used to elucidate the role played by PSR in shifts in functional residual capacity during changes in posture. An interesting observation made at this time is that although cough is primarily associated with RAR activity it can not be triggered from the lungs. The results of experiments demonstrating a similar role for RAR in conscious animals are presented.The influence of high frequency ventilation, on pulmonary receptors, the reflexes they produce and on the non-Newtonian properties of bronchial mucus is described.The way in which different species control their very different frequencies of breathing is included and the way pulmonary receptor activity is changed in some models of lung disease. The effects of modern anaesthetics on receptor activity and the effect of acupuncture as a respiratory stimulant are reported. The results of some investigations of human movement and tremor are presented. The candidates contributions to books and books published are described

NOVEL CORN HYBRIDS FOR SILAGE PRODUCTION

Four corn (Zea mays) hybrid types at three plant densities and two nitrogen rates were evaluated for forage yield, forage quality and ensilage quality. The four hybrid types over the first two year of the study included nutri-dense, waxy, leafy, and dualpurpose, the third year a second dual purpose hybrid was added; while the three target plant densities were 54 000, 68 000, and 81 000 plants per hectare; and the nitrogen rates were 134 and 224 kilograms per hectare. The dual-purpose hybrid consistently had high forage yields compared with the other types. When averaged over nitrogen rate and hybrid type, the two highest plant densities typically had higher yields. Across all hybrids nitrogen had no effect on forage yield when averaged across plant density. The leafy hybrid had a lower harvest index than other hybrid types indicating that leaves accounted for much of the harvested weight. Hybrids were examined both at harvest (green chop) and after ensiling for protein and digestibility. Higher nitrogen rates increased crude protein when averaged over all hybrids and plant densities. Dual purpose and waxy hybrid types typically had the lowest acid detergent fiber (ADF) and neutral detergent fiber (NDF) and the highest relative feed values (RFV); while the nutri-dense and leafy hybrids typically had the highest ADF and NDF values and lowest RFV

Effects of CO2-induced pH reduction on the exoskeleton structure and biophotonic properties of the shrimp Lysmata californica.

The anticipated effects of CO2-induced ocean acidification on marine calcifiers are generally negative, and include dissolution of calcified elements and reduced calcification rates. Such negative effects are not typical of crustaceans for which comparatively little ocean acidification research has been conducted. Crustaceans, however, depend on their calcified exoskeleton for many critical functions. Here, we conducted a short-term study on a common caridean shrimp, Lysmata californica, to determine the effect of CO2-driven reduction in seawater pH on exoskeleton growth, structure, and mineralization and animal cryptic coloration. Shrimp exposed to ambient (7.99 ± 0.04) and reduced pH (7.53 ± 0.06) for 21 days showed no differences in exoskeleton growth (percent increase in carapace length), but the calcium weight percent of their cuticle increased significantly in reduced pH conditions, resulting in a greater Ca:Mg ratio. Cuticle thickness did not change, indicating an increase in the mineral to matrix ratio, which may have mechanical consequences for exoskeleton function. Furthermore, there was a 5-fold decrease in animal transparency, but no change in overall shrimp coloration (red). These results suggest that even short-term exposure to CO2-induced pH reduction can significantly affect exoskeleton mineralization and shrimp biophotonics, with potential impacts on crypsis, physical defense, and predator avoidance

Modern seawater acidification: The response of foraminifera to high-CO<inf>2</inf> conditions in the Mediterranean Sea

The seas around the island of Ischia (Italy) have a lowered pH as a result of volcanic gas vents that emit carbon dioxide from the sea floor at ambient seawater temperatures. These areas of acidified seawater provide natural laboratories in which to study the long-term biological response to rising CO2 levels. Benthic foraminifera (single-celled protists) are particularly interesting as they have short life histories, are environmentally sensitive and have an excellent fossil record. Here, we examine changes in foraminiferal assemblages along pH gradients at CO2 vents on the coast of Ischia and show that the foraminiferal distribution, diversity and nature of the fauna change markedly in the living assemblages as pH decreases. © 2010 Geological Society of London