Your search keyword '"GAS-EXCHANGE"' showing total 13 results

1. Sunflecks in the upper canopy: dynamics of light‐use efficiency in sun and shade leaves of Fagus sylvatica

Author

Maxime Durand, Zsofia R. Stangl, Yann Salmon, Alexandra J. Burgess, Erik H. Murchie, T. Matthew Robson, Canopy Spectral Ecology and Ecophysiology, Organismal and Evolutionary Biology Research Programme, University of Helsinki, Department of Forest Sciences, Institute for Atmospheric and Earth System Research (INAR), Viikki Plant Science Centre (ViPS), Micrometeorology and biogeochemical cycles, and Ecosystem processes (INAR Forest Sciences)

Subjects

sun and shade leaves, STEADY-STATE, Fagus sylvatica, Physiology, MESOPHYLL CONDUCTANCE, TROPICAL RAIN-FOREST, canopy vertical gradients, FLUCTUATING LIGHT, photosynthetic induction, stomatal dynamics, Plant Science, 11831 Plant biology, Trees, Plant Leaves, sunfleck, ENERGY-DISSIPATION, VERTICAL GRADIENT, Fagus, Sunlight, Photosynthesis, PIGMENT COMPOSITION, STOMATAL RESPONSES, provenance trial, GAS-EXCHANGE

Abstract

Sunflecks are transient patches of direct radiation that provide a substantial proportion of the daily irradiance to leaves in the lower canopy. In this position, faster photosynthetic induction would allow for higher sunfleck-use efficiency, as is commonly reported in the literature. Yet, when sunflecks are too few and far between, it may be more beneficial for shade leaves to prioritize efficient photosynthesis under shade. We investigated the temporal dynamics of photosynthetic induction, recovery under shade, and stomatal movement during a sunfleck, in sun and shade leaves of Fagus sylvatica from three provenances of contrasting origin. We found that shade leaves complete full induction in a shorter time than sun leaves, but that sun leaves respond faster than shade leaves due to their much larger amplitude of induction. The core-range provenance achieved faster stomatal opening in shade leaves, which may allow for better sunfleck-use efficiency in denser canopies and lower canopy positions. Our findings represent a paradigm shift for future research into light fluctuations in canopies, drawing attention to the ubiquitous importance of sunflecks for photosynthesis, not only in lower-canopy leaves where shade is prevalent, but particularly in the upper canopy where longer sunflecks are more common due to canopy openness.

Published

2022

2. Microstructural changes enhance oxygen transport in tomato ( Solanum lycopersicum ) fruit during maturation and ripening

Author

Suzane Pols, Bart Nicolai, Pieter Verboven, Hui Xiao, and Agnese Piovesan

Subjects

Ethylene, Physiology, microstructure, maturation and ripening, Plant Science, tomato, Thermal diffusivity, CELL EXPANSION, chemistry.chemical_compound, Solanum lycopersicum, Gene Expression Regulation, Plant, Respiration, oxygen diffusivity, Plant Proteins, Science & Technology, DIVISION, intercellular pore, biology, hypoxia, Plant Sciences, DEATH, Oxygen transport, food and beverages, Ripening, X-Ray Microtomography, GRAPE BERRIES, Ethylenes, cell, PEAR FRUIT, biology.organism_classification, DIFFUSION, Oxygen, MODEL, RESPIRATION, chemistry, Fruit, Biophysics, GROWTH, Solanum, Respiration rate, Climacteric, Life Sciences & Biomedicine, X-ray micro-computed tomography, GAS-EXCHANGE

Abstract

Climacteric ripening of tomato fruit is initiated by a characteristic surge of the production rate of ethylene, accompanied by an increase in respiration rate. As both activities consume O2 and produce CO2 , gas concentration gradients develop in the fruit that cause diffusive transport. This may, in turn, affect respiration and ethylene biosynthesis. Gas diffusion in fruit depends on the amount and connectivity of cells and intercellular spaces in 3D. We investigated micromorphological changes in different tomato tissues during development and ripening by visualizing cells and pores based on high-resolution micro-computed tomography, and computed effective O2 diffusivity coefficients based on microstructural features of the tissues. We demonstrated that mesocarp and septa tissues have larger cells but small and more disconnected pores than the placenta and columella, resulting in relatively lower effective O2 diffusivity coefficients. Cell disintegration occurred in the mesocarp and septa during ripening, indicating lysigenous air pore formation and resulting in a gradual increase of the effective O2 diffusivity. The results suggest that hypoxic conditions caused by the increasing size and, hence, diffusion resistance of the growing fruit may induce an increase of tissue porosity that results in a greatly enhanced O2 diffusivity and, thus, helps to alleviate them. ispartof: NEW PHYTOLOGIST vol:232 issue:5 pages:2043-2056 ispartof: location:England status: published

Published

2021

3. Artificial lungs--Where are we going with the lung replacement therapy?

Subjects

GOAT FETUSES, PUMP-LUNG, LIFE-SUPPORT, FIBER BUNDLE, IN-VITRO, extracorporeal membrane oxygenation, extracorporeal life support, BRIDGE, SINGLE-CENTER EXPERIENCE, EXTRACORPOREAL MEMBRANE-OXYGENATION, end&#8208, CO2 REMOVAL, stage lung disease, lung transplantation, wearable portable lung, artificial lung, biofabricated lung, GAS-EXCHANGE

Abstract

Lung transplantation may be a final destination therapy in lung failure, but limited donor organ availability creates a need for alternative management, including artificial lung technology. This invited review discusses ongoing developments and future research pathways for respiratory assist devices and tissue engineering to treat advanced and refractory lung disease. An overview is also given on the aftermath of the coronavirus disease 2019 pandemic and lessons learned as the world comes out of this situation. The first order of business in the future of lung support is solving the problems with existing mechanical devices. Interestingly, challenges identified during the early days of development persist today. These challenges include device-related infection, bleeding, thrombosis, cost, and patient quality of life. The main approaches of the future directions are to repair, restore, replace, or regenerate the lungs. Engineering improvements to hollow fiber membrane gas exchangers are enabling longer term wearable systems and can be used to bridge lung failure patients to transplantation. Progress in the development of microchannel-based devices has provided the concept of biomimetic devices that may even enable intracorporeal implantation. Tissue engineering and cell-based technologies have provided the concept of bioartificial lungs with properties similar to the native organ. Recent progress in artificial lung technologies includes continued advances in both engineering and biology. The final goal is to achieve a truly implantable and durable artificial lung that is applicable to destination therapy.

Published

2020

4. Extending the range of applicability of the semi‐empirical ecosystem flux model PRELES for varying forest types and climate

Author

Annikki Mäkelä, Tuomo Kalliokoski, Mikko Peltoniemi, Xianglin Tian, Francesco Minunno, Tianjian Cao, Department of Forest Sciences, Ecosystem processes (INAR Forest Sciences), Institute for Atmospheric and Earth System Research (INAR), INAR Physics, Forest Ecology and Management, Department of Physics, and Forest Modelling Group

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, evapotranspiration, Extrapolation, Eddy covariance, Forests, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Soil, light-use efficiency, Evapotranspiration, NET PRIMARY PRODUCTION, geographical variations, Environmental Chemistry, plant functional type, Uncertainty quantification, Ecosystem, 1172 Environmental sciences, BOREAL-FOREST, 0105 earth and related environmental sciences, General Environmental Science, OF-THE-ART, 4112 Forestry, Global and Planetary Change, Climate pattern, Ecology, RADIATION-USE EFFICIENCY, multisite calibration, Water, inverse modelling, Primary production, Bayes Theorem, GROSS PRIMARY PRODUCTION, Vegetation, 15. Life on land, Plant functional type, CARBON BALANCE MODEL, BAYESIAN CALIBRATION, 13. Climate action, 1181 Ecology, evolutionary biology, Environmental science, LIGHT USE EFFICIENCY, GAS-EXCHANGE, PRIMARY PRODUCTIVITY

Abstract

Applications of ecosystem flux models on large geographical scales are often limited by model complexity and data availability. Here we calibrated and evaluated a semi-empirical ecosystem flux model, PREdict Light-use efficiency, Evapotranspiration and Soil water (PRELES), for various forest types and climate conditions, based on eddy covariance data from 55 sites. A Bayesian approach was adopted for model calibration and uncertainty quantification. We applied the site-specific calibrations and multisite calibrations to nine plant functional types (PFTs) to obtain the site-specific and PFT-specific parameter vectors for PRELES. A systematically designed cross-validation was implemented to evaluate calibration strategies and the risks in extrapolation. The combination of plant physiological traits and climate patterns generated significant variation in vegetation responses and model parameters across but not within PFTs, implying that applying the model without PFT-specific parameters is risky. But within PFT, the multisite calibrations performed as accurately as the site-specific calibrations in predicting gross primary production (GPP) and evapotranspiration (ET). Moreover, the variations among sites within one PFT could be effectively simulated by simply adjusting the parameter of potential light-use efficiency (LUE), implying significant convergence of simulated vegetation processes within PFT. The hierarchical modelling of PRELES provides a compromise between satellite-driven LUE and physiologically oriented approaches for extrapolating the geographical variation of ecosystem productivity. Although measurement errors of eddy covariance and remotely sensed data propagated a substantial proportion of uncertainty or potential biases, the results illustrated that PRELES could reliably capture daily variations of GPP and ET for contrasting forest types on large geographical scales if PFT-specific parameterizations were applied.

Published

2020

5. Where does the river end? Drivers of spatiotemporal variability in CO2concentration and flux in the inflow area of a large boreal lake

Author

Hilmar Hofmann, Tatyana Efremova, Sebastian Sobek, Hannah E. Chmiel, and Natacha Pasche

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, temporal variability, Climate change, Flux, Oceanografi, hydrologi och vattenresurser, Inflow, Aquatic Science, carbon-dioxide, Oceanography, Atmospheric sciences, under-ice, 01 natural sciences, surface waters, Atmosphere, Oceanography, Hydrology and Water Resources, chemistry.chemical_compound, Water column, emission, patterns, 0105 earth and related environmental sciences, Ekologi, Ecology, 010604 marine biology & hydrobiology, spatial heterogeneity, Spatial heterogeneity, gas-exchange, chemistry, Boreal, climate-change, Carbon dioxide, Environmental science, wind-speed

Abstract

River inflow affects the spatiotemporal variability of carbon dioxide (CO2) in the water column of lakes and may locally influence CO2 gas exchange with the atmosphere. However, spatiotemporal CO2 variability at river inflow sites is often unknown leaving estimates of lake-wide CO2 emission uncertain. Here, we investigated the CO2 concentration and flux variability along a river-impacted bay and remote sampling locations of Lake Onego. During 3 years, we resolved spatial CO2 gradients between river inflow and central lake and recorded the temporal course of CO2 in the bay from the ice-covered period to early summer. We found that the river had a major influence on the spatial CO2 variability during ice-covered periods and contributed similar to 35% to the total amount of CO2 in the bay. The bay was a source of CO2 to the atmosphere at ice-melt each year emitting 2-15 times the amount as an equally sized area in the central lake. However, there was large interannual variability in the spring CO2 emission from the bay related to differences in discharge and climate that affected the hydrodynamic development of the lake during spring. In early summer, the spatial CO2 variability was unrelated to the river signal but correlated negatively with dissolved oxygen concentrations instead indicating a stronger biological control on CO2. Our study reveals a large variability of CO2 and its drivers at river inflow sites at the seasonal and at the interannual time scale. Understanding these dynamics is essential for predicting lake-wide CO2 fluxes more accurately under a warming climate.

Published

2019

6. Artificial lungs––Where are we going with the lung replacement therapy?

Author

N. Shigemura, Justyna Swol, Masaki Anraku, Shingo Ichiba, Ulrich Steinseifer, and Roberto Lorusso

Subjects

medicine.medical_specialty, Coronavirus disease 2019 (COVID-19), medicine.medical_treatment, 0206 medical engineering, LIFE-SUPPORT, Biomedical Engineering, FIBER BUNDLE, Medicine (miscellaneous), Bioengineering, 02 engineering and technology, Oxygenators, 030204 cardiovascular system & hematology, extracorporeal life support, BRIDGE, Artificial lung, EXTRACORPOREAL MEMBRANE-OXYGENATION, Biomaterials, Wearable Electronic Devices, 03 medical and health sciences, 0302 clinical medicine, CO2 REMOVAL, lung transplantation, medicine, Extracorporeal membrane oxygenation, Humans, Lung transplantation, wearable portable lung, Intensive care medicine, artificial lung, biofabricated lung, GOAT FETUSES, Lung, Tissue Engineering, PUMP-LUNG, COVID-19, IN-VITRO, General Medicine, extracorporeal membrane oxygenation, 020601 biomedical engineering, SINGLE-CENTER EXPERIENCE, Transplantation, end&#8208, medicine.anatomical_structure, Biomimetic Devices, Intensive Care, Neonatal, stage lung disease, GAS-EXCHANGE, Destination therapy

Abstract

Lung transplantation may be a final destination therapy in lung failure, but limited donor organ availability creates a need for alternative management, including artificial lung technology. This invited review discusses ongoing developments and future research pathways for respiratory assist devices and tissue engineering to treat advanced and refractory lung disease. An overview is also given on the aftermath of the coronavirus disease 2019 pandemic and lessons learned as the world comes out of this situation. The first order of business in the future of lung support is solving the problems with existing mechanical devices. Interestingly, challenges identified during the early days of development persist today. These challenges include device-related infection, bleeding, thrombosis, cost, and patient quality of life. The main approaches of the future directions are to repair, restore, replace, or regenerate the lungs. Engineering improvements to hollow fiber membrane gas exchangers are enabling longer term wearable systems and can be used to bridge lung failure patients to transplantation. Progress in the development of microchannel-based devices has provided the concept of biomimetic devices that may even enable intracorporeal implantation. Tissue engineering and cell-based technologies have provided the concept of bioartificial lungs with properties similar to the native organ. Recent progress in artificial lung technologies includes continued advances in both engineering and biology. The final goal is to achieve a truly implantable and durable artificial lung that is applicable to destination therapy.

Published

2020

7. Early Miocene <scp>CO</scp> 2 estimates from a Neotropical fossil leaf assemblage exceed 400 ppm

Author

Dana L. Royer, Liliana Londoño, Andrés L. Cárdenas-Rozo, Jaime Escobar, Carlos Jaramillo, David A. Foster, Aaron R. Wood, Universidad EAFIT. Departamento de Ciencias, and Biodiversidad, Evolución y Conservación

Subjects

fossil, model, leaf, 010504 meteorology & atmospheric sciences, Global climate, stomata, Holocene climatic optimum, Miocene, Plant Science, Biology, 010502 geochemistry & geophysics, 01 natural sciences, Greenhouse climate, gas-exchange, 13. Climate action, Co2 concentration, Genetics, Assemblage (archaeology), CO2, Physical geography, Ecology, Evolution, Behavior and Systematics, Volume concentration, 0105 earth and related environmental sciences

Abstract

Premise of the Study: The global climate during the early Miocene was warmer than the present and preceded the even warmer middle Miocene climatic optimum. The paleo-CO2 records for this interval suggest paradoxically low concentrations (95% confidence) that CO2 during the late early Miocene exceeded 400 ppm. These results revise upwards the likely CO2 concentration at this time, more in keeping with a CO2-forced greenhouse climate. © 2018 Botanical Society of America

Published

2018

8. The validity of optimal leaf traits modelled on environmental conditions

Author

Belinda E. Medlyn, Michael J. Liddell, Lingling Zhu, Matthias M. Boer, I. Colin Prentice, Rizwana Rumman, Bradley Evans, Michael F. Hutchinson, Tim Wardlaw, David S. Ellsworth, Lucas A. Cernusak, James Cleverly, Ian J. Wright, Derek Eamus, Peter Cale, John J. G. Egerton, Keith J. Bloomfield, Henrique Furstenau Togashi, Lucy Hayes, Craig Macfarlane, Owen K. Atkin, Wayne S. Meyer, and AXA Research Fund

Subjects

0106 biological sciences, 0301 basic medicine, Stomatal conductance, stomatal conductance (g(s)), Physiology, MESOPHYLL CONDUCTANCE, STOMATAL CONDUCTANCE, Plant Biology & Botany, stable isotopes, Plant Science, Environment, CARBON-ISOTOPE DISCRIMINATION, Models, Biological, 01 natural sciences, Electron Transport, 03 medical and health sciences, Quantitative Trait, Heritable, 07 Agricultural and Veterinary Sciences, Botany, water-use efficiency, ATMOSPHERIC CO2, Photosynthesis, Carbon Isotopes, Science & Technology, TEMPERATURE RESPONSE, Philosophy, Plant Sciences, temperature, BIOCHEMICAL-MODEL, stomatal conductance (gs), Reproducibility of Results, 06 Biological Sciences, 15. Life on land, Photosynthetic capacity, Plant Leaves, 030104 developmental biology, aridity, 13. Climate action, Plant Stomata, Linear Models, OPTIMIZATION THEORY, Life Sciences & Biomedicine, PHOTOSYNTHETIC CAPACITY, Temperature response, GAS-EXCHANGE, 010606 plant biology & botany

Abstract

© 2018 The Authors. New Phytologist © 2018 New Phytologist Trust The ratio of leaf intercellular to ambient CO 2 (χ) is modulated by stomatal conductance (g s ). These quantities link carbon (C) assimilation with transpiration, and along with photosynthetic capacities (V cmax and J max ) are required to model terrestrial C uptake. We use optimization criteria based on the growth environment to generate predicted values of photosynthetic and water-use efficiency traits and test these against a unique dataset. Leaf gas-exchange parameters and carbon isotope discrimination were analysed in relation to local climate across a continental network of study sites. Sun-exposed leaves of 50 species at seven sites were measured in contrasting seasons. Values of χ predicted from growth temperature and vapour pressure deficit were closely correlated to ratios derived from C isotope (δ 13 C) measurements. Correlations were stronger in the growing season. Predicted values of photosynthetic traits, including carboxylation capacity (V cmax ), derived from δ 13 C, growth temperature and solar radiation, showed meaningful agreement with inferred values derived from gas-exchange measurements. Between-site differences in water-use efficiency were, however, only weakly linked to the plant's growth environment and did not show seasonal variation. These results support the general hypothesis that many key parameters required by Earth system models are adaptive and predictable from plants’ growth environments.

Published

2018

9. Measuring 129 Xe transfer across the blood-brain barrier using MR spectroscopy.

Author

Rao MR, Norquay G, Stewart NJ, and Wild JM

Subjects

Humans, Lung, Magnetic Resonance Imaging, Magnetic Resonance Spectroscopy, Xenon, Blood-Brain Barrier diagnostic imaging, Xenon Isotopes

Abstract

Purpose: This study develops a tracer kinetic model of xenon uptake in the human brain to determine the transfer rate of inhaled hyperpolarized 129 Xe from cerebral blood to gray matter that accounts for the effects of cerebral physiology, perfusion and magnetization dynamics. The 129 Xe transfer rate is expressed using a tracer transfer coefficient, which estimates the quantity of hyperpolarized 129 Xe dissolved in cerebral blood under exchange with depolarized 129 Xe dissolved in gray matter under equilibrium of concentration., Theory and Methods: Time-resolved MR spectra of hyperpolarized 129 Xe dissolved in the human brain were acquired from three healthy volunteers. Acquired spectra were numerically fitted with five Lorentzian peaks in accordance with known 129 Xe brain spectral peaks. The signal dynamics of spectral peaks for gray matter and red blood cells were quantified, and correction for the 129 Xe T 1 dependence upon blood oxygenation was applied. 129 Xe transfer dynamics determined from the ratio of the peaks for gray matter and red blood cells was numerically fitted with the developed tracer kinetic model., Results: For all the acquired NMR spectra, the developed tracer kinetic model fitted the data with tracer transfer coefficients between 0.1 and 0.14., Conclusion: In this study, a tracer kinetic model was developed and validated that estimates the transfer rate of HP 129 Xe from cerebral blood to gray matter in the human brain., (© 2021 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2021

10. Water Sources and Water‐Use Efficiency in Mediterranean Coastal Dune Vegetation

Author

Marco Lauteri, M. De Lillis, Enrico Brugnoli, and G. A. Alessio

Subjects

Delta, Stomatal conductance, Elymus, Water table, Fresh Water, Plant Science, Oxygen Isotopes, Biology, Models, Biological, Magnoliopsida, Quercus, STABLE-ISOTOPES, Botany, Seawater, PLANTS, Water-use efficiency, CARBON ISOTOPE DISCRIMINATION, Ecology, Evolution, Behavior and Systematics, Smilax aspera, Carbon Isotopes, PRECIPITATION, Mediterranean Region, Water, Xylem, General Medicine, biology.organism_classification, Agronomy, Juniperus, Pistacia, Smilax, Juniperus oxycedrus, Elymus farctus, GAS-EXCHANGE

Abstract

In coastal environments plants have to cope with various water sources: rainwater, water table, seawater, and mixtures. These are usually characterized by different isotopic signatures ( (18)O/ (16)O and D/H ratios). Xylem water reflects the isotopic compositions of the water sources. Additionally, water-use efficiency (WUE) can be assessed with carbon isotope discrimination (Delta) analyses. Gas exchange, Delta of leaf dry matter, and isotopic composition (delta (18)O) of xylem water were measured from June to August 2001 in herbaceous perennials of mobile dunes (Ammophila littoralis, Elymus farctus) and sclerophyllous shrubs and climbers (Arbutus unedo, Pistacia lentiscus, Phillyrea angustifolia, Qercus ilex, Juniperus oxycedrus, Smilax aspera) of consolidated dunes. Assimilation rates were rather low and did not show clear seasonal patterns, possibly due to limited precipitation and generally low values of stomatal conductance. The lowest values were shown in S. aspera. Different physiological patterns were found, on the basis of delta (18)O and Delta analyses. Values of delta (18)O of xylem water of phanerophytes were remarkably constant and matched those of the water table, indicating dependence on a reliable water source; values of Delta were relatively high, indicating low intrinsic WUE, with the exception of J. oxycedrus. Surprisingly, very high delta (18)O values were found for the xylem water from S. aspera in August. This suggests retrodiffusion of leaf water to xylem sap in the stem or direct uptake of water by leaves or stems, owing to dew or fog occurrence. Low Delta values indicated high WUE in S. aspera. Contrasting strategies were shown by the species of mobile dunes: E. farctus relied on superficial water and exhibited low WUE, accordingly to its therophyte-like vegetative cycle; on the contrary, A. littoralis used deeper water sources, showing higher WUE in relation to its long-lasting vegetative habit.

Published

2004

11. Photosynthesis of two poplar clones under long-term exposure to ozone

Author

Cristina Nali, Gian Franco Soldatini, Giacomo Lorenzini, Lucia Guidi, and F. Filippi

Subjects

ENVIRONMENT ALTERS RESPONSE, CHLOROPHYLL FLUORESCENCE, Stomatal conductance, STRESS, Ozone, Physiology, Plant Science, Biology, Photosynthesis, chemistry.chemical_compound, Co2 concentration, Botany, Genetics, Chlorophyll fluorescence, SEEDLINGS, HYBRID POPULUS L, ACER-SACCHARUM MARSH, Cell Biology, General Medicine, Fluorescence, Differential effects, Electron transport chain, Horticulture, YIELD, chemistry, GROWTH, ENVIRONMENT ALTERS RESPONSE, ACER-SACCHARUM MARSH, HYBRID POPULUS L, CHLOROPHYLL FLUORESCENCE, GAS-EXCHANGE, SEEDLINGS, YIELD, GROWTH, STRESS, GAS-EXCHANGE

Abstract

The photosynthetic response was studied in two clones (Populus deltoides × maximowiczii Eridano and Populus × euramericana I-214), known for their differential response to ozone (O3) in terms of visible symptoms, when exposed to O3 (60 nl l−1 5 h day−1, 7 and 15 days). The photosynthetic ability was tested using gas exchange and chlorophyll fluorescence analysis. O3 caused a decrease in the CO2 assimilation rate at light saturation level in mature leaves of both clones. Alterations of Chl fluorescence parameters, in particular the Fv/Fm ratio and non-photochemical quenching were also observed. The effects were similar for both clones and it could not be concluded that differential effects on electron transport capacity were responsible for the observed reduction in photosynthesis. The reduction of photosynthetic rate in Eridano was due mainly to a reduced mesophyll activity, as evidenced by the increase in intercellular CO2 concentration and the minimal changes in stomatal conductance. In contrast, in I-214, stomatal effects were primarily responsible, although effects on the mesophyll cannot be excluded. Data obtained indicate that the effects observed at the mesophyll level may be attributed to indirect effects caused by membrane disorders.

Published

1998

12. Experimental validation of the hyperpolarized 129 Xe chemical shift saturation recovery technique in healthy volunteers and subjects with interstitial lung disease.

Author

Stewart NJ, Leung G, Norquay G, Marshall H, Parra-Robles J, Murphy PS, Schulte RF, Elliot C, Condliffe R, Griffiths PD, Kiely DG, Whyte MK, Wolber J, and Wild JM

Abstract

Purpose: To assess the sensitivity of the hyperpolarized 129 Xe chemical shift saturation recovery (CSSR) technique for noninvasive quantification of changes to lung microstructure and function in idiopathic pulmonary fibrosis (IPF) and systemic sclerosis (SSc)., Methods: Ten healthy volunteers, four subjects with SSc and four with IPF were scanned at 1.5 T. A CSSR pulse sequence was implemented using binomial-composite radiofrequency pulses to monitor 129 Xe magnetization in tissues and blood plasma (T/P) and red blood cells (RBCs). The dynamics of 129 Xe uptake into these compartments were fitted with three existing analytical models of gas diffusion to extract parameters of lung physiology. These parameters were quantitatively compared between models., Results: Uptake of xenon into the pulmonary capillaries was impaired in subjects with IPF and SSc. Statistically significant septal thickening was measured by 129 Xe CSSR in IPF patients. Preliminary data suggests age-dependent alterations to septal thickness in healthy volunteers. These findings were reproduced using each of the literature models. CSSR-derived parameters were compared with gold-standard indicators of pulmonary function; diffusing capacity of carbon monoxide and pulmonary transit-time., Conclusions: CSSR with hyperpolarized 129 Xe is sensitive to pathology-induced degradation of lung structure/function and shows promise for quantification of disease severity and monitoring treatment response. Magn Reson Med 74:196-207, 2015. © 2014 Wiley Periodicals, Inc., (© 2014 Wiley Periodicals, Inc.)

Published

2015

13. Foliar respiration is related to photosynthetic, growth and carbohydrate response to experimental drought and elevated temperature

Author

Collins, Adam D., Ryan, Michael G., Adams, Henry D., Dickman, Lee Turin, Garcia-Forner, Nuria, Grossiord, Charlotte, Powers, Heath H., Sevanto, Sanna, and McDowell, Nate G.

Subjects

thermal-acclimation, carbon balance, atmospheric co2, food and beverages, trees, isohydry, fine-root respiration, tree, anisohydry, gas-exchange, thermal acclimation, climate-change, tree mortality, leaf respiration, plant respiration, nonstructural carbohydrates, pinyon-juniper woodland, stomatal control

Abstract

Short-term plant respiration (R) increases exponentially with rising temperature, but drought could reduce respiration by reducing growth and metabolism. Acclimation may alter these responses. We examined if species with different drought responses would differ in foliar R response to +4.8 degrees C temperature and -45% precipitation in a field experiment with mature pinon and juniper trees, and if any differences between species were related to differences in photosynthesis rates, shoot growth and nonstructural carbohydrates (NSCs). Short-term foliar R had a Q(10) of 1.6 for pinon and 2.6 for juniper. Pinon foliar R did not respond to the +4.8 degrees C temperatures, but R increased 1.4x for juniper. Across treatments, pinon foliage had higher growth, lower NSC content, 29% lower photosynthesis rates, and 44% lower R than juniper. Removing 45% precipitation had little impact on R for either species. Species differences in the response of R under elevated temperature were related to substrate availability and stomatal response to leaf water potential. Despite not acclimating to the higher temperature and having higher R than pinon, greater substrate availability in juniper suggests it could supply respiratory demand for much longer than pinon. Species responses will be critical in ecosystem response to a warmer climate.