43,494 research outputs found
1. Athenaze. An Introduction to Ancient Greek, Third Edition, Book I-II, by M. Balme-G. Lawall, revised by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Workbook I, by G. Lawall-J. F. Johnson-C. King, Edited by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Workbook II, by G. Lawall-J. F. Johnson-L. Miraglia, Edited by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Book I, by M. Balme-G. Lawall, revised by J. Morwood with drawings by C. Balme, Oxford, University Press, 2016 Athenaze. An Introduction to Ancient Greek, Revised Third Edition, Workbook I, by G. Lawall-J. F. Johnson-L. Miraglia, Edited by J. Morwood, Oxford, University Press, 2016 Athenaze. An Introduction to Ancient Greek, Revised Third Edition, Workbook II, by G. Lawall-J. F. Johnson-C. King, Edited by J. Morwood, Oxford, University Press, 2016
Ferrigno Laura. 1. Athenaze. An Introduction to Ancient Greek, Third Edition, Book I-II, by M. Balme-G. Lawall, revised by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Workbook I, by G. Lawall-J. F. Johnson-C. King, Edited by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Workbook II, by G. Lawall-J. F. Johnson-L. Miraglia, Edited by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Book I, by M. Balme-G. Lawall, revised by J. Morwood with drawings by C. Balme, Oxford, University Press, 2016 Athenaze. An Introduction to Ancient Greek, Revised Third Edition, Workbook I, by G. Lawall-J. F. Johnson-L. Miraglia, Edited by J. Morwood, Oxford, University Press, 2016 Athenaze. An Introduction to Ancient Greek, Revised Third Edition, Workbook II, by G. Lawall-J. F. Johnson-C. King, Edited by J. Morwood, Oxford, University Press, 2016. In: Revue des Études Grecques, tome 129, fascicule 2, Juillet-décembre 2016. pp. 595-599
1. Athenaze. An Introduction to Ancient Greek, Third Edition, Book I-II, by M. Balme-G. Lawall, revised by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Workbook I, by G. Lawall-J. F. Johnson-C. King, Edited by J. Morwood, Oxford, University Press, 2015*Athenaze. An Introduction to Ancient Greek, Third Edition, Workbook II, by G. Lawall-J. F. Johnson-L. Miraglia, Edited by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Book I, by M. Balme-G. Lawall, revised by J. Morwood with drawings by C. Balme, Oxford, University Press, 2016 Athenaze. An Introduction to Ancient Greek, Revised Third Edition, Workbook I, by G. Lawall-J. F. Johnson-L. Miraglia, Edited by J. Morwood, Oxford, University Press, 2016 Athenaze. An Introduction to Ancient Greek, Revised Third Edition, Workbook II, by G. Lawall-J. F. Johnson-C. King, Edited by J. Morwood, Oxford, University Press, 2016
Ferrigno Laura. 1. Athenaze. An Introduction to Ancient Greek, Third Edition, Book I-II, by M. Balme-G. Lawall, revised by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Workbook I, by G. Lawall-J. F. Johnson-C. King, Edited by J. Morwood, Oxford, University Press, 2015*Athenaze. An Introduction to Ancient Greek, Third Edition, Workbook II, by G. Lawall-J. F. Johnson-L. Miraglia, Edited by J. Morwood, Oxford, University Press, 2015 Athenaze. An Introduction to Ancient Greek, Third Edition, Book I, by M. Balme-G. Lawall, revised by J. Morwood with drawings by C. Balme, Oxford, University Press, 2016 Athenaze. An Introduction to Ancient Greek, Revised Third Edition, Workbook I, by G. Lawall-J. F. Johnson-L. Miraglia, Edited by J. Morwood, Oxford, University Press, 2016 Athenaze. An Introduction to Ancient Greek, Revised Third Edition, Workbook II, by G. Lawall-J. F. Johnson-C. King, Edited by J. Morwood, Oxford, University Press, 2016. In: Revue des Études Grecques, tome 130, fascicule 1, Janvier-juin 2017. pp. 285-289
Chest wall and lung volume estimation by optical reflectance motion analysis.
Cala, S. J., C. M. Kenyon, G. Ferrigno, P. Carnevali, A. Aliverti, A. Pedotti, P. T. Macklem, and D. F. Rochester. Chest wall and lung volume estimation by optical reflectance motion analysis. J. Appl. Physiol. 81(6): 2680–2689, 1996.—Estimation of chest wall motion by surface measurements only allows one-dimensional measurements of the chest wall. We have assessed an optical reflectance system (OR), which tracks reflective markers in three dimensions (3-D) for respiratory use. We used 86 (6-mm-diameter) hemispherical reflective markers arranged circumferentially on the chest wall in seven rows between the sternal notch and the anterior superior iliac crest in two normal standing subjects. We calculated the volume of the entire chest wall and compared inspired and expired volumes with volumes obtained by spirometry. Marker positions were recorded by four TV cameras; two were 4 m in front of and two were 4 m behind the subject. The TV signals were sampled at 100 Hz and combined with grid calibration parameters on a personal computer to obtain the 3-D coordinates of the markers. Chest wall surfaces were reconstructed by triangulation through the point data, and chest wall volume was calculated. During tidal breathing and vital capacity maneuvers and during CO2-stimulated hyperpnea, there was a very close correlation of the lung volumes (Vl) estimated by spirometry [Vl(SP)] and OR [Vl(OR)]. Regression equations of Vl(OR) ( y) vs. Vl(SP) ( x,btps in liters) for the two subjects were given by y = 1.01 x − 0.01 ( r = 0.996) and y = 0.96 x + 0.03 ( r = 0.997), and by y = 1.04 x + 0.25 ( r = 0.97) and y = 0.98 x + 0.14 ( r = 0.95) for the two maneuvers, respectively. We conclude spirometric volumes can be estimated very accurately and directly from chest wall surface markers, and we speculate that OR may be usefully applied to calculations of chest wall shape, regional volumes, and motion analysis. </jats:p
Ice-front change and iceberg behaviour along Oates and George V Coasts, Antarctica, 1912-96
Ice-front change may well be a sensitive indicator of regional climate change. We have studied the western Oates Coast from Cape Kinsey (158°50'E, 69°19'S) to Cape Hudson (153°45'E, 68°20'S) and the entire George V Coast, from Cape Hudson to Point Alden (142°02'E, 66°48'S). The glaciers here drain part of the Dome Charlie and Talos Dome areas (640 000 km2). A comparison between various documents, dated several years apart, has allowed an estimate of the surficial ice discharge, the ice-front fluctuation and the iceberg-calving flux during the last 50 years. The ice-front discharge of the studied coast has been estimated at about 90±12 km3 a-1 in 1989-91, 8.5 km3 a-1 for western Oates Coast and 82 km3 a-1 for George V Coast. From 1962-63 to 1973-74 the floating glaciers underwent a net reduction that continued from 1973-74 to 1989-91. On the other hand, from 1989-91 to 1996 the area of floating glaciers increased. Ninnis Glacier Tongue and the western part of Cook Ice Shelf underwent a significant retreat after 1980 and 1947, respectively. Satellite-image analysis of large icebergs has provided information about ice-ocean interaction and the existence of an 'iceberg trap' along George V Coast. A first estimate of the mass balance of the drainage basin of Mertz and Ninnis Glaciers shows a value close to zero or slightly negative
[Letter to J. G. O'Rielly Regarding Firefighting - October 15, 1943]
Letter to J. G. O'Rielly of W. S. Darley & Company discussing the champion type "H" pump and an enclosed list of fire chiefs located throughout the Middle East. The author of this letter recommends that Mr. Rielly send photographs and the highest pressure recorded on this pump to Captain James C. Thompson
Human respiratory muscle action and control during exercise.
Aliverti, A., S. J. Cala, R. Duranti, G. Ferrigno, C. M. Kenyon, A. Pedotti, G. Scano, P. Sliwinski, Peter T. Macklem, and S. Yan. Human respiratory muscle actions and control during exercise. J. Appl. Physiol. 83(4): 1256–1269, 1997.—We measured pressures and power of diaphragm, rib cage, and abdominal muscles during quiet breathing (QB) and exercise at 0, 30, 50, and 70% maximum workload (W˙max) in five men. By three-dimensional tracking of 86 chest wall markers, we calculated the volumes of lung- and diaphragm-apposed rib cage compartments (Vrc,p and Vrc,a, respectively) and the abdomen (Vab). End-inspiratory lung volume increased with percentage of W˙max as a result of an increase in Vrc,p and Vrc,a. End-expiratory lung volume decreased as a result of a decrease in Vab. ΔVrc,a/ΔVab was constant and independent ofW˙max. Thus we used ΔVab/time as an index of diaphragm velocity of shortening. From QB to 70%W˙max, diaphragmatic pressure (Pdi) increased ∼2-fold, diaphragm velocity of shortening 6.5-fold, and diaphragm workload 13-fold. Abdominal muscle pressure was ∼0 during QB but was equal to and 180° out of phase with rib cage muscle pressure at all percent W˙max. Rib cage muscle pressure and abdominal muscle pressure were greater than Pdi, but the ratios of these pressures were constant. There was a gradual inspiratory relaxation of abdominal muscles, causing abdominal pressure to fall, which minimized Pdi and decreased the expiratory action of the abdominal muscles on Vrc,a gradually, minimizing rib cage distortions. We conclude that from QB to 0% W˙max there is a switch in respiratory muscle control, with immediate recruitment of rib cage and abdominal muscles. Thereafter, a simple mechanism that increases drive equally to all three muscle groups, with drive to abdominal and rib cage muscles 180° out of phase, allows the diaphragm to contract quasi-isotonically and act as a flow generator, while rib cage and abdominal muscles develop the pressures to displace the rib cage and abdomen, respectively. This acts to equalize the pressures acting on both rib cage compartments, minimizing rib cage distortion . </jats:p
INTEGRAL discovery of a new hard X-ray transient: IGR J17177-3656
Authors: - A. Frankowski, C. Ferrigno, E. Bozzo, T. J.-L. Courvoisier, A. Tramacere, J. Chenevez, S. Brandt, E. Kuulkers, M. Cadolle Bel, C. Sanchez-Fernandez, J. Rodriguez, I. Caballero, S. Zhang, V. Beckmann, M. Kuehnel, L. Barragan, I. Kreykenbohm, A. Paizis, M. Fiocchi, F. Capitanio, L. Natalucci, M. Del Santo, K. Watanabe, G. Puehlhofer, P. Jonker, L. Kuiper, Katja Pottschmidt, S. P. Drave, A. Malizia, V. Sguera, R. Landi, S. Migliari and P. R. den Hartoghttps://www.astronomerstelegram.org/?read=322
Inferior alveolar nerve transposition in conjunction with implant placement. Int J Oral Maxillofac Implants
The effect of using variable frequency trains during functional electrical stimulation cycling
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