Multidetector CT coronary angiography: have we found the holy grail of non-invasive coronary imaging?

Is technology about to deliver on the long awaited goal of effective non-invasive methods for visualising and assessing coronary arteries?

Cell cycling and cell enlargement in developing leaves of Arabidopsis

Cell cycling plays an important role in plant development, including: (1) organ morphogenesis, (2) cell proliferation within tissues, and (3) cell differentiation. In this study we use a cyclin::beta-glucuronidase reporter construct to characterize spatial and temporal patterns of cell cycling at each of these levels during wild-type development in the model genetic organism Arabidopsis thaliana (Columbia). We show that a key morphogenetic event in leaf development, blade formation, is highly correlated with localized cell cycling at the primordium margin. However, tissue layers are established by a more diffuse distribution of cycling cells that does not directly involve the marginal zone. During leaf expansion, tissue proliferation shows a strong longitudinal gradient, with basiplastic polarity. Tissue layers differ in pattern of proliferative cell divisions: cell cycling of palisade mesophyll precursors is prolonged in comparison to that of pavement cells of the adjacent epidermal layers, and cells exit the cycle at different characteristic sizes. Cell divisions directly related to formation of stomates and of vascular tissue from their respective precursors occur throughout the period of leaf extension, so that differing tissue patterns reflect superposition of cycling related to cell differentiation on more general tissue proliferation. Our results indicate that cell cycling related to leaf morphogenesis, tissue-specific patterns of cell proliferation, and cell differentiation occurs concurrently during leaf development and suggest that unique regulatory pathways may operate at each level.

End-expiratory lung volume during arm and leg exercise in normal subjects and patients with cystic fibrosis

There are no reports concerning the regulation of end-expiratory lung volume (EELV) and flow-volume relationships during upper limb exercise in health and disease. We studied EELV during such exercise in 22 adults with cystic fibrosis (CF) and nine age-matched healthy control subjects. Subjects with CF were grouped according to the severity of their lung disease, as follows: mild = FEV1 > 80% predicted; moderate = FEV1 40 to 80% predicted, and severe = FEV1 < 40% predicted. EELV was calculated from measurements of inspiratory capacity (IC) made at each workload during an incremental arm and leg ergometer test to peak work capacity. In the control group, the decrease in EELV was significantly smaller for arm than for leg exercise at peak work (-0.13 L versus -0.53 L, p < 0.001) and for arm than for leg exercise at an equivalent submaximal ventilation (-0.13 L versus -0.46 L, p < 0.01). In the groups with moderate and severe CF, arm exercise resulted in an increase in EELV from resting levels (dynamic hyperinflation) that was not significantly different from the increase observed for leg exercise. For CF subjects there was a significant inverse relationship between FEV1 and changes in EELV from rest to peak arm exercise (r = -0.46, p < 0.05). In normal subjects, there was a difference in the EELV response for arm versus leg exercise. In CF subjects with airflow limitation, dynamic hyperinflation occurred with both forms of exercise.

Evaluation of supported upper limb exercise capacity in patients with cystic fibrosis

Physiological responses to upper limb exercise have not been well documented in patients with cystic fibrosis (CF). This is the first study to quantify ventilatory responses to supported incremental upper limb exercise in this patient group. Twenty-four subjects with CF, with a wide range of pulmonary impairment, and ten normal control subjects were studied. Subjects performed pulmonary function tests and incremental arm and leg exercise to peak work capacity on an arm crank and bicycle ergometer. All subjects performed less work with the arms than legs. At an equivalent oxygen consumption, ventilation was higher for arm work than leg work. This higher ventilation was achieved mainly through a higher frequency of breathing. Only CF subjects with severe pulmonary impairment (FEV1 < 40% predicted, FEF25-75% < 20% predicted) had a reduced arm work capacity compared with control subjects. At peak arm work, these subjects had a mean ventilation to maximum voluntary ventilation ratio (VE/MVV) of 106% +/- 25, while maximum heart rate was less than 80% predicted. Despite the high ventilatory requirement for arm exercise, arm work capacity was well maintained in subjects with CF until severe lung disease impaired the ability to further increase ventilation.

Ventilatory mechanics at rest and during exercise in patients with cystic fibrosis

Ventilatory mechanics were measured at rest and during steady-state (25%, 50%, 75%) and maximal exercise (W-Max) on a cycle-ergometer in eight adult patients (FEV1 22 to 114% of predicted) with cystic fibrosis (CF). Tidal flow-volume loops were measured at rest and during exercise and placed within the maximal pre- and postexercise flow-volume loops, based on measured end-expiratory lung volume (EELV). The degree of flow limitation was expressed as the percentage of the tidal flow-volume loop that met the expiratory boundary of the maximal loop (TFVL%). Pressure-volume relationships were assessed by measurement of transpulmonary pressure (PTP). Peak inspiratory PTP was compared with maximal inspiratory pressures at rest and during exercise (Pcap(i)) at the equivalent lung volume. The maximal effective expiratory pressure (Pmax(e)) was determined using the orifice technique. Three patients with milder disease (FEV1 114, 98, 89% of predicted) did not show any flow limitation at rest or 50% W-Max but two did show some flow limitation at W-Max (0, 3, 23 TFVL%) with a decrease in EELV (-400, -200, -300 ml). There was considerable reserve for inspiratory and expiratory pressure generation at W-Max. Flow limitation was noted at rest in three patients and at 50% W-Max in the five patients with more severe airways obstruction. The increased flow was achieved by an increase in EELV in all five patients (+400, +430, +330, +150, +700 ml at W-Max). Pcap(i) was reached in two patients (-28, -36 cm H2O), while Pmax(e) was exceeded by four patients suggesting inefficient pressure generation. Expiratory flow limitation, hyperinflation, and pressure swings approaching capacity severely compromised the capacity to generate ventilation in some patients with CF.

Large lungs and growth hormone: an increased alveolar number?

Previous physiological studies suggest that increased lung growth in patients with acromegaly is associated with either a normal or above normal pulmonary transfer factor. These findings can be interpreted to suggest either alveolar hypertrophy or hyperplasia as the mechanism for lung growth in this condition. Since the ventilated airspaces retain normal elastic properties, we wanted to determine whether the mechanism for lung growth in acromegaly is the result of an increased alveolar number rather than size. Measurements of pulmonary distensibility (K) (an index of alveolar size), elastic recoil, single-breath carbon monoxide transfer factor and carbon monoxide transfer coefficient (KCO), pulmonary capillary blood volume and alveolar membrane diffusing capacity, together with chest width, were compared in nonsmoking, acromegalic and normal men and women, with and without an increased lung size. Pulmonary transfer factor was normal for all groups studied, regardless of lung size. However, KCO was inversely related to total lung capacity (% predicted) for all subjects and KCO (% predicted) was inversely related to chest width in men. Pulmonary capillary blood volume (% predicted) was inversely related to total lung capacity (% predicted) for subjects with large lungs. Pulmonary distensibility (K), membrane diffusing capacity and elastic recoil were within the normal range. These findings suggest normal alveolar size, alveolar membrane surface area and mechanical function in subjects with large lungs. They also suggest that KCO may not be a reliable guide to the interpretation of the mechanism of lung growth in individuals with disproportionately large lungs, and may be reduced because not all the alveoli are perfused. The normal values for pulmonary distensibility found in all our individuals with large lungs, including acromegalics, suggest that lung growth has been achieved by an increased alveolar number rather than size. However, morphometric studies of the lungs of nonsmoking, acromegalic subjects without lung disease, are required to substantiate this finding.

Large lungs and growth hormone: an increased alveolar number?

Previous physiological studies suggest that increased lung growth in patients with acromegaly is associated with either a normal or above normal pulmonary transfer factor. These findings can be interpreted to suggest either alveolar hypertrophy or hyperplasia as the mechanism for lung growth in this condition. Since the ventilated airspaces retain normal elastic properties, we wanted to determine whether the mechanism for lung growth in acromegaly is the result of an increased alveolar number rather than size. Measurements of pulmonary distensibility (K) (an index of alveolar size), elastic recoil, single-breath carbon monoxide transfer factor and carbon monoxide transfer coefficient (KCO), pulmonary capillary blood volume and alveolar membrane diffusing capacity, together with chest width, were compared in nonsmoking, acromegalic and normal men and women, with and without an increased lung size. Pulmonary transfer factor was normal for all groups studied, regardless of lung size. However, KCO was inversely related to total lung capacity (% predicted) for all subjects and KCO (% predicted) was inversely related to chest width in men. Pulmonary capillary blood volume (% predicted) was inversely related to total lung capacity (% predicted) for subjects with large lungs. Pulmonary distensibility (K), membrane diffusing capacity and elastic recoil were within the normal range. These findings suggest normal alveolar size, alveolar membrane surface area and mechanical function in subjects with large lungs. They also suggest that KCO may not be a reliable guide to the interpretation of the mechanism of lung growth in individuals with disproportionately large lungs, and may be reduced because not all the alveoli are perfused. The normal values for pulmonary distensibility found in all our individuals with large lungs, including acromegalics, suggest that lung growth has been achieved by an increased alveolar number rather than size. However, morphometric studies of the lungs of nonsmoking, acromegalic subjects without lung disease, are required to substantiate this finding.

The upper limit of alveolar capillary recruitment in a young man with lung growth impairment

In order to obtain further insight into the adaptive mechanisms relating to gas exchange in anatomically small lungs, tests of mechanical lung function and gas exchange were made in an active young man, whose lung growth had been severely impaired due to pectus excavatum developed in childhood. We found our patient to have small (total lung capacity, 59% of predicted) but mechanically normal lungs. He had a normal cardiac output, a normal single-breath diffusing capacity (100% pred), and a high diffusion coefficient (148% pred) associated with a high pulmonary capillary blood volume (131% pred) at rest. Pulmonary distensibility (K) and elastic recoil were normal. During steady-state exercise he was unable to recruit further reserves of pulmonary capillaries, but this was not reflected in a plateau for oxygen consumption, which was presumably the result of an increased pulmonary capillary blood flow rather than volume. The recruitment of pulmonary capillary reserves in this young man has enabled him to maintain a normal maximum exercise capacity. In addition, the high stroke volume and a haemoglobin level in the high normal range (176 g.l-1) may have maintained his maximal exercise function, despite fewer alveolar units. This study suggests that, contrary to previous findings, loss of a major proportion of lung tissue need not impair exercise capacity. Patients with either small lungs or following pneumonectomy may benefit from physical training sufficient to optimize both an increase in cardiac output and recruitment of their existing alveolar capillary reserves.

The effect of a comprehensive, intensive inpatient treatment program on lung function and exercise capacity in patients with cystic fibrosis

BACKGROUND AND PURPOSE

The purpose of this investigation was to measure the effects of a 10- to 14-day comprehensive, intensive hospital treatment program on peak exercise capacity, endurance capacity, respiratory function, weight change, and maximum inspiratory and expiratory mouth pressures in patients with cystic fibrosis with a pulmonary exacerbation.

SUBJECTS

Fourteen young adults with cystic fibrosis admitted to a hospital for an exacerbation of their pulmonary disease were studied.

METHODS

Subjects performed pulmonary function tests, inspiratory and expiratory mouth pressure tests, and stationary bicycle exercise tests at admission and discharge. Comprehensive therapy provided during the hospital admission consisted of intravenous antibiotics, physical therapy, high-calorie diet, and daily medical review.

RESULTS

The patients showed improvements in forced expiratory volume in 1 second (46%-55% of predicted values) and forced vital capacity (62%-68% of predicted values). Maximum inspiratory and expiratory mouth pressures also improved (118%-131% and 78%-92% of predicted values, respectively). There was a mean weight gain of 2 kg. Maximum work capacity on a bicycle ergometer improved from a mean of 45% to 52% of predicted values. The most impressive result was the marked increase in exercise endurance time from a mean of 9.5 minutes on admission to 16.6 minutes at discharge.

CONCLUSION AND DISCUSSION

This study indicates that young adults with cystic fibrosis and an exacerbation of their pulmonary disease obtain measurable benefits from a comprehensive, intensive treatment program, particularly improvement in their capacity for endurance exercise.

The large lungs of elite swimmers: an increased alveolar number?

In order to obtain further insight into the mechanisms relating to the large lung volumes of swimmers, tests of mechanical lung function, including lung distensibility (K) and elastic recoil, pulmonary diffusion capacity, and respiratory mouth pressures, together with anthropometric data (height, weight, body surface area, chest width, depth and surface area), were compared in eight elite male swimmers, eight elite male long distance athletes and eight control subjects. The differences in training profiles of each group were also examined. There was no significant difference in height between the subjects, but the swimmers were younger than both the runners and controls, and both the swimmers and controls were heavier than the runners. Of all the training variables, only the mean total distance in kilometers covered per week was significantly greater in the runners. Whether based on: (a) adolescent predicted values; or (b) adult male predicted values, swimmers had significantly increased total lung capacity ((a) 145 +/- 22%, (mean +/- SD) (b) 128 +/- 15%); vital capacity ((a) 146 +/- 24%, (b) 124 +/- 15%); and inspiratory capacity ((a) 155 +/- 33%, (b) 138 +/- 29%), but this was not found in the other two groups. Swimmers also had the largest chest surface area and chest width. Forced expiratory volume in one second (FEV1) was largest in the swimmers ((b) 122 +/- 17%) and FEV1 as a percentage of forced vital capacity (FEV1/FVC)% was similar for the three groups. Pulmonary diffusing capacity (DLCO) was also highest in the swimmers (117 +/- 18%). All of the other indices of lung function, including pulmonary distensibility (K), elastic recoil and diffusion coefficient (KCO), were similar. These findings suggest that swimmers may have achieved greater lung volumes than either runners or control subjects, not because of greater inspiratory muscle strength, or differences in height, fat free mass, alveolar distensibility, age at start of training or sternal length or chest depth, but by developing physically wider chests, containing an increased number of alveoli, rather than alveoli of increased size. However, in this cross-sectional study, hereditary factors cannot be ruled out, although we believe them to be less likely.

The large lungs of elite swimmers: an increased alveolar number?

In order to obtain further insight into the mechanisms relating to the large lung volumes of swimmers, tests of mechanical lung function, including lung distensibility (K) and elastic recoil, pulmonary diffusion capacity, and respiratory mouth pressures, together with anthropometric data (height, weight, body surface area, chest width, depth and surface area), were compared in eight elite male swimmers, eight elite male long distance athletes and eight control subjects. The differences in training profiles of each group were also examined. There was no significant difference in height between the subjects, but the swimmers were younger than both the runners and controls, and both the swimmers and controls were heavier than the runners. Of all the training variables, only the mean total distance in kilometers covered per week was significantly greater in the runners. Whether based on: (a) adolescent predicted values; or (b) adult male predicted values, swimmers had significantly increased total lung capacity ((a) 145 +/- 22%, (mean +/- SD) (b) 128 +/- 15%); vital capacity ((a) 146 +/- 24%, (b) 124 +/- 15%); and inspiratory capacity ((a) 155 +/- 33%, (b) 138 +/- 29%), but this was not found in the other two groups. Swimmers also had the largest chest surface area and chest width. Forced expiratory volume in one second (FEV1) was largest in the swimmers ((b) 122 +/- 17%) and FEV1 as a percentage of forced vital capacity (FEV1/FVC)% was similar for the three groups. Pulmonary diffusing capacity (DLCO) was also highest in the swimmers (117 +/- 18%). All of the other indices of lung function, including pulmonary distensibility (K), elastic recoil and diffusion coefficient (KCO), were similar. These findings suggest that swimmers may have achieved greater lung volumes than either runners or control subjects, not because of greater inspiratory muscle strength, or differences in height, fat free mass, alveolar distensibility, age at start of training or sternal length or chest depth, but by developing physically wider chests, containing an increased number of alveoli, rather than alveoli of increased size. However, in this cross-sectional study, hereditary factors cannot be ruled out, although we believe them to be less likely.

Changes in end-expiratory lung volume during exercise in cystic fibrosis relate to severity of lung disease

Changes in end-expiratory lung volume (EELV) during exercise in normal subjects and in patients with severe chronic obstructive lung disease have previously been examined. To date there are no studies that have examined the changes in EELV in patients with mild to moderate lung disease. We studied the changes in EELV during exercise in patients with cystic fibrosis (CF) with a wide range of pulmonary impairment to determine if changes in EELV were related to the severity of lung disease. Twenty-two patients with CF were studied (FEV1 17 to 112% of predicted) during progressive bicycle exercise, and changes in EELV were determined by repeat measures of inspiratory capacity. Changes in EELV at end exercise ranged from an increase of 0.67 L to a decrease of 0.61 L, and significant relationships were found between the changes in EELV and resting lung function (FEV1 percent predicted r = 0.79 and VR/TLC r = 0.58), indices of maximal expiratory flow (FEF50 r = -0.72 and FEF25-75 r = -0.71), and maximal work capacity (W-Max r = -0.76 and W-Max percent predicted r = -0.69). For subsequent analysis, patients were divided into two subgroups. Patients who were able to decrease EELV during exercise (Subgroup A) had significantly better resting lung function and SaO2 and significantly higher W-Max, peak oxygen consumption, and SaO2 at W-Max. Patients in Subgroup A also had a near normal ventilatory pattern during exercise. In contrast, the patients who increased EELV during exercise (Subgroup B) had severe lung disease (mean FEV1 29 +/- 4 percent predicted), limited work capacity, and desaturated during exercise.(ABSTRACT TRUNCATED AT 250 WORDS)

What factors explain racial differences in lung volumes?

In order to examine the physical characteristics that may determine racial differences in lung volumes, we studied healthy, nonsmoking Caucasian, Chinese and Indian males of similar ages (range 18-51 yrs). We measured spirometric function, flow volume curves, lung volumes, inspiratory and expiratory muscle pressures, alveolar distensibility and diffusing capacity, together with height, weight and fat free mass. Chest shape was measured using radiographs. The mean total lung capacity and vital capacity in the Caucasian group, expressed as percentage predicted, were 5 and 10% higher than in the Chinese group and 17 and 20% higher than in the Indian group. Chinese values for these measurements were 12 and 10% greater than Indian. We found that Caucasians had higher fat free masses, higher inspiratory and expiratory muscle pressures and wider chests than the other races. The Caucasians and Chinese had longer chests than the Indians. There was no difference in alveolar distensibility or in the diffusion coefficient between the groups. These findings suggest that Caucasians have larger lung volumes than Chinese and Indians because they have increased numbers of alveoli and physically larger chest cavities, and not because of greater alveolar distensibility. Chest dimensions, together with height and race explained 90% of the variation in forced vital capacity and 86% of the variation in total lung capacity. Height multiplied by fat free mass, a "physique factor", previously suggested as the best predictive factor for forced vital capacity in Caucasians, did not account for much of the variation in forced vital capacity between Caucasians and Indians, presumably because it takes no account of differences in chest dimensions.

What factors explain racial differences in lung volumes?

In order to examine the physical characteristics that may determine racial differences in lung volumes, we studied healthy, nonsmoking Caucasian, Chinese and Indian males of similar ages (range 18-51 yrs). We measured spirometric function, flow volume curves, lung volumes, inspiratory and expiratory muscle pressures, alveolar distensibility and diffusing capacity, together with height, weight and fat free mass. Chest shape was measured using radiographs. The mean total lung capacity and vital capacity in the Caucasian group, expressed as percentage predicted, were 5 and 10% higher than in the Chinese group and 17 and 20% higher than in the Indian group. Chinese values for these measurements were 12 and 10% greater than Indian. We found that Caucasians had higher fat free masses, higher inspiratory and expiratory muscle pressures and wider chests than the other races. The Caucasians and Chinese had longer chests than the Indians. There was no difference in alveolar distensibility or in the diffusion coefficient between the groups. These findings suggest that Caucasians have larger lung volumes than Chinese and Indians because they have increased numbers of alveoli and physically larger chest cavities, and not because of greater alveolar distensibility. Chest dimensions, together with height and race explained 90% of the variation in forced vital capacity and 86% of the variation in total lung capacity. Height multiplied by fat free mass, a "physique factor", previously suggested as the best predictive factor for forced vital capacity in Caucasians, did not account for much of the variation in forced vital capacity between Caucasians and Indians, presumably because it takes no account of differences in chest dimensions.

Respiratory failure and sleep in neuromuscular disease

Sleep hypoxaemia in non-rapid eye movement (non-REM) and rapid eye movement (REM) sleep was examined in 20 patients with various neuromuscular disorders with reference to the relation between oxygen desaturation during sleep and daytime lung and respiratory muscle function. All the patients had all night sleep studies performed and maximum inspiratory and expiratory mouth pressures (PI and Pemax), lung volumes, single breath transfer coefficient for carbon monoxide (KCO), and daytime arterial oxygen (PaO2) and carbon dioxide tensions (PaCO2) determined. Vital capacity in the erect and supine posture was measured in 14 patients. Mean (SD) PI max at RV was low at 33 (19) cm H2O (32% predicted). Mean PE max at TLC was also low at 53 (24) cm H2O (28% predicted). Mean daytime PaO2 was 67 (16) mm Hg and PaCO2 52 (13) mm Hg (8.9 (2.1) and 6.9 (1.7) kPa). The mean lowest arterial oxygen saturation (SaO2) was 83% (12%) during non-REM and 60% (23%) during REM sleep. Detailed electromyographic evidence in one patient with poliomyelitis showed that SaO2% during non-REM sleep was maintained by accessory respiratory muscle activity. There was a direct relation between the lowest SaO2 value during REM sleep and vital capacity, daytime PaO2, PaCO2, and percentage fall in vital capacity from the erect to the supine position (an index of diaphragm weakness). The simple measurement of vital capacity in the erect and supine positions and arterial blood gas tensions when the patient is awake provide a useful initial guide to the degree of respiratory failure occurring during sleep in patients with neuromuscular disorders. A sleep study is required to assess the extent of sleep induced respiratory failure accurately.

Stratification of inspired air in the elongated lungs of the carpet python, Morelia spilotes variegata

Using lung gas tensions via a triple lumen catheter to monitor ventilation distribution (VA) and radioactive techniques to study blood flow distribution (Q), the distribution of ventilation to perfusion ration (VA/Q) was studied in the elongated alveolar lung of the Carpet Python, Morelia spilotes variegata. In the resting, sleeping and agitated states both alveolar oxygen (PAO2) and carbon dioxide tensions (PACO2) were 'stratified' (unevenly distributed) within the alveolar lungs at end inspiration, during breath holding for up to 6 minutes and, when VA was low, at end expiration. The blood flow was also stratified. The degree of stratification of VA was influenced by the rate and depth of breathing and the length of the breath hold which preceeded the gas sampling. Similar results were obtained with a glass lung model. In both resting and sleeping states VA/Q ratios were similar over the proximal 75% of the alveolar lungs whereas VA nearly always exceeded Q over the distal 25%. The anatomic features of the lung are proposed as a possible mechanism for maintaining a uniform VA/Q distribution. Since the anatomical arrangement places the heart at the apical regions of the lungs, absence of cardiac mixing, combined with low respiratory rates, enables stratification to continue for very long periods within the aveolar lungs of the snake.