Urinary CC16 after challenge with dry air hyperpnoea and mannitol in recreational summer athletes.

Airway epithelial injury is regarded as a key contributing factor to the pathogenesis of exercise-induced bronchoconstriction (EIB) in athletes. The concentration of the pneumoprotein club cell (Clara cell) CC16 in urine has been found to be a non-invasive marker for hyperpnoea-induced airway epithelial perturbation. Exercise-hyperpnoea induces mechanical, thermal and osmotic stress to the airways. We investigated whether osmotic stress alone causes airway epithelial perturbation in athletes with suspected EIB. Twenty-four recreational summer sports athletes who reported respiratory symptoms on exertion performed a standard eucapnic voluntary hyperpnoea test with dry air and a mannitol test (osmotic challenge) on separate days. Median urinary CC16 increased from 120 to 310 ρg µmol creatinine(-1) after dry air hyperpnoea (P = 0.002) and from 90 to 191 ρg µmol creatinine(-1) after mannitol (P = 0.021). There was no difference in urinary CC16 concentration between athletes who did or did not bronchoconstrict after dry air hyperpnoea or mannitol. We conclude that, in recreational summer sports athletes with respiratory symptoms, osmotic stress per se to the airway epithelium induces a rise in urinary excretion of CC16. This suggests that hyperosmolarity of the airway surface lining perturbs the airway epithelium in symptomatic athletes.

Compensation for hypercapnia by a euryhaline elasmobranch: effect of salinity and roles of gills and kidneys in fresh water.

Specimens of the euryhaline elasmobranch, Dasyatis sabina were acclimated to seawater and fresh water, and exposed to normocapnic (air) and hypercapnic (1% CO2 in air) environmental water. Blood pH, PCO2, and [HCO3-], as well as whole-animal net-acid excretion, were measured for up to 24 h of hypercapnia. In a separate experimental series, urine was collected from freshwater acclimated stingrays during 8 h of normocapnia and hypercapnia. Stingrays in both salinities at least partially compensated for the respiratory acidosis by accumulating HCO3- in their extracellular spaces. The degree of compensation for blood pH was 88.5% in seawater, but only 31.0% in fresh water after 24 h of hypercapnia. Whole-animal net-acid excretion was also greater in seawater than in fresh water, as was the increase in extracellular fluid [HCO3-]. Mean urinary net-acid excretion rates were slightly negative, and never increased above normocapnic control rates during hypercapnia. Since whole-animal net-acid excretion rates increased with blood [HCO3-], and urinary excretion was always negative, the gills were probably the primary organ responsible for compensation from environmental hypercapnia. The faster, and more complete, compensation for hypercapnia in seawater than in fresh water for this euryhaline elasmobranch is consistent with data for euryhaline teleosts, and probably reflects Na+-dependent mechanisms of branchial acid excretion.

Renal denervation enhances the phosphaturic effect of parathyroid hormone.

Hyperventilation/hypocapnia increases renal phosphate reabsorption and decreases the phosphaturic effect of parathyroid hormone (PTH). Recent studies suggest that the blunted phosphaturic effect of PTH in hyperventilated/hypocapnic rats may be mediated by the stimulation of renal beta-adrenoreceptors. In the present study, no differences in plasma catecholamine levels were detected in hyperventilated/hypocapnic rats as compared to hyperventilated/normocapnic rats. Therefore, studies were performed to determine the role of the renal nerves in the blunted phosphaturic effect of PTH in hyperventilated/hypocapnic rats. In clearance experiments in acutely thyroparathyroidectomized male Sprague-Dawley rats, PTH infusion increased the fractional excretion of phosphate (FEPi) in the denervated left kidney of hyperventilated/hypocapnic rats (n = 8), from 2.4 +/- 1.1 to 18.6 +/- 2.7%, as compared to 1.0 +/- 0.3 to 9.1 +/- 2.1% in the contralateral innervated kidney. Denervation of the left kidney in hyperventilated/normocapnic rats (n = 8) also significantly increased the phosphaturic response to PTH by 2.5 +/- 1.5 to 26.9 +/- 3.0% as compared to 0.9 +/- 0.5 to 18.6 +/- 2.6% in the contralateral innervated kidney. The phosphaturic responses to PTH were similar when comparing the denervated kidney in hyperventilated/hypocapnic rats with the innervated kidney of hyperventilated/normocapnic rats. Thus, renal denervation enhanced the phosphaturic effect of PTH in both hyperventilated/hypocapnic and hyperventilated/normocapnic rats. These results suggest that renal nerves play a role in the modulation of the phosphaturic effect of PTH.

Effect of chronic respiratory acidosis on urinary calcium excretion in the dog.

It is currently believed that the two chronic acidemic disorders exert disparate effects on urinary calcium excretion: chronic metabolic acidosis induces consistent hypercalciuria, but no appreciable change or even a decrease in calcium excretion is reported to attend chronic respiratory acidosis. Whereas the effect of metabolic acidosis is well documented, little work has been carried out in chronic hypercapnia. In fact, most of the studies on chronic respiratory acidosis were short in duration, had employed only mild hypercapnia, or had failed to control carefully the prevailing metabolic conditions. We have carried out balance observations in nine dogs exposed to a 10% CO2 atmosphere in an environmental chamber for a period of two weeks. Chronic respiratory acidosis led to a significant increase in urinary calcium excretion from a mean control value of 0.4 +/- 0.1 mmol/day to 0.6 +/- 0.1 mmol/day during both week 1 and 2 of hypercapnia (P less than 0.05). Hypercalciuria occurred even though filtered load of calcium fell. Mean fractional excretion of calcium increased significantly during each week of hypercapnia averaging 0.60 +/- 0.12% during control, 1.05 +/- 0.13% during week 1, and 1.26 +/- 0.17% during week 2 of hypercapnic exposure (P less than 0.05). There were no changes in plasma levels of immunoreactive parathyroid hormone or 1,25-dihydroxyvitamin D3. These findings suggest that chronic respiratory acidosis, just like chronic metabolic acidosis, augments urinary calcium excretion by a direct depressive effect on the tubular reabsorption of calcium.

Effect of acute hypercapnia on PTH-stimulated phosphaturia in dietary Pi-deprived rat.

The effects of respiratory acidosis on renal inorganic phosphate (Pi) handling are controversial. Clearance experiments, therefore, were performed in fasted, chronically parathyroidectomized (PTX), dietary Pi-deprived rats. The objectives were twofold: to study the effects of compensated and uncompensated hypercapnia per se on renal Pi excretion and to examine the interaction between acute hypercapnia, dietary Pi, and parathyroid hormone (PTH) on the renal handling of Pi. Acute hypercapnia increased the plasma Pi (delta 2.82 +/- 0.65 mg/dl, P less than 0.05) without altering the glomerular filtration rate (GFR). The FEPi increased (delta 7.26 +/- 0.48%, P less than 0.001) but the TRPi/GFR also increased. PTH (3 U X kg-1 X h-1) superimposed on hypercapnia resulted in a plasma Pi comparable to hypercapnia alone. The FEPi (7.56 +/- 0.78 vs. 24.43 +/- 2.20%; P less than 0.001) was higher and the TRPi/GFR (117 +/- 4 vs. 80 +/- 2 micrograms/min, P less than 0.01) lower, in the former group. PTH infusion during normocapnia resulted in a lower FEPi (0.20 +/- 0.10 vs. 24.43 +/- 2.20%, P less than 0.001) and a higher TRPi/GFR (106 +/- 2 vs. 80 +/- 2 micrograms/min, P less than 0.01) compared with PTH infusion during hypercapnia. Urinary adenosine 3',5'-cyclic monophosphate (cAMP) excretion was similar between the groups. During hypercapnia, when the extracellular acidemia was neutralized, the phosphaturic action of PTH persisted. These studies offer direct evidence that in chronically PTX, dietary Pi-deprived rats, the phosphaturic action of PTH is restored by hypercapnia per se. This effect appears to be independent of extracellular acidemia, changes in the plasma Pi and calcium, urinary pH and Na and cAMP excretion.

Renal acidification during chronic hypercapnia in the conscious dog.

Enhanced renal acidification during chronic hypercapnia (CH) results in transient augmentation in net acid excretion (NAE) (adaptation phase) and persistent acceleration in renal bicarbonate reclamation (adaptation and steady-state phases). The mechanisms responsible for the return of NAE to control values despite persistent acidemia during the steady state phase of CH remain undefined. In addition, it remains unsettled whether the enhancement of renal ammoniagenesis known to occur during the adaptation phase of CH persists during the steady-state phase. Furthermore it is uncertain if the alteration in whole-kidney acidification observed in CH originates from augmentation in the acidification of both proximal and distal nephronal segments. To shed further light on these issues, observations on the profile of the urine acid-base moieties during the adaptive and steady-state phases of CH were carried out in dogs chronically exposed to hypercapnia (10% FiCO2) in an environmental chamber (13 days). Additionally, collecting duct hydrogen ion secretion (CDH+S) was evaluated by employing the U-B PCO2 in alkaline urine in intact unanesthetized dogs with either CH (10% FiCO2) or eucapnia. The balance studies demonstrated that NAE increased in early hypercapnia (4.84 meq/kg body weight, control 3.27 meq/kg body weight, p less than 0.05) and returned to baseline thereafter; by contrast, urine NH+4 which was augmented during the adaptation phase (3.71 meq/kg body weight, control 1.97 meq/kg body weight, p less than 0.05) remained elevated throughout (3.25 meq/kg body weight).(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of acute hypercapnia on renal bicarbonate reabsorption in the dog.

The increased plasma bicarbonate concentration seen in hypercapnia implies that tubular bicarbonate reabsorption must be increased in the presence of an elevated Paco2. In contrast to early reports, more recent experimental data in acute hypercapnia have been interpreted to show that the observed increment in tubular reabsorption of bicarbonate factored for glomerular filtration rate (THCO3/GFR) is largely related to the concurrent changes in renal sodium reabsorption and to the increment in the filtered load of bicarbonate, and that acute hypercapnia per se causes little or no change in the tubular handling of bicarbonate. We reexamined this question by observing the changes in renal function occurring in the presence of a moderate elevation of plasma bicarbonate concentration in two groups of dogs. In group I, the elevation occurred as a result of acute hypercapnia during the administration of an "isometric" solution; in group II, it was caused by the infusion of identical amounts of an isotonic solution with the same concentration of sodium as in group I, but a higher bicarbonate concentration, in the presence of eucapnia. A subset of group II provided controls for the decrease in renal perfusion pressure that occurred spontaneously in group I. With increasing filtered loads of bicarbonate, fractional excretion (FE) of HCO3 increased in group II, whereas it dropped markedly in group I. Furthermore, the relative reabsorption rate of HCO3 compared with that of Cl (assessed by changes in fractional reabsorption (FR) of HCO3/Cl) decreased in group II, whereas it increased in group I. Although FENa also decreased in group II, the opposite changes in FR(HCO3/Cl) could not be attributed solely to concurrent changes in sodium handling, indicating that in the presence of acute hypercapnia there is a preferential reabsorption of bicarbonate that tends to perpetuate the increase in plasma bicarbonate concentration. By contrast, THCO3/GFR rose in both groups. The data are interpreted to reveal that acute hypercapnia, although causing a drop in renal perfusion pressure and in natriuresis, also has an additional specific effect on raising preferential bicarbonate reabsorption. This effect can be detected best by monitoring changes in the anionic composition of tubular reabsorbate, whereas it may not be unveiled by following changes in THCO3/GFR. Changes in THCO3/GFR may not yield useful information regarding the integrated response of the kidney to acid-base perturbations, and the conclusions of previous studies based on changes in this parameter must be carefully reexamined.

Relationship of urinary and blood carbon dioxide tension during hypercapnia in the rat. Its significance in the evaluation of collecting duct hydrogen ion secretion.

This study was designed to establish the relationship between urinary pCO2 and systemic blood pCO2 during acute hypercapnia and to investigate the significance of this relationship to collecting duct hydrogen ion (H+) secretion when the urine is acid and when it is highly alkaline. In rats excreting a highly alkaline urine, an acute increase in blood pCO2 (from 42 +/- 0.8 to 87 +/- 0.8 mmHg) resulted in a significant fall in urine minus blood (U-B) pCO2 (from 31 +/- 2.0 to 16 +/- 4.2 mmHg, P less than 0.005), a finding which could be interpreted to indicate inhibition of collecting duct H+ secretion by hypercapnia. The urinary pCO2 of rats with hypercapnia, unlike that of normocapnic controls, was significantly lower than that of blood when the urine was acid (58 +/- 6.3 and 86 +/- 1.7 mmHg, P less than 0.001) and when it was alkalinized in the face of accelerated carbonic acid dehydration by infusion of carbonic anhydrase (78 +/- 2.7 and 87 +/- 1.8 mmHg, P less than 0.02). The finding of a urinary pCO2 lower than systemic blood pCO2 during hypercapnia suggested that the urine pCO2 prevailing before bicarbonate loading should be known and the blood pCO2 kept constant to evaluate collecting duct H+ secretion using the urinary pCO2 technique. In experiments performed under these conditions, sodium bicarbonate infusion resulted in an increment in urinary pCO2 (i.e., a delta pCO2) which was comparable in hypercapnic and normocapnic rats (40 +/- 7.2 and 42 +/- 4.6 mmHg, respectively) that were alkalemic (blood pH 7.53 +/- 0.02 and 7.69 +/- 0.01, respectively). The U-B pCO2, however, was again lower in hypercapnic than in normocapnic rats (15 +/- 4.0 and 39 +/- 2.5 mmHg, respectively, P less than 0.001). In hypercapnic rats in which blood pH during bicarbonate infusion was not allowed to become alkalemic (7.38 +/- 0.01), the delta pCO2 was higher than that of normocapnic rats which were alkalemic (70 +/- 5.6 and 42 +/- 4.6 mmHg, respectively, P less than 0.005) while the U-B pCO2 was about the same (39 +/- 3.7 and 39 +/- 2.5 mmHg). We further examined urine pCO2 generation by measuring the difference between the urine pCO2 of a highly alkaline urine not containing carbonic anhydrase and that of an equally alkaline urine containing this enzyme. Carbonic anhydrase infusion to hypercapnic rats that were not alkalemic resulted in a fall in urine pCO(2) (from 122+/-5.7 to 77+/-2.2 mmHg) which was greater (P <0.02) than that seen in alkalemic normocapnic controls (from 73+/- 1.9 to 43+/-1.3 mmHg) with a comparable urine bicarbonate concentration and urine nonbicarbonate buffer capacity. CO(2) generation, therefore, from collecting dust H(+) secretion and titration of bicarbonate, was higher in hypercapnic rats that in normocapnic controls. We conclude that in rats with actue hypercapnia, the U-B p(CO(2)) achieved during bicarbonate loading greatly underestimates collecting duct H(+) secretion because it is artificially influenced by systemic blood pCO(2). the deltapCO(2) is a better qualitative index of collecting duct H+ secretion that the U-B pCO(2), because it is not artificially influenced by systemic blood pCO(2) and it takes into account the urine PCO(2) prevailing before bicarbonate loading.

Urinary pCO2 as an index of collecting duct hydrogen ion secretion during chronic hypercapnia.

The rise in urinary pCO2 above blood pCO2 which occurs in response to bicarbonate loading (i.e. the urine to blood (U-B) pCO2 gradient), is used with increasing frequency as an index of collecting duct hydrogen ion secretion. We recently proposed, however, that the U-B pCO2 gradient is not an appropriate index of collecting duct hydrogen ion secretion when blood pCO2 is altered acutely. This issue was further investigated by examining the effect of chronic hypercapnia on urinary pCO2 generation. In rats exposed to chronic hypercapnia induced by breathing 10% CO2 for 3 days in an environmental chamber, acute sodium bicarbonate infusion resulted in a U-B pCO2 lower than that of normocapnic control rats (11 +/- 4.6 and 30 +/- 1.8 mm Hg, p less than 0.001). This finding could be interpreted to indicate that collecting duct hydrogen ion secretion is depressed in rats with chronic hypercapnia. The urinary pCO2 of rats with chronic hypercapnia was lower than that of the blood (54 +/- 6.0 and 86 +/- 1.2 mm Hg, p less than 0.005, respectively). In these rats, NaHCO3 infusion, while blood pCO2 was kept constant, elicited a marked rise in urine pCO2 (from 54 +/- 6.0 to 104 +/- 6.0 mm Hg, p less than 0.005) which was not significantly different from that observed in normocapnic control rats. The infusion of carbonic anhydrase resulted in a comparable fall in urine pCO2 in hypercapnic and normocapnic rats (-27 +/- 5 and -30 +/- 3 mm Hg).(ABSTRACT TRUNCATED AT 250 WORDS)

Acute hypercapnic acidosis diminishes renal water excretion in conscious dogs.

The effects of acute hypercapnic acidosis (PaCO2 = 52 +/- 2 mm Hg, pH = 7.23 +/- 0.01) of 40-80 min duration on renal water excretion and circulating vasopressin were examined in conscious dogs during stable diuresis in protocols either with hypotonic water loading (n = 6) or in the euvolemic state (n = 7). The mean arterial pressure increased (p less than 0.05) during acute hypercapnic acidosis in euvolemic dogs, but was unchanged in the dogs given a water load. However, the free water clearance decreased (p less than 0.05), and urine osmolality increased during acute hypercapnic acidosis in both water-loaded and euvolemic dogs despite stable renal hemodynamic function and osmolar clearance. Plasma vasopressin concentrations increased (p less than 0.05) during hypercapnic acidosis in euvolemic but not in water-loaded dogs. The plasma renin activity increased with hypercapnic acidosis in both water loaded and euvolemic dogs. These observations indicate that acute hypercapnic acidosis results in diminished renal water excretion and increased urine osmolality in conscious dogs.

[Urinary excretion of hydroxyproline in patients with chronic respiratory insufficiency (author's transl)]. / Excreción urinaria de hidroxiprolina en pacientes con insuficiencia respiratoria crónica.

The level of urinary excretion of hydroxyproline is considered as an index of the metabolic activity of the collagen. It increases in situations which include an increase in the osteoblastic activity or in the bone resorption. In respiratory insufficiency a series of conditions occur which are theoretically capable of modyfing this parameter. Twelve patients (9 males and 3 women) with chronic respiratory disease in a situation of respiratory insufficiency (hypoxemia and/or hypercapnia at rest) were studied. The urinary excretion of hydroxyproline in these patients was 15.30 +/- 8.16 mg/day/m2, significantly greater than that of a control group with similar characteristics which was 9.97 +/- 3.07 mg/day/m2 (p less than 0.05; Student's t test). The existence of a significant correlation between the urinary excretion of hydroxyproline and the degree of hypoxemia (r = 0.66; p less than 0.01) was likewise verified; in the same way, although to a lesser degree with the hypercapnia (r = 0.62; p less than 0.05). The different factors capable of influencing the bone metabolism in respiratory insufficiency are discussed, as well as the effects of the medications used by these patients. It is possible, on the other hand, that the increase of the urinary excretion of hydroxyproline does not depend only on alterations in the metabolic condition of the bone, but also on a reduction in the hepatic metabolism of the amino acid in relation with gasometric modifications.

Relationship between phosphaluria and acute hypercapnia in the rat.

Standard clearance studies were performed in mechanically ventilated intact and acutely thyroparathyroidectomized (TPTX) rats to document and characterize the effect of hypercapnia (HC) on urinary phosphorus excretion (U(P)V). HC as compared to normocapnia (NC) was associated with an increase in U(P)V in intact (62.5 vs. 7.93 mug/min) and TPTX (30.5 vs. 0.59 mug/min) rats, an increase in filtered load of phosphorus in intact (218 vs. 191 mug/min) and TPTX (243 vs. 146 mug/min) rats, an increase in blood bicarbonate concentration in intact (27.8 vs. 26.0 meq/liter) and TPTX (24.5 vs. 22.3 meq/liter) animals, and a decrease in blood pH in intact (7.15 vs. 7.42) and TPTX (7.07 vs. 7.39) rats. Additional TPTX rats with NC and HC were studied during phosphorus infusion at a comparable filtered load of phosphorus (NC = 307 mug/min and HC = 328 mug/min). U(P)V was 18.5 mug/min in NC and 85.2 mug/min in HC animals. Intact NC animals infused with NaHCO(3) achieved a blood bicarbonate of 45.9 meq/liter compared to 26.0 meq/liter in intact NC NaCl-infused rats. U(P)V was 10.0 mug/min in the NaHCO(3) and 7.93 mug/min in NaCl-infused animals. In intact HC animals infused with NaHCO(3), blood pH was 7.36 compared to 7.42 in NC intact NaCl-infused animals. U(P)V was 83.2 mug/min in the HC bicarbonate-infused and 7.93 mug/min in the NC NaCl-infused rats. These experiments demonstrate that elevated blood carbon dioxide tension per se increases U(P)V. Increases in filtered load of phosphorus and blood bicarbonate which are associated with HC contribute to the phosphaturia as does parathyroid hormone. The phosphaturia is not dependent upon reduction of extracellular pH.