scholarly journals Physiological effects of environmental acidification in the deep-sea urchin <i>Strongylocentrotus fragilis</i>

2014 ◽  
Vol 11 (5) ◽  
pp. 1413-1423 ◽  
Author(s):  
J. R. Taylor ◽  
C. Lovera ◽  
P. J. Whaling ◽  
K. R. Buck ◽  
E. F. Pane ◽  
...  
Keyword(s):  
Sea Urchin ◽  
Deep Sea ◽  
Global Climate ◽  
Gonadosomatic Index ◽  
Respiratory Acidosis ◽  
Elevated Pco2 ◽  
Coelomic Fluid ◽  
Acid Base Balance ◽  
Base Balance ◽  
Minimum Zone

Abstract. Anthropogenic CO2 is now reaching depths over 1000 m in the Eastern Pacific, overlapping the Oxygen Minimum Zone (OMZ). Deep-sea animals are suspected to be especially sensitive to environmental acidification associated with global climate change. We have investigated the effects of elevated pCO2 and variable O2 on the deep-sea urchin Strongylocentrotus fragilis, a species whose range of 200–1200 m depth includes the OMZ and spans a pCO2 range of approx. 600–1200 μatm (approx. pH 7.6 to 7.8). Individuals were evaluated during two exposure experiments (1-month and 4 month) at control and three levels of elevated pCO2 at in situ O2 levels of approx. 10% air saturation. A treatment of control pCO2 at 100% air saturation was also included in experiment two. During the first experiment, perivisceral coelomic fluid (PCF) acid-base balance was investigated during a one-month exposure; results show S. fragilis has limited ability to compensate for the respiratory acidosis brought on by elevated pCO2, due in part to low non-bicarbonate PCF buffering capacity. During the second experiment, individuals were separated into fed and fasted experimental groups, and longer-term effects of elevated pCO2 and variable O2 on righting time, feeding, growth, and gonadosomatic index (GSI) were investigated for both groups. Results suggest that the acidosis found during experiment one does not directly correlate with adverse effects during exposure to realistic future pCO2 levels.

scholarly journals Physiological compensation for environmental acidification is limited in the deep-sea urchin <i>Strongylocentrotus fragilis</i>

2013 ◽  
Vol 10 (5) ◽  
pp. 8313-8341 ◽  
Author(s):  
J. R. Taylor ◽  
C. Lovera ◽  
P. J. Whaling ◽  
K. R. Buck ◽  
E. F. Pane ◽  
...  
Keyword(s):  
Sea Urchin ◽  
Deep Sea ◽  
Global Climate ◽  
Gonadosomatic Index ◽  
Extracellular Fluid ◽  
Respiratory Acidosis ◽  
Acid Base Balance ◽  
Bathymetric Range ◽  
Base Balance ◽  
Minimum Zone

Abstract. Anthropogenic CO2 is now reaching depths over 1000 m in the Eastern Pacific, overlapping the Oxygen Minimum Zone (OMZ). Deep-sea animals – particularly, calcifiers – are suspected to be especially sensitive to environmental acidification associated with global climate change. We have investigated the effects of hypercapnia and hypoxia on the deep-sea urchin Strongylocentrotus fragilis, during two long-term exposure experiments (1 month and 4 month) at three levels of reduced pH at in situ O2 levels of approx. 10% saturation, and also to control pH at 100% O2 saturation. During the first experiment, internal acid-base balance was investigated during a one-month exposure; results show S. fragilis has limited ability to compensate for the respiratory acidosis brought on by reduced pH, due in part to low non-bicarbonate extracellular fluid buffering capacity. During the second experiment, longer-term effects of hypercapnia and variable O2 on locomotion, feeding, growth, and gonadosomatic index (GSI) were investigated; results show significant mortality and correlation of all measured parameters with environmental acidification at pH 6.6. Transient adverse effects on locomotion and feeding were seen at pH 7.2, without compromise of growth or GSI. Based on the expected changes in ocean pH and oxygen, results suggest extinction of S. fragilis in the eastern North Pacific is unlikely. Rather, we expect a shoaling and contraction of its bathymetric range.

Acid-base balance and plasma composition in the aestivating lungfish (Protopterus)

1977 ◽  
Vol 232 (1) ◽  
pp. R10-R17 ◽  
Author(s):  
R. G. DeLaney ◽  
S. Lahiri ◽  
R. Hamilton ◽  
P. Fishman
Keyword(s):  
Plasma Osmolality ◽  
Respiratory Acidosis ◽  
Electrolyte Balance ◽  
Plasma Composition ◽  
Total Plasma ◽  
Acid Base Balance ◽  
Acid Base ◽  
Plasma Bicarbonate ◽  
Arterial Ph ◽  
Base Balance

Upon entering into aestivation, Protopterus aethiopicus develops a respiratory acidosis. A slow compensatory increase in plasma bicarbonate suffices only to partially restore arterial pH toward normal. The cessation of water intake from the start of aestivation results in hemoconcentration and marked oliguria. The concentrations of most plasma constituents continue to increase progressively, and the electrolyte ratios change. The increase in urea concentration is disproportionately high for the degree of dehydration and constitutes an increasing fraction of total plasma osmolality. Acid-base and electrolyte balance do not reach a new equilibrium within 1 yr in the cocoon.

Effects of temperature on acid-base balance and ventilation in desert iguanas

1981 ◽  
Vol 51 (2) ◽  
pp. 452-460 ◽  
Author(s):  
P. E. Bickler
Keyword(s):  
Steady State ◽  
Pulmonary Ventilation ◽  
Respiratory Acidosis ◽  
Lung Ventilation ◽  
Acid Base Balance ◽  
Acid Base ◽  
Arterial Ph ◽  
Blood Relative ◽  
Base Balance ◽  
History Of

The effects of constant and changing temperatures on blood acid-base status and pulmonary ventilation were studied in the eurythermal lizard Dipsosaurus dorsalis. Constant temperatures between 18 and 42 degrees C maintained for 24 h or more produced arterial pH changes of -0.0145 U X degrees C-1. Arterial CO2 tension (PCO2) increased from 9.9 to 32 Torr plasma [HCO-3] and total CO2 contents remained constant at near 19 and 22 mM, respectively. Under constant temperature conditions, ventilation-gas exchange ratios (VE/MCO2 and VE/MO2) were inversely related to temperature and can adequately explain the changes in arterial PCO2 and pH. During warming and cooling between 25 and 42 degrees C arterial pH, PCO2 [HCO-3], and respiratory exchange ratios (MCO2/MO2) were similar to steady-state values. Warming and cooling each took about 2 h. During the temperature changes, rapid changes in lung ventilation following steady-state patterns were seen. Blood relative alkalinity changed slightly with steady-state or changing body temperatures, whereas calculated charge on protein histidine imidazole was closely conserved. Cooling to 17-18 degrees C resulted in a transient respiratory acidosis correlated with a decline in the ratio VE/MCO2. After 12-24 h at 17-18 degrees C, pH, PCO2, and VE returned to steady-state values. The importance of thermal history of patterns of acid-base regulation in reptiles is discussed.

The effects of enforced activity on ventilation, circulation and blood acid-base balance in the aquatic gill-less urodele, Cryptobranchus alleganiensis; a comparison with the semi-terrestrial anuran, Bufo marinus

1980 ◽  
Vol 84 (1) ◽  
pp. 289-302
Author(s):  
R. G. Boutilier ◽  
D. G. McDonald ◽  
D. P. Toews
Keyword(s):  
Recovery Period ◽  
Respiratory Acidosis ◽  
Bufo Marinus ◽  
Acid Base Balance ◽  
Acid Base ◽  
Post Exercise ◽  
Arterial Blood ◽  
Cryptobranchus Alleganiensis ◽  
Base Balance ◽  
Lower Magnitude

A combined respiratory and metabolic acidosis occurs in the arterial blood immediately following 30 min of strenuous activity in the predominantly skin-breathing urodele, Cryptobranchus alleganiensis, and in the bimodal-breathing anuran, Bufo marinus, at 25 degrees C. In Bufo, the bulk of the post-exercise acidosis is metabolic in origin (principally lactic acid) and recovery is complete within 4-8 h. In the salamander, a lower magnitude, longer duration, metabolic acid component and a more pronounced respiratory acidosis prolong the recovery period for up to 22 h post-exercise. It is suggested that fundamental differences between the dominant sites for gas exchange (pulmonary versus cutaneous), and thus in the control of respiratory acid-base balance, may underline the dissimilar patterns of recovery from exercise in these two species.

Effects of acute and chronic acetazolamide on resting ventilation and ventilatory responses in men

1993 ◽  
Vol 74 (1) ◽  
pp. 230-237 ◽  
Author(s):  
E. R. Swenson ◽  
J. M. Hughes
Keyword(s):  
Metabolic Acidosis ◽  
Ventilatory Response ◽  
Minute Ventilation ◽  
Respiratory Acidosis ◽  
Acute Effects ◽  
Acid Base Balance ◽  
Ventilatory Control ◽  
Peripheral Chemoreceptor ◽  
Ventilatory Responses ◽  
Base Balance

The effects of acetazolamide (ACTZ) on ventilatory control are thought to be mediated by metabolic acidosis. However, carbonic anhydrase (CA) inhibition within brain and chemoreceptors and tissue respiratory acidosis may also be important. We compared the acute effects of ACTZ (tissue respiratory acidosis and tissue CA inhibition without metabolic acidosis) on ventilation and ventilatory control with chronic ACTZ (acute effects plus metabolic acidosis). Five men were studied 1 h after 500 mg iv ACTZ or 0.9% saline (acute effects) and also after three doses of ACTZ (500 mg po every 6 h; chronic effects). Minute ventilation (VE), steady-state hypercapnic ventilatory response (HCVR), and hypoxic ventilatory response (HVR) were measured with respiratory inductance plethysmography. Resting VE was increased equally by acute and chronic ACTZ. HCVR increased with chronic ACTZ in hyperoxia and even further in hypoxia. In contrast, acute ACTZ had no effect on the HCVR slope in hyperoxia and suppressed its augmentation by hypoxia. HVR was fully suppressed by acute ACTZ but unchanged with chronic ACTZ. ACTZ also slowed the rate of full ventilatory response to CO2. These findings show that CA inhibitors affect ventilatory control in a complex fashion, not only through changes in systemic acid-base balance but also by central and peripheral chemoreceptor inhibition.

Practical Evaluation of Acid-Base Balance

1957 ◽  
Vol 3 (5) ◽  
pp. 631-637
Author(s):  
Herbert P Jacobi ◽  
Anthony J Barak ◽  
Meyer Beber
Keyword(s):  
Respiratory Acidosis ◽  
Respiratory Alkalosis ◽  
Acid Base Balance ◽  
Bicarbonate Concentration ◽  
Acid Base ◽  
Plasma Bicarbonate ◽  
Practical Evaluation ◽  
Base Balance

Abstract The Co2 combining power bears a variable relationship to the in vivo plasma bicarbonate concentration, depending upon the type and severity of acid-base distortion. In respiratory alkalosis and metabolic acidosis the Co2 combining power will usually be greater than the in vivo plasma bicarbonate concentration; whereas, in respiratory acidosis and metabolic alkalosis the Co2 combining power will usually be less. Co2 content, on the other hand, will always parallel the in vivo plasma bicarbonate concentration quite closely, being only slightly greater. These facts, together with other considerations which are discussed, recommend the abandonment of the determination of CO2 combining power.

Effect of systemic acid-base balance on ileal secretion

1987 ◽  
Vol 253 (3) ◽  
pp. G330-G335
Author(s):  
D. S. Goldfarb ◽  
P. M. Ingrassia ◽  
A. N. Charney
Keyword(s):  
Metabolic Acidosis ◽  
Cholera Toxin ◽  
Metabolic Disorders ◽  
Respiratory Acidosis ◽  
Secretory Process ◽  
Sprague Dawley ◽  
Acid Base Balance ◽  
Acid Base ◽  
Ph Change ◽  
Base Balance

We previously reported that systemic pH and HCO3 concentration affect ileal water and electrolyte absorption. To determine whether these effects could influence an ongoing secretory process, we measured transport in ileal loops exposed to either saline or 50-75 micrograms cholera toxin in mechanically ventilated Sprague-Dawley rats anesthetized with pentobarbital sodium. The effects of acute respiratory and metabolic acidosis and alkalosis were then examined. Decreases in systemic pH during respiratory acidosis caused equivalent increases in net water (54 +/- 8 microliters . cm-1 . h-1) and Na absorption (7 +/- 1 mu eq . cm- . h-1) and smaller increases in Cl absorption in cholera toxin compared with saline loops. These increases reversed the net secretion of these ions observed during alkalemia in the cholera toxin loops to net absorption. Metabolic acidosis and alkalosis and respiratory compensation of systemic pH of these metabolic disorders also altered cholera toxin-induced secretion in a direction consistent with the pH change. The increase in net HCO3 secretion caused by cholera toxin was unaffected by the respiratory disorders and did not vary with the HCO3 concentration in the metabolic disorders. These findings suggest that the systemic acid-base disorders that characterize intestinal secretory states may themselves alter intestinal absorptive function and fluid losses.

The use of elements of the Stewart model (Strong Ion Approach) for the diagnostics of respiratory acidosis on the basis of the calculation of a value of a modified anion gap (AGm) in brachycephalic dogs

2015 ◽  
Vol 18 (1) ◽  
pp. 217-222 ◽  
Author(s):  
P. Sławuta ◽  
K. Glińska-Suchocka ◽  
A. Cekiera
Keyword(s):  
Reference Values ◽  
Soft Palate ◽  
Respiratory Acidosis ◽  
Anion Gap ◽  
Correction Procedure ◽  
Acid Base Balance ◽  
Acid Base ◽  
Apparent Lack ◽  
Before And After ◽  
Base Balance

AbstractApart from the HH equation, the acid-base balance of an organism is also described by the Stewart model, which assumes that the proper insight into the ABB of the organism is given by an analysis of: pCO2, the difference of concentrations of strong cations and anions in the blood serum – SID, and the total concentration of nonvolatile weak acids – Acid total. The notion of an anion gap (AG), or the apparent lack of ions, is closely related to the acid-base balance described according to the HH equation. Its value mainly consists of negatively charged proteins, phosphates, and sulphates in blood. In the human medicine, a modified anion gap is used, which, including the concentration of the protein buffer of blood, is, in fact, the combination of the apparent lack of ions derived from the classic model and the Stewart model. In brachycephalic dogs, respiratory acidosis often occurs, which is caused by an overgrowth of the soft palate, making it impossible for a free air flow and causing an increase in pCO2– carbonic acid anhydride The aim of the present paper was an attempt to answer the question whether, in the case of systemic respiratory acidosis, changes in the concentration of buffering ions can also be seen. The study was carried out on 60 adult dogs of boxer breed in which, on the basis of the results of endoscopic examination, a strong overgrowth of the soft palate requiring a surgical correction was found. For each dog, the value of the anion gap before and after the palate correction procedure was calculated according to the following equation: AG = ([Na+mmol/l] + [K+mmol/l]) – ([Cl−mmol/l]+[HCO3−mmol/l]) as well as the value of the modified AG – according to the following equation: AGm= calculated AG + 2.5 × (albuminsr– albuminsd). The values of AG calculated for the dogs before and after the procedure fell within the limits of the reference values and did not differ significantly whereas the values of AGmcalculated for the dogs before and after the procedure differed from each other significantly. Conclusions: 1) On the basis of the values of AGmobtained it should be stated that in spite of finding respiratory acidosis in the examined dogs, changes in ion concentration can also be seen, which, according to the Stewart theory, compensate metabolic ABB disorders 2) In spite of the fact that all the values used for calculation of AGmwere within the limits of reference values, the values of AGmin dogs before and after the soft palate correction procedure differed from each other significantly, which proves high sensitivity and usefulness of the AGmcalculation as a diagnostic method.

Renal regulation of acid-base balance in the bullfrog

1961 ◽  
Vol 201 (6) ◽  
pp. 980-986 ◽  
Author(s):  
Hisato Yoshimura ◽  
Masateru Yata ◽  
Minoru Yuasa ◽  
Robert A. Wolbach
Keyword(s):  
Carbonic Anhydrase ◽  
Ammonia Excretion ◽  
Respiratory Acidosis ◽  
Acid Base Balance ◽  
Acid Base ◽  
Urinary Ph ◽  
Base Balance ◽  
Chloride Excretion ◽  
Acid Load ◽  
Renal Carbonic Anhydrase

Renal mechanisms for the maintenance of acid-base balance were studied in the normal bullfrog, during metabolic and respiratory acidosis, and after carbonic anhydrase inhibition. Following intravenous administration of 0.3–12 mmole HCl/ kg, as 0.1 n HCl, urinary pH (initially pH 6.3–7.7) did not change significantly. However, urinary ammonia excretion increased more than twofold, and within 3–5 days the cumulative increase was equivalent to the acid load given. Despite the increased ammonia excretion, chloride excretion did not increase after acid loading. In both normal and acidotic bullfrogs ammonia excretion was correlated with an increase in urinary pH. Respiratory acidosis in the small frog, Rana limnocharis, produced by exposure to 6.4% CO2 in air, induced neither urinary acidification nor increased ammonia excretion; both urinary sodium and bicarbonate excretion increased. When renal carbonic anhydrase was inhibited by acetazoleamide injection, urine flow, sodium excretion, and bicarbonate excretion increased markedly, urinary pH increased slightly, and urinary ammonia excretion remained unchanged. These renal responses to acidosis are compared with those of the acidotic dog.

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