The acute effects of biatrial pacing on atrial depolarization and repolarization.

Permanent biatrial and/or multisite atrial pacing may prevent atrial fibrillation (AF), but the effects on atrial electrophysiology remain incompletely understood. Acute biatrial pacing was studied in 20 patients with and 28 without (controls) a history of atrial fibrillation and/or flutter. Twelve-lead electrocardiograms were recorded during pacing from the high right atrium (RA), from the distal coronary sinus (LA), and biatrial pacing. P wave duration was measured in each lead and the difference between maximum and minimum P duration was termed P wave dispersion. Effective refractory periods (ERPs) were measured during each pacing mode. The dispersion of P wave duration was 35 +/- 14 ms in controls and 40 +/- 29 ms in AF patients (P = 0.17). Compared to RA pacing, LA pacing shortened P duration in controls (127 +/- 18 to 107 +/- 16 ms, P < 0.05) and biatrial pacing markedly shortened P duration in controls (127 +/- 18 to 93 +/- 14 ms, P < 0.05) and AF patients (114 +/- 43 to 97 +/- 21 ms, P < 0.05). P wave dispersion was unaffected. In controls, the LA ERP was longer than the RA ERP. This phenomenon was not present in AF patients, whose LA ERP was shorter than that of controls. Biatrial pacing had no effect on atrial ERPs or the dispersion of atrial refractoriness. In conclusion, acute biatrial pacing does not affect atrial repolarization but it does cause a marked shortening of global biatrial depolarization. Distal coronary sinus pacing produces a shorter P wave than RA pacing. There is substantial dispersion in the surface P wave of the electrocardiogram, the significance of which awaits further study.

Identification of a peptide toxin from Grammostola spatulata spider venom that blocks cation-selective stretch-activated channels.

We have identified a 35 amino acid peptide toxin of the inhibitor cysteine knot family that blocks cationic stretch-activated ion channels. The toxin, denoted GsMTx-4, was isolated from the venom of the spider Grammostola spatulata and has <50% homology to other neuroactive peptides. It was isolated by fractionating whole venom using reverse phase HPLC, and then assaying fractions on stretch-activated channels (SACs) in outside-out patches from adult rat astrocytes. Although the channel gating kinetics were different between cell-attached and outside-out patches, the properties associated with the channel pore, such as selectivity for alkali cations, conductance ( approximately 45 pS at -100 mV) and a mild rectification were unaffected by outside-out formation. GsMTx-4 produced a complete block of SACs in outside-out patches and appeared specific since it had no effect on whole-cell voltage-sensitive currents. The equilibrium dissociation constant of approximately 630 nM was calculated from the ratio of association and dissociation rate constants. In hypotonically swollen astrocytes, GsMTx-4 produces approximately 40% reduction in swelling-activated whole-cell current. Similarly, in isolated ventricular cells from a rabbit dilated cardiomyopathy model, GsMTx-4 produced a near complete block of the volume-sensitive cation-selective current, but did not affect the anion current. In the myopathic heart cells, where the swell-induced current is tonically active, GsMTx-4 also reduced the cell size. This is the first report of a peptide toxin that specifically blocks stretch-activated currents. The toxin affect on swelling-activated whole-cell currents implicates SACs in volume regulation.

Rabbit ventricular myocyte volume changes as a direct result of crystalloid cardioplegia in congestive heart failure induced by aortic regurgitation.

OBJECTIVES: We hypothesized that the cell volume of ventricular myocytes isolated from hearts in volume-overload congestive failure would respond differently to hypothermic cardioplegia than would sham-operated cohorts. METHODS: Adult rabbits underwent either valvotomy and aortic regurgitation-induced heart failure or sham surgery. Congestive failure was confirmed clinically and by means of echocardiography. Cell volumes of isolated myocytes were measured by digital video microscopy. After equilibration in 37 degrees C physiologic solution, cells were suprafused with 9 degrees C standard or low-Cl(-) St Thomas' Hospital solution followed by reperfusion in 37 degrees C physiologic solution. RESULTS: Exposure to cold St Thomas' Hospital solution for 20 minutes caused sham myocytes to swell by 8% (n = 9); cell volumes fully recovered on normothermic reperfusion. In contrast, congestive failure myocytes (n = 9) maintained their cell volume in cold St Thomas' Hospital solution and during reperfusion. Lowering the [K(+)][Cl(-)] product of St Thomas' Hospital solution by partially replacing Cl(-) with an impermeant anion prevented cellular edema in the sham group (n = 8) but caused a 4% swelling in failure myocytes (n = 10) on reperfusion. Osmotically shrinking the failure cells (n = 9) converted their behavior to that of sham cells. CONCLUSIONS: In the absence of ischemia, congestive failure myocytes are less sensitive to cardioplegia-induced edema than sham cells. Low-Cl(-) cardioplegia, which prevents edema and protects the normal heart, induced swelling and may be detrimental in myopathic hearts. Differences in volume regulation in failure and sham myocytes may be due to activation of volume-sensitive channels that are turned off by osmotic shrinkage.

Induction of ventricular fibrillation by T wave shocks: observations from monophasic action potential recordings.

INTRODUCTION: Shocks given during the vulnerable period of cardiac repolarization may induce ventricular fibrillation (VF). However, the relationship of the vulnerable period and the monophasic action potential (MAP) has not yet been reported in humans. The purpose of this study was, therefore, to determine how the monophasic action potential recorded from the right ventricle correlates with inducibility of VF using T wave shocks during ventricular pacing. METHODS: Eleven patients undergoing implantable cardioverter defibrillator (ICD) implantation had a MAP catheter positioned in the right ventricle (RV). The local monophasic action potential duration at 90% repolarization (MAP90) duration was measured during pacing at 400 ms. VF induction was attempted by pacing at 400 ms for 10 cycles and then giving a 1.0 joule monophasic T wave shock at varying coupling intervals (CI) to the last paced stimulus. The maximum and minimum CI that induced VF were determined and mapped in relation to the MAP90 recording. RESULTS: The average paced MAP duration was 275 +/- 20 ms. The minimum and maximum CI to induce VF were 255 +/- 24 ms and 325 +/- 36 ms respectively. This ranged from 93% to 118% of the MAP90 duration but because of delay in conduction time to the MAP catheter, shocks that induced ventricular fibrillation occurred between 74% and 99% of local repolarization time. CONCLUSION: VF is inducible with low energy T wave shocks falling during the last 25% of the right ventricular MAP90 recording. This corresponds with VF initiation during phase III repolarization.

Age-related effects of St Thomas' Hospital cardioplegic solution on isolated cardiomyocyte cell volume.

OBJECTIVES: We tested the hypothesis that neonatal cells are more sensitive to cardioplegia-induced cell swelling than more mature cells and spontaneous swelling in the absence of ischemia can be prevented by cardioplegia with a physiologic KCl product. METHODS: Cell volumes of isolated ventricular myocytes from neonatal (3-5 days), intermediate (10-13 days), and adult (>6 weeks) rabbits were measured by digital video microscopy. After equilibration in 37 degrees C physiologic solution, cells were suprafused with 37 degrees C or 9 degrees C St Thomas' Hospital solution (standard or low Cl(-)) or 9 degrees C physiologic solution followed by reperfusion with 37 degrees C physiologic solution. RESULTS: Neonatal cells swelled 16.2% +/- 1.8% (P <.01) in 37 degrees C St Thomas' Hospital solution and recovered during reperfusion, whereas more mature cells maintained constant volume. In contrast, 9 degrees C St Thomas' Hospital solution caused significant age-dependent swelling (neonatal, 16.8% +/- 1.5%; intermediate, 8.6% +/- 2.1%; adult, 5.6% +/- 1.1%). In contrast to more mature cells, neonatal cells remained significantly edematous throughout reperfusion (8.1% +/- 1.5%). Swelling was not due to hypothermia because 9 degrees C physiologic solution did not affect volume. Lowering the KCl product of St Thomas' Hospital solution by partially replacing Cl(-) with an impermeant anion prevented cellular edema in all groups. CONCLUSION: In the absence of ischemia, neonatal cells were more sensitive to cardioplegia-induced cellular edema than more mature cells, and edema observed in all groups was avoided by decreasing the KCl product of St Thomas' Hospital solution to the physiologic range. Differences in cell volume regulation may explain the sensitivity of neonatal hearts to hyperkalemic cardioplegic arrest and suggest novel approaches to improving myocardial protection.

Swelling-activated chloride current is persistently activated in ventricular myocytes from dogs with tachycardia-induced congestive heart failure.

The hypothesis that cellular hypertrophy in congestive heart failure (CHF) modulates mechanosensitive (ie, swelling- or stretch-activated) anion channels was tested. Digital video microscopy and amphotericin-perforated-patch voltage clamp were used to measure cell volume and ion currents in ventricular myocytes isolated from normal dogs and dogs with rapid ventricular pacing-induced CHF. In normal myocytes, osmotic swelling in 0.9T to 0.6T solution (T, relative osmolarity; isosmotic solution, 296 mOsmol/L) was required to elicit ICl,swell, an outwardly rectifying swelling-activated Cl- current that reversed near -33 mV and was inhibited by 1 mmol/L 9-anthracene carboxylic acid (9AC), an anion channel blocker. Block of ICl,swell by 9AC simultaneously increased the volume of normal cells in hyposmotic solutions by up to 7%, but 9AC had no effect on volume in isosmotic or hyperosmotic solutions. In contrast, ICl,swell was persistently activated under isosmotic conditions in CHF myocytes, and 9AC increased cell volume by 9%. Osmotic shrinkage in 1.1T to 1.5T solution inhibited both ICl,swell and 9AC-induced cell swelling in CHF cells, whereas osmotic swelling only slightly increased ICl,swell. The current density for fully activated 9AC-sensitive ICl,swell was 40% greater in CHF than normal myocytes. In both groups, 9AC-sensitive current and 9AC-induced cell swelling were proportional with changes in osmolarity and 9AC concentration, and the effects of 9AC on current and volume were blocked by replacing bath Cl- with methanesulfonate. CHF thus altered the set point and magnitude of ICl,swell and resulted in its persistent activation. We previously observed analogous regulation of mechanosensitive cation channels in the same CHF model. Mechanosensitive anion and cation channels may contribute to the electrophysiological and contractile derangements in CHF and may be novel targets for therapy.

Persistent activation of a swelling-activated cation current in ventricular myocytes from dogs with tachycardia-induced congestive heart failure.

The hypothesis that cellular hypertrophy in congestive heart failure (CHF) modulates mechanosensitive (ie, swelling- or stretch-activated) channels was tested. Digital video microscopy and amphotericin-perforated-patch voltage clamp were used to measure cell volume and ion currents in ventricular myocytes isolated from normal dogs and dogs with rapid ventricular pacing-induced CHF. In normal myocytes, osmotic swelling in 0.9x to 0.6x isosmotic solution (296 mOsm/L) was required to elicit an inwardly rectifying swelling-activated cation current (I(Cir,swell)) that reversed near -60 mV and was inhibited by 10 micromol/L Gd3+, a mechanosensitive channel blocker. Block of I(Cir,swell) by Gd3+ simultaneously reduced the volume of normal cells in hyposmotic solutions by up to approximately 10%, but Gd3+ had no effect on volume in isosmotic solution. In contrast, I(Cir,swell) was persistently activated under isosmotic conditions in CHF myocytes, and Gd3+ decreased cell volume by approximately 8%. Osmotic shrinkage in 1.1x to 1.5x isosmotic solution inhibited both I(Cir,swell) and Gd3+-induced cell shrinkage in CHF cells, whereas osmotic swelling only slightly increased I(Cir,swell). The K0.5 and Hill coefficient for Gd3+ block of I(Cir,swell) and Gd3+-induced cell shrinkage were estimated as approximately 2.0 micromol/L and approximately 1.9, respectively, for both normal and CHF cells. In both groups, the effects of Gd3+ on current and volume were blocked by replacing bath Na+ and K+ and were linearly related with varying Gd3+ concentration and the degree of cell swelling. CHF thus altered the set point for and caused persistent activation of I(Cir,swell). This current may contribute to dysrhythmias, hypertrophy, and altered contractile function in CHF and may be a novel target for therapy.

Using gadolinium to identify stretch-activated channels: technical considerations.

Gadolinium (Gd3+) blocks cation-selective stretch-activated ion channels (SACs) and thereby inhibits a variety of physiological and pathophysiological processes. Gd3+ sensitivity has become a simple and widely used method for detecting the involvement of SACs, and, conversely, Gd3+ insensitivity has been used to infer that processes are not dependent on SACs. The limitations of this approach are not adequately appreciated, however. Avid binding of Gd3+ to anions commonly present in physiological salt solutions and culture media, including phosphate- and bicarbonate-buffered solutions and EGTA in intracellular solutions, often is not taken into account. Failure to detect an effect of Gd3+ in such solutions may reflect the vanishingly low concentrations of free Gd3+ rather than the lack of a role for SACs. Moreover, certain SACs are insensitive to Gd3+, and Gd3+ also blocks other ion channels. Gd3+ remains a useful tool for studying SACs, but appropriate care must be taken in experimental design and interpretation to avoid both false negative and false positive conclusions.

Intravenous amiodarone for acute heart rate control in the critically ill patient with atrial tachyarrhythmias.

Control of heart rate in critically ill patients who develop atrial fibrillation or atrial flutter can be difficult. Amiodarone may be an alternative agent for heart rate control if conventional measures are ineffective. We retrospectively studied intensive care unit patients (n = 38) who received intravenous amiodarone for heart rate control in the setting of hemodynamically destabilizing atrial tachyarrhythmias resistant to conventional heart rate control measures. Atrial fibrillation was present in 33 patients and atrial flutter in 5 patients. Onset of rapid heart rate (mean 149 +/- 13 beats/min) was associated with a decrease in systolic blood pressure of 20 +/- 5 mm Hg (p <0.05). Intravenous diltiazem (n = 34), esmolol (n = 4), or digoxin (n = 24) had no effect on heart rate, while reducing systolic blood pressure by 6 +/- 4 mm Hg (p <0.05). The infusion of amiodarone (242 +/- 137 mg over 1 hour) was associated with a decrease in heart rate by 37 +/- 8 beats/min and an increase in systolic blood pressure of 24 +/- 6 mm Hg. Both of these changes were significantly improved (p <0.05) from onset of rapid heart rate or during conventional therapy. Beneficial changes were also noted in pulmonary artery occlusive pressure and cardiac output. There were no adverse effects secondary to amiodarone therapy. Intravenous amiodarone is efficacious and hemodynamically well tolerated in the acute control of heart rote in critically ill patients who develop atrial tachyarrhythmias with rapid ventricular response refractory to conventional treatment. Cardiac electrophysiologic consultation should be obtained before using intravenous amiodarone for this purpose.

Swelling-activated Gd3+-sensitive cation current and cell volume regulation in rabbit ventricular myocytes.

The role of swelling-activated currents in cell volume regulation is unclear. Currents elicited by swelling rabbit ventricular myocytes in solutions with 0.6-0.9x normal osmolarity were studied using amphotericin perforated patch clamp techniques, and cell volume was examined concurrently by digital video microscopy. Graded swelling caused graded activation of an inwardly rectifying, time-independent cation current (ICir,swell) that was reversibly blocked by Gd3+, but ICir,swell was not detected in isotonic or hypertonic media. This current was not related to IK1 because it was insensitive to Ba2+. The PK/PNa ratio for ICir,swell was 5.9 +/- 0.3, implying that inward current is largely Na+ under physiological conditions. Increasing bath K+ increased gCir,swell but decreased rectification. Gd3+ block was fitted with a K0.5 of 1.7 +/- 0.3 microM and Hill coefficient, n, of 1.7 +/- 0.4. Exposure to Gd3+ also reduced hypotonic swelling by up to approximately 30%, and block of current preceded the volume change by approximately 1 min. Gd3+-induced cell shrinkage was proportional to ICir,swell when ICir,swell was varied by graded swelling or Gd3+ concentration and was voltage dependent, reflecting the voltage dependence of ICir,swell. Integrating the blocked ion flux and calculating the resulting change in osmolarity suggested that ICir,swell was sufficient to explain the majority of the volume change at -80 mV. In addition, swelling activated an outwardly rectifying Cl- current, ICl,swell. This current was absent after Cl- replacement, reversed at ECl, and was blocked by 1 mM 9-anthracene carboxylic acid. Block of ICl,swell provoked a 28% increase in swelling in hypotonic media. Thus, both cation and anion swelling-activated currents modulated the volume of ventricular myocytes. Besides its effects on cell volume, ICir,swell is expected to cause diastolic depolarization. Activation of ICir, swell also is likely to affect contraction and other physiological processes in myocytes.

Ethylene oxide on electrophysiology catheters following resterilization: implications for catheter reuse.

Reuse of electrophysiology catheters is an important cost-saving option for many laboratories. However, to be reused safely, catheters must undergo resterilization with ethylene oxide (EtO). Residual EtO levels on resterilized catheters may be high and could pose a risk to patients. Resterilized diagnostic electrophysiology catheters were tested for residual EtO using headspace gas chromatography after both a standard resterilization with an aeration process and after a resterilization process that incorporated a detoxification period. The Food and Drug Administration's maximum permissible level of EtO for implantable products, 25 parts per million (ppm), was used as the cutoff for acceptable catheter residuals. At day 2 after standard resterilization, the residual level of EtO on catheters was high at 41 +/- 6 ppm. However, these levels decreased with shelf time, decreasing to 26 +/- 3 ppm by day 7 and to 14 +/- 2 ppm by day 14 after sterilization, at which time all catheters were <25 ppm (p <0.001). Detoxification periods of 6, 12, and 15 hours were tested and 15 hours was found to be optimal. After 15 hours of detoxification, residual EtO was 19 +/- 1 ppm by day 2 and all catheters were <25 ppm. In summary, electrophysiology catheters that have undergone resterilization have residual EtO levels that are twice the Food and Drug Administration's limit for implantable products. Residual EtO levels may be substantially reduced either by allowing a 14-day waiting period after resterilization or by incorporating a detoxification period immediately after EtO exposure.

Efficacy of ibutilide for termination of atrial fibrillation and flutter.

The clinical utility of ibutilide fumarate (Corvert) for the acute conversion of atrial tachyarrhythmias to normal sinus rhythm has been demonstrated in several randomized, placebo-controlled clinical trials. The efficacy of intravenous ibutilide for rapid conversion of atrial flutter is in the range of 50-70%, whereas its efficacy for conversion of atrial fibrillation is 30-50%. Approximately 80% of atrial tachyarrhythmias that terminate do so within 30 minutes from the initiation of the intravenous infusion. Ibutilide is more effective than either intravenous procainamide or intravenous sotalol for conversion of atrial fibrillation and atrial flutter to sinus rhythm. Age, presence of structural heart disease, gender and concomitant medication do not appear to influence the efficacy of ibutilide; however, shorter duration of atrial fibrillation is a strong predictor of successful termination. Plasma concentration of ibutilide and QTc interval prolongation are not directly correlated with the success rate for conversion of atrial tachyarrhythmias. Ibutilide's greater efficacy compared with other antiarrhythmic drugs may be related to its ability to cause greater prolongation of atrial monophasic action potential duration relative to atrial cycle length. Termination of atrial flutter with ibutilide was preceded by increased atrial cycle length variability. Ibutilide rapidly and effectively converts atrial fibrillation and atrial flutter to sinus rhythm when administered as a 1-mg total dose followed by a second 1-mg dose. It should be used in conjunction with continuous electrocardiographic monitoring for at least 4 hours after the termination of the infusion, or until the QTc interval returns to baseline. Hypokalemia and hypomagnesemia should be corrected before the start of the infusion. An external cardiac defibrillator, intravenous magnesium, and an external transcutaneous cardiac pacemaker should be readily available for immediate use in the event that palymorphic ventricular tachyarrhythmias occur. Ibutilide is a new intravenous agent that safely and rapidly converts atrial fibrillation and atrial flutter to sinus rhythm.

Atrial natriuretic peptide and cardiac electrophysiology: autonomic and direct effects.

Atrial natriuretic peptide (ANP) has varied effects on cardiac electrophysiologic parameters including heart rate, intraatrial conduction time, and refractory period. ANP's vagoexcitatory and sympathoinhibitory actions as well as its direct actions on cardiac ion currents may be responsible for some of these effects. This review discusses the role of ANP in cardiac electrophysiology, its interactions with the autonomic nervous system and baroreceptor reflex, and its effects on cardiac ion currents.

cGMP and atrial natriuretic factor regulate cell volume of rabbit atrial myocytes.

Atrial natriuretic factor (ANF) reduces the volume of atrial myocytes by inhibiting Na+/K+/2Cl- cotransport. We determined the role of cGMP and cAMP in ANF-induced shrinkage by using digital video microscopy to measure cell volume; volumes are reported relative to control. ANF (1 mumol/L) reversibly reduced atrial cell volume from 1.0 to 0.915 +/- 0.005 (mean +/- SEM). This effect was mimicked by 10 mumol/L 8-bromo-cGMP (8-Br-cGMP), which decreased myocyte volume to 0.894 +/- 0.007 with an ED50 of 0.99 +/- 0.05 mumol/L. In contrast, 100 mumol/L 8-bromo-cAMP (8-Br-cAMP) did not affect volume, and activating the cAMP pathway with 100 mumol/L 8-Br-cAMP did not alter the volume decrease caused by 8-Br-cGMP or ANF. Inhibition of Na+/K+/2Cl- cotransport with bumetanide (1 mumol/L) also reduced cell volume and prevented further shrinkage on subsequent exposure to 8-Br-cGMP. Similarly, 8-Br-cGMP (10 mumol/L) prevented further shrinkage by ANF. Block of Na(+)-H+ exchange, a participant in volume regulation in other cells, did not alter the response to 8-Br-cGMP. More evidence implicating cGMP was obtained by altering its metabolism. LY83583 (10 mumol/L), a guanylate cyclase inhibitor, blocked ANF-induced cell shrinkage. Zaprinast (100 mumol/L), a cGMP-specific phosphodiesterase inhibitor, markedly potentiated the effect of a threshold concentration of ANF (0.01 mumol/L). The actions of ANF, LY83583, and zaprinast on cGMP levels were verified by radioimmunoassay. These data strongly support the idea that the cGMP cascade is the intracellular signaling pathway responsible for ANF-induced atrial cell shrinkage.(ABSTRACT TRUNCATED AT 250 WORDS)

Stretch-activated channel blockers modulate cell volume in cardiac ventricular myocytes.

Stretch-activated channels (SAC) are postulated to regulate cell volume. While this hypothesis is appealing, direct evidence is lacking. Using digital video microscopy, we found that pharmacological blockade of SACs alters the cell volume of isolated rabbit ventricular myocytes during hypoosmotic stress. Under control conditions, relative cell volume increased from 1.0 to 1.311 +/- 0.019 after 10 min in 195 mosmol/l solution. The cation SAC blocker gadolinium (Gd3+; 10 microM) reduced the amount of swelling in hypoosmotic solution by 24% and induced a regulatory volume decrease otherwise not observed. In contrast, the anion SAC blocker 9-anthracene carboxylic acid (9-AC; 1 mM) increased swelling by 44% under the same conditions. Based on the direction of SAC currents, Gd3+ and 9-AC are expected to have opposite effects on cell volume. Furthermore, Gd3+ and 9-AC changed cell volume by only approximately 2% in isosmotic solutions when SACs are expected to be closed. This supports the idea that Gd3+ and 9-AC affect stretch-activated transport processes. In contrast, omitting bath Ca2+ did not alter cell volume under iso- or hypoosmotic conditions suggesting stretch-activated Ca2+ influx is not important in setting cell volume. Not all channels can affect cell volume. Opening ATP-sensitive K+ channels with aprikalim (100 microM) or blocking them with glibenclamide (1 microM) did not alter cell volume under isosmotic or hypoosmotic conditions. These data support the idea that SACs are involved in cardiac cell volume regulation.

Safety of pacemaker implantation in patients with transvenous (nonthoracotomy) implantable cardioverter defibrillators.

While several reports have documented the safety of implantation of transvenous pacemakers in patients with epicardial patch-based implantable cardioverter defibrillators (ICDs), the implantation of transvenous pacemakers in patients with transvenous (nonthoracotomy) ICDs has not been well-described. We present three patients with transvenous ICDs who subsequently underwent implantation of transvenous pacemakers without complication. Technical considerations and a testing, protocol for detection of pacemaker-ICD interactions are discussed.

Modulation of rabbit ventricular cell volume and Na+/K+/2Cl- cotransport by cGMP and atrial natriuretic factor.

Previously we showed that atrial natriuretic factor (ANF) decreases cardiac cell volume by inhibiting ion uptake by Na+/K+/2Cl- cotransport. Digital video microscopy was used to study the role of guanosine 3',5'-monophosphate (cGMP) in this process in rabbit ventricular myocytes. Each cell served as its own control, and relative cell volumes (volume(test)/volume(control)) were determined. Exposure to 10 microM 8-bromo-cGMP (8-Br-cGMP) reversibly decreased cell volume to 0.892 +/- 0.007; the ED50 was 0.77 +/- 0.33 microM. Activating guanylate cyclase with 100 microM sodium nitroprusside also decreased cell volume to 0.889 +/- 0.009. In contrast, 8-bromo-adenosine 3',5'-monophosphate (8-Br-AMP; 0.01-100 microM) neither altered cell volume directly nor modified the response to 8-Br-cGMP. The idea that cGMP decreases cell volume by inhibiting Na+/K+/2Cl- cotransport was tested by blocking the cotransporter with 10 microM bumetanide (BUM) and removing the transported ions. After BUM treatment, 10 microM 8-Br-cGMP failed to decrease cell volume. Replacement of Na+ with N-methyl-D-glucamine or Cl- with methanesulfonate also prevented 8-Br-cGMP from shrinking cells. The data suggest that 8-Br-cGMP, like ANF, decreases ventricular cell volume by inhibiting Na+/K+/2Cl-cotransport. Evidence that ANF modulates cell volume via cGMP was also obtained. Pretreatment with 10 microM 8-Br-cGMP prevented the effect of 1 microM ANF on cell volume, and ANF suppressed 8-Br-cGMP-induced cell shrinkage. Inhibiting guanylate cyclase with the quinolinedione LY83583 (10 microM) diminished ANF-induced cell shrinkage, and inhibiting cGMP-specific phosphodiesterase with M&B22948 (Zaprinast; 100 microM) amplified the volume decrease caused by a low dose of ANF (0.01 microM) approximately fivefold. In contrast, neither 100 microM 8-Br-cAMP nor 50 microM forskolin affected the response to ANF. The effects of ANF, LY83583, and M&B29948 on cGMP levels in isolated ventricular myocytes were confirmed by 125I-cGMP radioimmunoassay. These data argue that ANF shrinks cardiac cells by increasing intracellular cGMP, thereby inhibiting Na+/K+/2Cl- cotransport. Basal cGMP levels also appear to modulate cell volume.

Prevention of myocardial intracellular edema induced by St. Thomas' Hospital cardioplegic solution.

During cardiac surgery, the heart is infused with cold crystalloid cardioplegic solutions such as St. Thomas' Hospital (StT) solution, which contains high concentrations of K+ and Mg2+. The high K+ and Mg2+ block impulse conduction and inhibit Ca2+ influx, thereby arresting the heart and reducing cardiac oxygen consumption. Nevertheless, myocardial edema and post-operative abnormalities have been noted after cardioplegia and attributed to ischemia and reflow or to hypothermia. We found, however, that cold StT (9 degrees C) was hypotonic and induced cell swelling in the absence of ischemic injury. Cell swelling in cold StT was not due to hypothermia alone, but rather was caused by KCl influx and was prevented by partially replacing Cl- with an impermeant anion. After exposure to cold StT, cells transiently shrank to less than control volume on rewarming in physiological saline (Tyrode's solution, 37 degrees C). The transient shrinkage was blocked by ouabain suggesting that Na+ loading of depolarized hypothermic cells and Na(+)-K+ pump activation on rewarming were responsible. Hypothermic ventricular cells seem to follow Donnan equilibrium, and the product of [K+] x [Cl-] in cardioplegic solutions affects cell volume in the absence of ischemic injury.

Atrial natriuretic factor decreases cell volume of rabbit atrial and ventricular myocytes.

The effect of atrial natriuretic factor (ANF) on cell volume was studied using video microscopy of rabbit atrial and ventricular myocytes. Each cell served as its own control, and relative cell volumes were determined. ANF (1 microM) significantly decreased relative cell volume to 0.929 +/- 0.006 (n = 7) in atrial and 0.930 +/- 0.013 (n = 5) in ventricular myocytes (normalized to volume without ANF). Reduction of volume was detectable at greater than or equal to 0.01 microM ANF, and the ED50 was 0.072 +/- 0.007 microM (n = 15). The effect of ANF also was examined under hypotonic (0.55T, 168 mosmol/l) and hypertonic (1.82T, 560 mosmol/l) conditions; osmolarity was adjusted using mannitol with NaCl fixed at 65 mM. In 0.55T, 1 microM ANF decreased cell volume to 0.941 +/- 0.014 (n = 5) in atrial and 0.942 +/- 0.017 (n = 7) in ventricular cells (normalized to 0.55T without ANF). In contrast, 1 microM ANF had no effect on atrial (n = 13) or ventricular (n = 11) cell volume in 1.82T. The hypothesis that ANF decreases cell volume by inhibiting Na(+)-K(+)-2Cl- cotransport was tested by blocking the cotransporter with bumetanide (10 microM). After inhibition of Na(+)-K(+)-2Cl- cotransport, 1 microM ANF failed to reduce cell volume in either atrial (n = 6) or ventricular myocytes (n = 6). Block of ANF-induced cell shrinkage by bumetanide was not due to changes in cell volume, since similar results were obtained using atrial (n = 7) and ventricular (n = 7) cells swollen in hypotonic (0.80T, 244 mosmol/l) solution. Replacement of Na+ with N-methyl-D-glucamine or Cl- with methanesulfonate abolished the ability of both ANF and bumetanide to decrease volume of atrial and ventricular cells in 1T and 0.8T solution. These data suggest that ANF can decrease the volume of atrial and ventricular cells under isotonic and hypotonic conditions by a mechanism that may involve Na(+)-K(+)-2Cl- cotransport. An ANF-induced decrease in cell volume may act as negative feedback and inhibit the stretch-induced release of ANF from atrial and ventricular cells. Furthermore, it may contribute to cell volume maintenance in myocytes in the setting of congestive heart failure or myocardial hypoxia when ANF release is elevated.