Epr detection of endogenous nitric oxide in postischemic heart using lipid and aqueous-soluble dithiocarbamate-iron complexes

Spin-trapping techniques combined with electron paramagnetic resonance (EPR) spectroscopy to measure nitric oxide (·NO) production were compared in the ischemic-reperfused myocardium for the first time, using both aqueous-soluble and lipophilic complexes of reduced iron (Fe) with dithiocarbamate derivatives. The aqueous-soluble complex of Fe and N-methyl-D-glucamine dithiocarbamate (MGD) formed MGD2-Fe-NO complex with a characteristic triplet EPR signal (a_N12.5 G and g_iso = 2.04) at room temperature, in native isolated rat hearts following 40 min global ischemia and 15 min reperfusion. Diethyldithiocarbamate (DETC) and Fe formed in ischemic-reperfused myocardium the lipophilic DETC2-Fe-NO complex exhibiting an EPR signal (g = 2.04 and g = 2.02 at 77K) with a triplet hyperfine structure at g. Dithiocarbamate-Fe-NO complexes detected by both trapping agents were abolished by the ·NO synthase inhibitor, N^G-nitro-L-arginine methyl ester. Quantitatively, both trapping procedures provi ded similar values for tissue ·NO production, which were observed primarily during ischemia. Postischemic hemodynamic recovery of the heart was not affected by the trapping procedure. (Mol Cell Biochem 175: 91–97, 1997)     

Endotoxin-induced skeletal muscle contractile dysfunction: contribution of nitric oxide synthases

The aims of thisstudy were to assess the role of nitric oxide (NO) and the contributionof different NO synthase (NOS) isoforms in skeletal muscle contractiledysfunction in septic shock. Four groups of conscious rats wereexamined. Group 1 served as control; groups 2, 3, and4 were injected withEscherichia coli endotoxin [lipopolysaccharide (LPS), 20 mg/kg ip] and killed after 6, 12, and 24 h, respectively. Protein expression was assessed byimmunoblotting and immunostaining. LPS injection elicited a transientexpression of the inducible NOS isoform, which peaked 12 h after LPSinjection and disappeared within 24 h. This expression coincided with a significant increase in nitrotyrosine formation (peroxynitrite footprint). Muscle expression of the endothelial and neuronal NOSisoforms, by comparison, rose significantly and remained higher thancontrol levels 24 h after LPS injection. In vitro measurement of musclecontractility 24 h after LPS injection showed that incubation with NOSinhibitor (S-methyliosothiourea)restored the decline in submaximal force generation, whereas maximalmuscle force remained unaffected. We conclude that NO plays asignificant role in muscle contractile dysfunction in septic animalsand that increased NO production is due to induction of the inducibleNOS isoform and upregulation of constitutive NOS isoforms.

     

Detection of nitric oxide in tissue by spin trapping EPR spectroscopy and triacetylglycerol extraction

A modified method based on EPR spin trapping and triacetylglycerol extraction was used for tissue nitric oxide (NO) detection at room temperature. NO signal intensity was stable for about 1.5 h and the detection limit of this method was less than 200 pmol g^–1 tissue. Using this method, we report evidence that NO production in vivo can be inhibited by adriamycin in mice livers.     

Evidence that nitric oxide increases glucose transport in skeletal muscle

Balon, Thomas W., and Jerry L. Nadler. Evidence thatnitric oxide increases glucose transport in skeletal muscle.J. Appl. Physiol. 82(1): 359-363, 1997.Nitric oxide synthase (NOS) is expressed in skeletal muscle.However, the role of nitric oxide (NO) in glucose transport in thistissue remains unclear. To determine the role of NO in modulatingglucose transport, 2-deoxyglucose (2-DG) transport was measured in ratextensor digitorum longus (EDL) muscles that were exposed to either amaximally stimulating concentration of insulin or to an electricalstimulation protocol, in the presence ofN^G-monomethyl-L-arginine,a NOS inhibitor. In addition, EDL preparations were exposed to sodiumnitroprusside (SNP), an NO donor, in the presence of submaximal andmaximally stimulating concentrations of insulin. NOS inhibition reducedboth basal and exercise-enhanced 2-DG transport but had no effect oninsulin-stimulated 2-DG transport. Furthermore, SNP increased 2-DGtransport in a dose-responsive manner. The effects of SNP and insulinon 2-DG transport were additive when insulin was present inphysiological but not in pharmacological concentrations. Chronictreadmill training increased protein expression of both type I and typeIII NOS in soleus muscle homogenates. Our results suggest that NO maybe a potential mediator of exercise-induced glucose transport.

     

In vivo detection of nitric oxide distribution in mice

This paper discusses in vivo detection of nitric oxide (NO) distribution in endotoxin-treated mice using L-band (1.1 GHz) electron paramagnetic resonance spectroscopy (EPR) in combination with the hydrophilic NO trapping complex: N-methyl-D-glucamine dithiocarbamate and iron (MGD-Fe). MGD-Fe-NO complex is found in the upper abdomen (liver region), lower abdomen (kidney and urinary bladder) and head region of ICR mice. Experiments with nitric oxide synthase (NOS) inhibition and ¹⁵N-labeled L-arginine as NOS substrate verify the origin of trapped NO from L-arginine. However, contribution from a 'nonenzymatic' NO generation pathway can not be ruled out. This paper further examines potential artifacts, which may arise in experiments using dithiocarbamate-iron complexes as NO trapping agents.     

Regulation of nitric oxide production in response to skeletal muscle activation

Nitric oxide(NO) is synthesized in normal muscle fibers by the neuronal (nNOS) andthe endothelial (ecNOS) isoforms of nitric oxide synthase (NOS). NOcontributes to the regulation of several processes such asexcitation-contraction coupling and mitochondrial respiration. Weassessed in this study whether NO production is regulated in responseto an acute increase in muscle activation. Three groups ofanesthetized, tracheostomized, spontaneously breathing rats wereexamined after an experimental period of 3 h. Group 1 served as a control (no loading), whereasgroups 2 and3 were exposed to moderate and severeinspiratory resistive loads, respectively, which elicited trachealpressures of 30 and 70% of maximum, respectively. Ventilatory(diaphragm, intercostal, and transverse abdominis) and limb(gastrocnemius) muscles were excised at the end of the experimentalperiod and examined for NOS activity and NOS protein expression.Neither submaximal nor maximum tracheal pressures were altered after 3 h of resistive loading. Diaphragmatic and intercostal muscle NOSactivities declined significantly in response to moderate and severeloading, whereas those of transverse abdominis and gastrocnemiusmuscles remained unchanged. On the other hand, resistive loading had nosignificant effect on ventilatory and limb muscle NOS isoformexpression. We propose that a contraction-induced decline in muscle NOSactivity represents a compensatory mechanism through which musclecontractility and mitochondrial function are protected from theinhibitory influence of NO.

     

beta -Adrenergic regulation of constitutive nitric oxide synthase in cardiac myocytes

Nitric oxide (NO) has been implicated in endogenous control ofmyocardial contractility. However, NO release has not yet been demonstrated in cardiac myocytes. Accordingly, endogenous NO production was measured with a porphyrinic microsensor positioned on the surfaceof individual neonatal or adult rat ventricular myocytes (n > 6 neonatal and adult cells perexperiment). In beating neonatal myocytes, there was no detectablespontaneous NO release with each contraction. However, norepinephrine(NE; 0.25-1 µM) elicited transient NO release from beatingneonatal (149 ± 11 to 767 ± 83 nM NO) and noncontracting adult(157 ± 13 to 791 ± 89 nM NO) cells. NO was released byadrenergic agonists with the following rank order of potency:isoproterenol(₁₂) > NE (/₁) > dobutamine (₁)  epinephrine(/₁₂) > tertbutylene (₂); NO wasnot released by phenylephrine (). NE-evoked NO release wasreversibly blocked byN^G-monomethyl-L-arginine,trifluoperazine, guanosine5'-O-(2-thiodiphosphate), andnifedipine but was enhanced by 3-isobutyl-1-methylxanthine (0.5 mM = 14.5 ± 1.6%) and BAY K 8644 (10 µM = 11.9 ± 1%). NO wasalso released by A-23187 (10 µM = 884 ± 88 nM NO), guanosine 5'-O-(3-thiotriphosphate) (1 µM = 334 ± 56 nMNO), and dibutyryl adenosine 3',5'-cyclic monophosphate(10-100 µM = 35 ± 9 to 284 ± 49 nM NO) but not by ATP,bradykinin, carbachol, 8-bromoguanosine 3',5'-cyclicmonophosphate, or shear stress. This first functional demonstration ofa constitutive NO synthase in cardiac myocytes suggests its regulationby a -adrenergic signaling pathway and may provide a novel mechanismfor the coronary artery vasodilatation and enhanced diastolicrelaxation observed with adrenergic stimulation.

     

Expression of nitric oxide synthase isoforms in normal ventilatory and limb muscles

Hussain, Sabah N. A., Qasim El-Dwairi, Mohammed N. Abdul-Hussain, and Dalia Sakkal. Expression of nitric oxidesynthase isoforms in normal ventilatory and limb muscles.J. Appl. Physiol. 83(2): 348-353, 1997.Nitric oxide (NO), an important messenger molecule withwidespread actions, is synthesized by NO synthases (NOS). In thisstudy, we investigated the correlation between fiber type and NOSactivity among ventilatory and limb muscles of various species. We alsoassessed the presence of the three NOS isoforms in normal skeletalmuscles and how various NOS inhibitors influence muscle NOS activity.NOS activity was detected in various muscles; however, NOS activity inrabbits and rats varied significantly among different muscles.Immunoblotting of muscle samples indicated the presence of both theneuronal NOS and the endothelial NOS isoforms but not thecytokine-inducible NOS isoform. However, these isoforms were expressedto different degrees in various muscles. Although the neuronal NOSisoform was detectable in the canine diaphragm, very weak expressionwas detected in rabbit, rat, and mouse diaphragms. The endothelial NOSisoform was detected in the rat and mouse diaphragms but not in thecanine and rabbit diaphragms. We also found thatN^G-nitro-L-arginine methyl ester,7-nitroindazole, andS-methylisothiourea werestronger inhibitors of muscle NOS activity than was aminoguanidine. These results indicate the presence of different degrees ofconstitutive NOS expression in normal ventilatory and limb muscles ofvarious species. Our data also indicate that muscle NOS activity is not determined by fiber type distribution but by other not yet identified factors. The functional significance of this expression remains to beassessed.

     

Inhaled nitric oxide prevents left ventricular impairment during endotoxemia

We evaluated theeffect of long-term inhalation of nitric oxide (NO) on cardiaccontractility after endotoxemia by using the end-systolicelastance of the left ventricle (LV) as a load-independent contractility index. Chronic instrumentation in 12 pigs included implantation of two pairs of endocardial dimension transducers tomeasure LV volume and a micromanometer to measure LV pressure. One weeklater, the animals were divided into a control group (n = 6) or a NO group(n = 6). All animals receivedintravenous Escherichia coliendotoxin (10 µg · kg¹ · h¹)and equivalent lactated Ringer solution. NO inhalation (20 parts/million) was begun 30 min after the initiation of endotoxemia andwas continued for 24 h. In both groups, tachycardia, pulmonaryhypertension, and systemic hyperdynamic changes were noted. Theend-systolic elastance in the control group was significantly decreasedbeyond 7 h. NO inhalation maintained the end-systolic elastance atbaseline levels and prevented its impairment. These findings indicatethat NO exerts a protective effect on LV contractility in this model of endotoxemia.

     

Role of inhibition of nitric oxide production in monocrotaline-induced pulmonary hypertension

Mathew, Rajamma, Elizabeth S. Gloster, T. Sundararajan, Carl I. Thompson, Guillermo A. Zeballos, andMichael H. Gewitz. Role of inhibition of nitric oxide productionin monocrotaline-induced pulmonary hypertension. J. Appl. Physiol. 82(5): 1493-1498, 1997.Monocrotaline (MCT)-induced pulmonary hypertension (PH) isassociated with impaired endothelium-dependent nitric oxide(NO)-mediated relaxation. To examine the role of NO in PH,Sprague-Dawley rats were given a single subcutaneous injection ofnormal saline [control (C)], 80 mg/kg MCT, or the same doseof MCT and a continuous subcutaneous infusion of 2 mg · kg¹ · day¹of molsidomine, a NO prodrug (MCT+MD). Two weeks later, plasma NO₃ levels, pulmonary arterialpressure (Ppa), ratio of right-to-left ventricular weights (RV/LV) toassess right ventricular hypertrophy, and pulmonary histology wereevaluated. The plasma NO₃ level inthe MCT group was reduced to 9.2 ± 1.5 µM(n = 12) vs. C level of 17.7 ± 1.8 µM (n = 8; P < 0.02). In the MCT+MD group,plasma NO₃ level was 12.3 ± 2.0 µM (n = 8). Ppa and RV/LV in theMCT group were increased compared with C [Ppa, 34 ± 3.4 mmHg(n = 6) vs. 19 ± 0.8 mmHg(n = 8) and 0.41 ± 0.01 (n = 9) vs. 0.25 ± 0.008 (n = 8), respectively;P < 0.001]. In the MCT+MDgroup, Ppa and RV/LV were not different when compared with C [19 ± 0.5 mmHg (n = 5) and 0.27 ± 0.01 (n = 9), respectively;P < 0.001 vs. MCT]. Medial wall thickness of lung vessels in the MCT group was increased comparedwith C [31 ± 1.5% (n = 9)vs. 13 ± 0.66% (n = 9);P < 0.001], and MDpartially prevented MCT-induced pulmonary vascular remodeling [22 ± 1.2% (n = 11);P < 0.001 vs. MCT and C].These results indicate that a defect in the availability of bioactive NO may play an important role in the pathogenesis of MCT-induced PH.

     

Role of paraquat in the uncoupling of nitric oxide synthase

Nitric oxide synthase (NOS) oxidizes L-arginine to NO(&z.ccirf;) and L-citrulline. Recent studies have shown that this enzyme can also generate O(2)(&z.ccirf;-) during its enzymatic cycling. Herein, we used spin trapping and electron paramagnetic resonance (EPR) spectroscopy to investigate the impact paraquat has on the transport of electrons through purified neuronal NOS (NOS I). In a concentration-dependent manner, ranging from 10-100 microM of paraquat, paraquat free radical was observed under anaerobic conditions. This demonstrates that NOS shunts electrons to paraquat, thereby uncoupling this enzyme. This resulted in enhanced production of O(2)(&z.ccirf;-) at the expense of NO(&z.ccirf;). Experiments demonstrated that the reductase domain is the site of paraquat-mediated uncoupling of NOS.     

Both physical fitness and acute exercise regulate nitric oxide formation in healthy humans

Jungersten, Lennart, Anneli Ambring, Björn Wall, andÅke Wennmalm. Both physical fitness and acute exerciseregulate nitric oxide formation in healthy humans. J. Appl. Physiol. 82(3): 760-764, 1997.We analyzednitrate, a major stable end product of nitric oxide (NO) metabolism invivo in plasma and urine from groups of healthy subjects with differentworking capacities. Resting plasma nitrate was higher in athleticsubjects than in nonathletic controls [45 ± 2 vs. 34 ± 2 (SE) µM; P < 0.01]. In other subjects, both the resting plasma nitrate level(r = 0.53; P < 0.01) and the urinary excretionof nitrate at rest (r = 0.46; P < 0.01) correlated to thesubjects' peak work rates, as determined by bicycle ergometry. Twohours of physical exercise elevated plasma nitrate by 18 ± 4 (P < 0.01) and 16 ± 6%(P < 0.01), respectively, in athletes and nonathletes, compared with resting nitrate before exercise. We conclude that physical fitness and formation of NO at restare positively linked to each other. Furthermore, a single session ofexercise elicits an acute elevation of NO formation. The observedpositive relation between physical exercise and NO formation may helpto explain the beneficial effects of physical exercise oncardiovascular health.

     

Endogenous nitric oxide is implicated in the regulation of lipolysis through antioxidant-related effect

We studied the influence ofnitric oxide (NO) endogenously produced by adipocytes in lipolysisregulation. Diphenyliodonium (DPI), a nitric oxide synthase (NOS)inhibitor, was found to completely suppress NO synthesis in intactadipocytes and was thus used in lipolysis experiments. DPI was found todecrease both basal and dibutyryl cAMP (DBcAMP)-stimulatedlipolysis. Inhibition of DBcAMP-stimulated lipolysis by DPI wasprevented by S-nitroso-N-acetyl-penicillamine (SNAP), a NO donor. This antilipolytic effect of DPI was also preventedby two antioxidants, ascorbate or diethyldithiocarbamic acid (DDC).Preincubation of isolated adipocytes with DPI (30 min) before exposureto DBcAMP almost completely abolished the stimulated lipolysis.Addition of SNAP or antioxidant during DPI preincubation restored thelipolytic response to DBcAMP, whereas no preventive effects wereobserved when these compounds were added simultaneously to DBcAMP.Exposure of isolated adipocytes to an extracellular generating systemof oxygen species (xanthine/xanthine oxidase) or toH₂O₂ also resulted in an inhibition of thelipolytic response to DBcAMP. H₂O₂ or DPIdecreased cAMP-dependent protein kinase (PKA) activation. The DPIeffect on PKA activity was prevented by SNAP, ascorbate, or DDC. Theseresults provide clear evidence that 1) the DPI antilipolyticeffect is related to adipocyte NOS inhibition leading to PKAalterations, and 2) endogenous NO is required for the cAMPlipolytic process through antioxidant-related effect.

     

In vivo detection of nitric oxide distribution in mice

This paper discusses in vivo detection of nitric oxide (NO) distribution in endotoxin-treated mice using L-band (1.1 GHz) electron paramagnetic resonance spectroscopy (EPR) in combination with the hydrophilic NO trapping complex: N-methyl-D-glucamine dithiocarbamate and iron (MGD-Fe). MGD-Fe-NO complex is found in the upper abdomen (liver region), lower abdomen (kidney and urinary bladder) and head region of ICR mice. Experiments with nitric oxide synthase (NOS) inhibition and 15N-labeled L-arginine as NOS substrate verify the origin of trapped NO from L-arginine. However, contribution from a 'nonenzymatic' NO generation pathway can not be ruled out. This paper further examines potential artifacts, which may arise in experiments using dithiocarbamate-iron complexes as NO trapping agents.     

Improved oxygenation with prostaglandin F2alpha with and without inhaled nitric oxide in dogs

Dogs of mixedbreed (n = 7) were anesthetized, rightlung atelectasis was established, and the cyclooxygenase pathway was blocked with ibuprofen. Measurements of pulmonary gas exchange wereperformed (fractional concentration of inspiredO₂ = 0.95) after infusions ofprostaglandin F₂(PGF₂; 2 µg · kg¹ · min¹),ventilation with nitric oxide (NO; 40 ppm), or both(PGF₂ + NO) in random order.The arterial PO₂(Pa_O2) under control conditions was 117 ± 16 Torr (shunt = 33 ± 2.5%), was unchanged with NO alone(Pa_O2 = 114 ± 17 Torr; shunt = 35.7 ± 3.1%), but was significantlyimproved with PGF₂ alone(Pa_O2 = 180 ± 28 Torr; shunt = 23.2 ± 2.8%) and with the combination ofPGF₂ + NO(Pa_O2 = 202 ± 30 Torr; shunt = 20.9 ± 2.5%). The addition of NO didnot significantly enhance the effectiveness of thePGF₂ onPa_O2.Simulation of these data in a computer model, combining pulmonary gasexchange and pulmonary blood flow, reproduced the results on the basisthat vasoconstriction with PGF₂was maximal under hypoxia in the atelectatic lung and reduced byhyperoxia in the ventilated lung, consistent with the hypothesis ofO₂ dependence ofPGF₂ vasoconstriction.

     

Gamma-irradiation potentiates L-arginine-dependent nitric oxide formation in mice.

Gamma-irradiation of mongrel mice at a sublethal dose (700 Roentgen) enhanced the formation of nitric oxide (NO) in the liver, intestine, lung, kidney, brain, spleen or heart of the animals. NO formation was determined by the increase in intensity of the EPR signal due to trapping of NO into mononitrosyl iron complexes (MNIC) with exogenous diethyldithiocarbamate (DETC) injected intraperitoneally. The EPR signal of these MNIC-DETC complexes was characterized by g-factor values at g perpendicular values at g perpendicular = 2.035 and g parallel = 2.02 and a triplet hyperfine structure at g perpendicular. The NO synthase inhibitor, NG-nitro-L-arginine, prevented MNIC-DETC complex formation both in liver and intestine, demonstrating the involvement of endogenous NO formed. Thus, gamma-irradiation may enhance endogenous NO biosynthesis in these tissues, presumably by facilitating the entry of Ca2+ ions into the membrane as well as the cytosol of NO-producing cells through irradiation-induced membrane lesions.     

Production and absorption of nitric oxide gas in the nose

Some nitric oxide gas (NO) produced in thesinuses and nasal cavity is absorbed before leaving the nose. Tomeasure production and absorption, we introduced NO at differentconcentrations into one nostril while sampling the NO leaving theopposite nostril with the soft palate closed. The quantity of NO gasproduced in six normal subjects (amount leaving plus the amountabsorbed) averaged 352 nl/min and was the same at gas flows rangingfrom 8 to 347 ml/min and at 10 l/min. An absorption coefficientA was calculated by dividing theamount of NO absorbed by the concentration leaving the nose.A ranged from 17 ml/min at a nasal gasflow of 8 ml/min to an A of 24 ml/minat a nasal gas flow of 347 ml/min. The calculated rates of productionand absorption did not change when gas flow rate was increased,suggesting diffusion equilibrium. The amount of uptake of NO in thenasal mucosa can be explained by its solubility coupled with tissue andblood reactivity.

     

On-line detection of nitric oxide formation in liquid aqueous phase by electron paramagnetic resonance spectroscopy.

A method for the detection of the nitric oxide radical (NO) in oxygen-containing aqueous solution by means of electron paramagnetic resonance spectroscopy (EPR) is described. NO evolving from the spontaneous decomposition of 3-morpholinosydnonimine (SIN-1) was trapped by Fe(2+)-diethyldithiocarbamate (DETC) complex dissolved in yeast cell membranes. The resulting mononitrosyl-Fe(2+)-(DETC)2 complex was stable and exhibited a characteristic EPR signal at g perpendicular = 2.04 and g parallel = 2.02 with an unresolved triplet hyperfine structure at g perpendicular in frozen solution and an isotropic triplet signal at gav = 2.03 at 37 degrees C. The amount of NO trapped was calculated from the amplitude of one of the triplet lines calibrated by means of a dinitrosyl-Fe(2+)-thiosulfate standard. The lower detection limit of NO was 0.5 nmol/(ml x h) due to a low background NO signal. The upper detection limit was about 10 nmol NO/40 mg traps (DETC-loaded yeast cells), because of saturation of traps. The trapping efficiency approached 60% under anaerobic conditions and with low concentrations of SIN-1, but decreased progressively with higher concentrations and in the presence of oxygen. Nitrite (up to 0.1 mM) did not increase the background NO level. The sensitivity was sufficient to follow the rate of NO release from SIN-1 on-line at 37 degrees C in a flat quartz cuvette. The time course of NO release detected by EPR spectrometry correlated with the time course of nitrite accumulation measured by diazotation. In conclusion, this method will permit the on-line detection of NO formation from endogenous and pharmacological sources in oxygen-containing aqueous media.     

Nature and site of action of endogenous nitric oxide in vasculature of isolated pig lungs

Cremona, George, Tim Higenbottam, Motoshi Takao, Edward A. Bower, and Leslie W. Hall. Nature and site of action of endogenousnitric oxide in vasculature of isolated pig lungs. J. Appl. Physiol. 82(1): 23-31, 1997.The site ofaction of endogenous and exogenous nitric oxide (NO) in isolated piglungs was investigated by using arterial, double, and venous occlusion,which allowed precapillary, postcapillary, and venous segments to bepartitioned into arterial, precapillary, postcapillary, and venoussegments. N^G-nitro-L-arginine(L-NNA;10⁵ M) increased resistancein the arterial (35 ± 6.6%, P = 0.003), precapillary (39.3 ± 5.1%,P = 0.001), and venous (18.3 ± 4.8%, P = 0.01) segments,respectively. Sodium nitroprusside(10⁵ M) and NO (80 parts/million) reversed the effects ofL-NNA. Total pulmonary vascularresistance fell with increasing flow, due to a fall in precapillaryresistance and dynamic resistance, and was significantlylower than mean total resistance.L-NNA increased the resistancesbut did not alter the pattern of the pressure-flow relationships. It isconcluded that, in isolated pig lungs, the effect of endogenous NOseems to be dependent on flow in the arterial segment and independentof flow in the precapillary segment, but variation of its release doesnot appear to be fundamental to accommodation to changes in steadyflow.

     

Comparison between the uptake of nitrous oxide and nitric oxide in the human nose

The absorption of nitrous oxide(N₂O) during unidirectional flowwas compared with the rate of uptake of nitric oxide (NO). At flowrates of 10, 20, and 60 ml/min from one nostril to the other, with thesoft palate closed, the N₂Oreached a steady-state rate of absorption in 5-15 min. The meansuperficial capillary blood flow (n = 5) calculated from solubility and the steady-state rate ofN₂O absorption ranged from 13.3 to15.9 ml/min. The relation between absorption ofN₂O in the nose and capillaryblood flow fits a ventilation-perfusion model used by others todescribe uptake of inert, soluble gases in the rat nose. By contrast,the rate of uptake of NO gas, which is chemically reactive, is25-31 times as great as predicted by just its blood-to-airpartition coefficient. Exogenous NO (16.9 parts/million) did not induce nasal vasodilation as measured with laser Doppler andN₂O absorption methods. Thedifference between the measured rate of uptake of NO and the rate ofuptake attributable to its partition coefficient in blood at the rateof blood flow calculated from N₂Ouptake is probably due to chemical reaction of NO in mucous secretions, nasal tissues, and capillary blood.