Effects of supplemental oxygen on forearm vasodilation in humans

Crawford, Paul, Peter A. Good, Eric Gutierrez, Joshua H. Feinberg, John P. Boehmer, David H. Silber, and Lawrence I. Sinoway. Effects of supplemental oxygen on forearm vasodilation in humans.J. Appl. Physiol. 82(5):1601-1606, 1997.Supplemental O₂ reduces cardiac output andraises systemic vascular resistance in congestive heart failure. Inthis study, 100% O₂ was given tonormal subjects and peak forearm flow was measured. Inexperiment 1, 100%O₂ reduced blood flow andincreased resistance after 10 min of forearm ischemia (flow 56.7 ± 7.9 vs. 47.8 ± 6.7 ml · min¹ · 100 ml¹;P < 0.02; vascular resistance 1.7 ± 0.2 vs. 2.4 ± 0.4 mmHg · min · 100 ml · ml¹;P < 0.03). Inexperiment 2, lower body negativepressure (LBNP; 30 mmHg) and venous congestion (VC) simulatedthe high sympathetic tone and edema of congestive heart failure.Postischemic forearm flow and resistance were measured under fourconditions: room air breathing (RA); LBNP+RA; RA+LBNP+VC; and 100%O₂+LBNP+VC. LBNP and VC did notlower peak flow. However, O₂raised minimal resistance (2.3 ± 0.4 RA; 2.8 ± 0.5 O₂+LBNP+VC,P < 0.04). When O₂ alone(experiment 1) was compared withO₂+LBNP+VC(experiment 2), no effect of LBNP+VCon peak flow or minimum resistance was noted, although the return rateof flow and resistance toward baseline was increased.O₂ reduces peak forearm flow evenin the presence of LBNP and VC.

     

Venous and arterial reflex responses to positive-pressure breathing and lower body negative pressure

Peters, Jochen K., George Lister, Ethan R. Nadel, and GaryW. Mack. Venous and arterial reflex responses to positive-pressure breathing and lower body negative pressure. J. Appl.Physiol. 82(6): 1889-1896, 1997.We examined therelative importance of arteriolar and venous reflex responses duringreductions in cardiac output provoked by conditions that increase[positive end-expiratory pressure (PEEP)] or decrease[lower body negative pressure (LBNP)] peripheral venous filling.Five healthy subjects were exposed to PEEP (10, 15, 20, and 25 cmH₂O) and LBNP (10,15, 20, and 25 mmHg) to induce progressive butcomparable reductions in right atrial transmural pressure (control tominimum): from 5.9 ± 0.4 to 1.8 ± 0.7 and from 6.5 ± 0.6 to2.0 ± 0.2 mmHg with PEEP and LBNP, respectively. Cardiac output(impedance cardiography) fell less during PEEP than during LBNP (from3.64 ± 0.21 to 2.81 ± 0.21 and from 3.39 ± 0.21 to 2.14 ± 0.24 l · min¹ · m²with PEEP and LBNP, respectively), and mean arterial pressure increased. We observed sustained increases in forearm vascular resistance (i.e., forearm blood flow by venous occlusionplethysmography) and systemic vascular resistance that were greaterduring LBNP: from 19.7 ± 2.91 to 27.97 ± 5.46 and from 20.56 ± 2.48 to 50.25 ± 5.86 mmHg · ml¹ · 100 mltissue¹ · min(P < 0.05) during PEEP and LBNP,respectively. Venomotor responses (venous pressure in thehemodynamically isolated limb) were always transient, significant onlywith the greatest reduction in right atrial transmural pressure, andwere similar for LBNP and PEEP. Thus arteriolar rather than venousresponses are predominant in blood volume mobilization from skin andmuscle, and venoconstriction is not intensified with venous engorgementduring PEEP.

     

Combined heart rate and activity improve estimates of oxygen consumption and carbon dioxide production rates

Moon, Jon K., and Nancy F. Butte. Combined heart rateand activity improve estimates of oxygen consumption and carbon dioxideproduction rates. J. Appl. Physiol.81(4): 1754-1761, 1996.Oxygen consumption(O₂) andcarbon dioxide production (CO₂) rates were measuredby electronically recording heart rate (HR) and physical activity (PA).Mean daily O₂ andCO₂ measurements by HR andPA were validated in adults (n = 10 women and 10 men) with room calorimeters. Thirteen linear and nonlinear functions of HR alone and HR combined with PA were tested as models of24-h O₂ andCO₂. Mean sleepO₂ andCO₂ were similar to basalmetabolic rates and were accurately estimated from HR alone[respective mean errors were 0.2 ± 0.8 (SD) and0.4 ± 0.6%]. The range of prediction errorsfor 24-h O₂ andCO₂ was smallestfor a model that used PA to assign HR for each minute to separateactive and inactive curves(O₂, 3.3 ± 3.5%; CO₂, 4.6 ± 3%). There were no significant correlations betweenO₂ orCO₂ errors and subject age,weight, fat mass, ratio of daily to basal energy expenditure rate, orfitness. O₂,CO₂, and energy expenditurerecorded for 3 free-living days were 5.6 ± 0.9 ml ^· min^{1 ·} kg¹,4.7 ± 0.8 ml ^· min^{1 ·} kg¹,and 7.8 ± 1.6 kJ/min, respectively. Combined HR and PA measured 24-h O₂ andCO₂ with a precisionsimilar to alternative methods.

     

Effect of luteal phase elevation in core temperature on forearm blood flow during exercise

Kolka, Margaret A., and Lou A. Stephenson. Effect ofluteal phase elevation in core temperature on forearm blood flow duringexercise. J. Appl. Physiol. 82(4):1079-1083, 1997.Forearm blood flow (FBF) as an index of skinblood flow in the forearm was measured in five healthy women by venousocclusion plethysmography during leg exercise at 80% peak aerobicpower and ambient temperature of 35°C (relative humidity 22%;dew-point temperature 10°C). Resting esophagealtemperature (T_es) was 0.3 ± 0.1°C higher in the midluteal than in the early follicular phase ofthe menstrual cycle (P < 0.05).Resting FBF was not different between menstrual cycle phases. TheT_es threshold for onset of skinvasodilation was higher (37.4 ± 0.2°C) in midluteal than inearly follicular phase (37.0 ± 0.1°C; P < 0.05). The slope of the FBF toT_es relationship was not different between menstrual cycle phases (14.0 ± 4.2 ml · 100 ml¹ · min¹ · °C¹for early follicular and 16.3 ± 3.2 ml · 100 ml¹ · min¹ · °C¹for midluteal phase). Plateau FBF was higher during exercise inmidluteal (14.6 ± 2.2 ml · 100 ml¹ · min¹ · °C¹)compared with early follicular phase (10.9 ± 2.4 ml · 100 ml¹ · min¹ · °C¹;P < 0.05). The attenuation of theincrease in FBF to T_es occurred when T_es was 0.6°C higher andat higher FBF in midluteal than in early follicular experiments(P < 0.05). In summary, the FBF response is different during exercise in the two menstrual cycle phasesstudied. After the attenuation of the increase in FBF and whileT_es was still increasing, thegreater FBF in the midluteal phase may have been due to the effects ofincreased endogenous reproductive endocrines on the cutaneousvasculature.

     

Association of chest wall motion and tidal volume responses during CO2 rebreathing

Yan, Sheng, Pawel Sliwinski, and Peter T. Macklem.Association of chest wall motion and tidal volume responses during CO₂ rebreathing.J. Appl. Physiol. 81(4):1528-1534, 1996.The purpose of this study is to investigate theeffect of chest wall configuration at end expiration on tidal volume(VT) response duringCO₂ rebreathing. In a group of 11 healthy male subjects, the changes in end-expiratory andend-inspiratory volume of the rib cage (Vrc,E andVrc,I, respectively) and abdomen (Vab,E and Vab,I, respectively) measured by linearizedmagnetometers were expressed as a function of end-tidalPCO₂(PET_CO2). The changes inend-expiratory and end-inspiratory volumes of the chest wall(Vcw,E and Vcw,I,respectively) were calculated as the sum of the respectiverib cage and abdominal volumes. The magnetometer coils were placed atthe level of the nipples and 1-2 cm above the umbilicus andcalibrated during quiet breathing against theVT measured from apneumotachograph. TheVrc,E/PET_CO2 slope was quite variable among subjects. It was significantly positive (P < 0.05) in fivesubjects, significantly negative in four subjects(P < 0.05), and not different fromzero in the remaining two subjects. TheVab,E/PET_CO2slope was significantly negative in all subjects(P < 0.05) with a much smallerintersubject variation, probably suggesting a relatively more uniformrecruitment of abdominal expiratory muscles and a variable recruitmentof rib cage muscles during CO₂rebreathing in different subjects. As a group, the meanVrc,E/PET_CO2,Vab,E/PET_CO2, andVcw,E/PET_CO2slopes were 0.010 ± 0.034, 0.030 ± 0.007, and0.020 ± 0.032 l / Torr, respectively;only theVab,E/PET_CO2 slope was significantly different from zero. More interestingly, theindividualVT/PET_CO2slope was negatively associated with theVrc,E/PET_CO2(r = 0.68,P = 0.021) and Vcw,E/PET_CO2slopes (r = 0.63,P = 0.037) but was not associated withtheVab,E/PET_CO2slope (r = 0.40, P = 0.223). There was no correlation oftheVrc,E/PET_CO2 andVcw,E/PET_CO2slopes with age, body size, forced expiratory volume in 1 s, orexpiratory time. The groupVab,I/PET_CO2 slope (0.004 ± 0.014 l / Torr) was not significantlydifferent from zero despite theVT nearly being tripled at theend of CO₂ rebreathing. Inconclusion, the individual VTresponse to CO₂, althoughindependent of Vab,E, is a function ofVrc,E to the extent that as theVrc,E/PET_CO2slope increases (more positive) among subjects, theVT response toCO₂ decreases. These results maybe explained on the basis of the respiratory muscle actions andinteractions on the rib cage.

     

Training-induced alterations of glucose flux in men

Friedlander, Anne L., Gretchen A. Casazza, Michael A. Horning, Melvin J. Huie, and George A. Brooks. Training-induced alterations of glucose flux in men. J. Appl.Physiol. 82(4): 1360-1369, 1997.We examined thehypothesis that glucose flux was directly related to relative exerciseintensity both before and after a 10-wk cycle ergometer trainingprogram in 19 healthy male subjects. Two pretraining trials [45and 65% of peak O₂ consumption(O_{2 peak})] andtwo posttraining trials (same absolute and relative intensities as 65%pretraining) were performed for 90 min of rest and 1 h of cyclingexercise. After training, subjects increasedO_{2 peak} by9.4 ± 1.4%. Pretraining, the intensity effect on glucose kinetics was evident with rates of appearance(R_a; 5.84 ± 0.23 vs. 4.73 ± 0.19 mg · kg¹ · min¹),disappearance (R_d; 5.78 ± 0.19 vs. 4.73 ± 0.19 mg · kg¹ · min¹),oxidation (R_ox; 5.36 ± 0.15 vs. 3.41 ± 0.23 mg · kg¹ · min¹),and metabolic clearance (7.03 ± 0.56 vs. 5.20 ± 0.28 ml · kg¹ · min¹)of glucose being significantly greater(P  0.05) in the 65% than the 45%O_{2 peak} trial. WhenR_d was expressed as a percentage of total energy expended per minute(R_{d E}), there was nodifference between the 45 and 65% intensities. Training did reduceR_a (4.63 ± 0.25),R_d (4.65 ± 0.24),R_ox (3.77 ± 0.43), andR_{d E} (15.30 ± 0.40 to12.85 ± 0.81) when subjects were tested at the same absolute workload (P  0.05). However, whenthey were tested at the same relative workload,R_a,R_d, andR_{d E} were not different,although R_ox was lowerposttraining (5.36 ± 0.15 vs. 4.41 ± 0.42, P  0.05). These results show1) glucose use is directly relatedto exercise intensity; 2) trainingdecreases glucose flux for a given power output;3) when expressed as relativeexercise intensity, training does not affect the magnitude of bloodglucose use during exercise; 4)training alters the pathways of glucose disposal.

     

The VO2 slow component for severe exercise depends on type of exercise and is not correlated with time to fatigue

The purpose ofthis study was to examine the influence of the type of exercise(running vs. cycling) on the O₂uptake (O₂) slow component.Ten triathletes performed exhaustive exercise on a treadmill and on acycloergometer at a work rate corresponding to 90% of maximalO₂ (90% work rate maximalO₂). The duration of thetests before exhaustion was superimposable for both type of exercises(10 min 37 s ± 4 min 11 s vs. 10 min 54 s ± 4 min 47 s forrunning and cycling, respectively). TheO₂ slow component (difference between O₂ atthe last minute and minute 3 ofexercise) was significantly lower during running compared with cycling(20.9 ± 2 vs. 268.8 ± 24 ml/min). Consequently, there was norelationship between the magnitude of theO₂ slow component and thetime to fatigue. Finally, because blood lactate levels at the end of the tests were similar for both running (7.2 ± 1.9 mmol/l) and cycling (7.3 ± 2.4 mmol/l), there was a clear dissociation between blood lactate and the O₂slow component during running. These data demonstrate that1) theO₂ slow component dependson the type of exercise in a group of triathletes and2) the time to fatigue isindependent of the magnitude of theO₂ slow component and bloodlactate concentration. It is speculated that the difference in muscularcontraction regimen between running and cycling could account for thedifference in theO₂ slow component.

     

Diffusional permeability of rabbit mesothelium

Diffusional permeability (P) to sucrose(P_suc) andNa⁺(P_Na⁺)was determined in specimens of rabbit sternal parietal pericardium,which may be obtained without stripping. Specimens were mounted in anUssing apparatus with ³H-labeledsucrose and²²Na⁺in a luminal (L) or interstitial (I) chamber.P_suc was 2.16 ± 0.44 for LI and 2.63 ± 0.45 (SE) × 10⁵ cm/s for IL,i.e., ~10 times smaller than that previously obtained in strippedspecimens of pleura despite the similarity of intercellular junctionsin pericardium and pleural mesothelium of various species. Thesefindings suggest that previousP_suc wasoverestimated because stripping damages the mesothelium.P_Na⁺ (×10⁵ cm/s) was 7.07 ± 0.71 for LI and 7.37 ± 0.69 × 10⁵ cm/s for IL.Measurements were also done with phospholipids, which are adsorbed onthe luminal side of mesothelium in vivo. With phospholipids in L,P_suc was 0.75 ± 0.10 and 0.65 ± 0.08 andP_Na⁺was 3.80 ± 0.32 and 3.76 ± 0.15 × 10⁵ cm/s for LI andIL, respectively, i.e., smaller than without phospholipids.With phospholipids in I (where they are not adsorbed), P_suc (2.33 ± 0.42 × 10⁵ cm/s) andP_Na⁺(7.01 ± 0.45 × 10⁵ cm/s) were similar tothose values without phospholipids. Hence, adsorbed phospholipidsdecrease P of mesothelium. If themesothelium were scraped away from the specimen,P_suc of theconnective tissue would be 13.2 ± 0.76 × 10⁵ cm/s.P_suc of themesothelium, computed fromP_suc of theunscraped and scraped specimens, corrected for the effect of unstirredlayers (2.54 and 19.4 × 10⁵ cm/s, respectively),was 2.92 and 0.74 × 10⁵ cm/s without and withphospholipids, respectively. Hence, most of the resistance to diffusionof the pericardium is provided by the mesothelium.

     

Training-induced alterations of carbohydrate metabolism in women: women respond differently from men

We examined the hypothesis that glucose flux wasdirectly related to relative exercise intensity both beforeand after a 12-wk cycle ergometer training program [5days/wk, 1-h duration, 75% peakO₂ consumption(O_{2 peak})] inhealthy female subjects (n = 17; age23.8 ± 2.0 yr). Two pretraining trials (45 and 65% of O_{2 peak})and two posttraining trials [same absolute workload (65% of oldO_{2 peak})and same relative workload (65% of new O_{2 peak})] wereperformed on nine subjects by using a primed-continuous infusion of[1-¹³C]- and[6,6-²H]glucose.Eight additional subjects were studied by using[6,6-²H]glucose.Subjects were studied postabsorption for 90 min of rest and 1 h ofcycling exercise. After training, subjects increased O_{2 peak} by 25.2 ± 2.4%. Pretraining, the intensity effect on glucose kinetics wasevident between 45 and 65% ofO_{2 peak} with rates ofappearance (R_a: 4.52 ± 0.25 vs. 5.53 ± 0.33 mg · kg¹ · min¹),disappearance (R_d: 4.46 ± 0.25 vs. 5.54 ± 0.33 mg · kg¹ · min¹),and oxidation (R_ox: 2.45 ± 0.16 vs. 4.35 ± 0.26 mg · kg¹ · min¹)of glucose being significantly greater(P  0.05) in the 65% thanin the 45% trial. Training reducedR_a (4.7 ± 0.30 mg · kg¹ · min¹),R_d (4.69 ± 0.20 mg · kg¹ · min¹),and R_ox (3.54 ± 0.50 mg · kg¹ · min¹)at the same absolute workload (P  0.05). When subjects were tested at the same relative workload,R_a,R_d, andR_ox were not significantlydifferent after training. However, at both workloads after training,there was a significant decrease in total carbohydrate oxidation asdetermined by the respiratory exchange ratio. These results show thefollowing in young women: 1)glucose use is directly related to exercise intensity;2) training decreasesglucose flux for a given power output;3) when expressed asrelative exercise intensity, training does not affect the magnitude ofblood glucose flux during exercise; but4) training does reduce totalcarbohydrate oxidation.

     

Ventilatory response to exercise in diabetic subjects with autonomic neuropathy

Tantucci, C., P. Bottini, M. L. Dottorini, E. Puxeddu, G. Casucci, L. Scionti, and C. A. Sorbini. Ventilatory response toexercise in diabetic subjects with autonomic neuropathy.J. Appl. Physiol. 81(5):1978-1986, 1996.We have used diabetic autonomic neuropathy as amodel of chronic pulmonary denervation to study the ventilatoryresponse to incremental exercise in 20 diabetic subjects, 10 with(Dan+) and 10 without (Dan) autonomic dysfunction, and in 10 normal control subjects. Although both Dan+ and Dan subjectsachieved lower O₂ consumption andCO₂ production(CO₂) thancontrol subjects at peak of exercise, they attained similar values ofeither minute ventilation(E) oradjusted ventilation (E/maximalvoluntary ventilation). The increment of respiratory rate withincreasing adjusted ventilation was much higher in Dan+ than inDan and control subjects (P < 0.05). The slope of the linearE/CO₂relationship was 0.032 ± 0.002, 0.027 ± 0.001 (P < 0.05), and 0.025 ± 0.001 (P < 0.001) ml/min inDan+, Dan, and control subjects, respectively. Bothneuromuscular and ventilatory outputs in relation to increasingCO₂ were progressivelyhigher in Dan+ than in Dan and control subjects. At peak ofexercise, end-tidal PCO₂ was muchlower in Dan+ (35.9 ± 1.6 Torr) than in Dan (42.1 ± 1.7 Torr; P < 0.02) and control (42.1 ± 0.9 Torr; P < 0.005) subjects.We conclude that pulmonary autonomic denervation affects ventilatoryresponse to stressful exercise by excessively increasing respiratoryrate and alveolar ventilation. Reduced neural inhibitory modulationfrom sympathetic pulmonary afferents and/or increasedchemosensitivity may be responsible for the higher inspiratoryoutput.

     

Effects of respiratory muscle work on cardiac output and its distribution during maximal exercise

We have recently demonstrated that changes inthe work of breathing during maximal exercise affect leg blood flow andleg vascular conductance (C. A. Harms, M. A. Babcock, S. R. McClaran, D. F. Pegelow, G. A. Nickele, W. B. Nelson, and J. A. Dempsey. J. Appl. Physiol. 82: 1573-1583,1997). Our present study examined the effects of changesin the work of breathing on cardiac output (CO) during maximalexercise. Eight male cyclists [maximalO₂ consumption(O_{2 max}):62 ± 5 ml · kg¹ · min¹]performed repeated 2.5-min bouts of cycle exercise atO_{2 max}. Inspiratorymuscle work was either 1) at controllevels [inspiratory esophageal pressure (Pes): 27.8 ± 0.6 cmH₂O],2) reduced via a proportional-assistventilator (Pes: 16.3 ± 0.5 cmH₂O), or 3) increased via resistive loads(Pes: 35.6 ± 0.8 cmH₂O).O₂ contents measured in arterialand mixed venous blood were used to calculate CO via the direct Fickmethod. Stroke volume, CO, and pulmonaryO₂ consumption(O₂) were not different(P > 0.05) between control andloaded trials atO_{2 max} but were lower(8, 9, and 7%, respectively) than control withinspiratory muscle unloading atO_{2 max}. Thearterial-mixed venous O₂difference was unchanged with unloading or loading. We combined thesefindings with our recent study to show that the respiratory muscle work normally expended during maximal exercise has two significant effectson the cardiovascular system: 1) upto 14-16% of the CO is directed to the respiratory muscles; and2) local reflex vasoconstriction significantly compromises blood flow to leg locomotor muscles.

     

Gas exchange and cardiovascular kinetics with different exercise protocols in heart transplant recipients

Grassi, Bruno, Claudio Marconi, Michael Meyer, Michel Rieu,and Paolo Cerretelli. Gas exchange and cardiovascular kinetics with different exercise protocols in heart transplant recipients. J. Appl. Physiol. 82(6): 1952-1962, 1997.Metabolicand cardiovascular adjustments to various submaximal exercises wereevaluated in 82 heart transplant recipients (HTR) and in 35 controlsubjects (C). HTR were tested 21.5 ± 25.3 (SD) mo (range1.0-137.1 mo) posttransplantation. Three protocols were used:protocol A consisted of 5 min of rectangular 50-W load repeatedtwice, 5 min apart [5 min rest, 5 min 50 W (Ex 1), 5 minrecovery, 5 min 50 W (Ex 2)]; protocol B consistedof 5 min of rectangular load at 25, 50, or 75 W; protocol Cconsisted of 15 min of rectangular load at 25 W. Breath-by-breathpulmonary ventilation (E),O₂ uptake (O₂),and CO₂ output(CO₂) were determined.During protocol A, beat-by-beat cardiacoutput () was estimated by impedance cardiography. The half times (t_1/2) of the on- andoff-kinetics of the variables were calculated. In all protocols,t_1/2 values forO₂ on-,E on-, andCO₂ on-kinetics were higher(i.e., the kinetics were slower) in HTR than in C, independently ofworkload and of the time posttransplantation. Also,t_1/2 on- was higher in HTRthan in C. In protocol A, no significant difference of t_1/2 O₂on- was observed in HTR between Ex 1 (48 ± 9 s) and Ex2 (46 ± 8 s), whereas t_1/2 on- was higher during Ex 1 (55 ± 24 s)than during Ex 2 (47 ± 15 s). In all protocols and for all variables, the t_1/2 off-values were higher in HTRthan in C. In protocol C, no differences of steady-stateE,O₂, andCO₂ were observed in bothgroups between 5, 10, and 15 min of exercise. We conclude that1) in HTR, a "priming" exercise, while effective inspeeding up the adjustment of convective O₂ flow to muscle fibers during a second on-transition, did not affect theO₂ on-kinetics, suggestingthat the slower O₂ on- inHTR was attributable to peripheral (muscular) factors; 2) thedissociation between on- andO₂ on-kinetics in HTRindicates that an inertia of muscle metabolic machinery is the mainfactor dictating theO₂ on-kinetics; and 3) theO₂ off-kinetics was slowerin HTR than in C, indicating a greater alactic O₂ deficitin HTR and, therefore, a sluggish muscleO₂ adjustment.

     

Effect of prolonged, heavy exercise on pulmonary gas exchange in athletes

During maximalexercise, ventilation-perfusion inequality increases, especially inathletes. The mechanism remains speculative. Wehypothesized that, if interstitial pulmonary edema is involved, prolonged exercise would result in increasing ventilation-perfusion inequality over time by exposing the pulmonary vascular bed to highpressures for a long duration. The response to short-term exercise wasfirst characterized in six male athletes [maximal O₂ uptake(O_{2 max}) = 63 ml · kg¹ · min¹] by using 5 minof cycling exercise at 30, 65, and 90%O_{2 max}. Multiple inert-gas, blood-gas, hemodynamic, metabolic rate, and ventilatory data were obtained. Resting log SD of the perfusion distribution (logSD) was normal [0.50 ± 0.03 (SE)] and increased with exercise (logSD = 0.65 ± 0.04, P < 0.005), alveolar-arterialO₂ difference increased (to 24 ± 3 Torr), and end-capillary pulmonary diffusion limitation occurred at 90%O_{2 max}. The subjectsrecovered for 30 min, then, after resting measurements were taken,exercised for 60 min at ~65%O_{2 max}.O₂ uptake, ventilation, cardiacoutput, and alveolar-arterial O₂difference were unchanged after the first 5 min of this test, but logSD increased from0.59 ± 0.03 at 5 min to 0.66 ± 0.05 at 60 min(P < 0.05), without pulmonary diffusion limitation. LogSD was negativelyrelated to total lung capacity normalized for body surface area(r = 0.97,P < 0.005 at 60 min). These data are compatible with interstitial edema as a mechanism and suggest that lungsize is an important determinant of the efficiency of gas exchangeduring exercise.

     

Peripheral O2 diffusion does not affect VO2 on-kinetics in isolated in situ canine muscle

To test thehypothesis that muscle O₂ uptake(O₂) on-kinetics islimited, at least in part, by peripheralO₂ diffusion, we determined theO₂ on-kinetics in1) normoxia (Control);2) hyperoxic gas breathing(Hyperoxia); and 3) hyperoxia andthe administration of a drug (RSR-13, Allos Therapeutics), whichright-shifts the Hb-O₂dissociation curve (Hyperoxia+RSR-13). The study was conducted inisolated canine gastrocnemius muscles(n = 5) during transitions from restto 3 min of electrically stimulated isometric tetanic contractions(200-ms trains, 50 Hz; 1 contraction/2 s; 60-70% peakO₂). In all conditions,before and during contractions, muscle was pump perfused withconstantly elevated blood flow (), at a levelmeasured at steady state during contractions in preliminary trials withspontaneous . Adenosine was infusedintra-arterially to prevent inordinate pressure increases with theelevated . was measuredcontinuously, arterial and popliteal venousO₂ concentrations were determinedat rest and at 5- to 7-s intervals during contractions, andO₂ was calculated as · arteriovenous O₂ content difference.PO₂ at 50%HbO₂saturation (P₅₀) was calculated.Mean capillary PO₂(c_O2)was estimated by numerical integration.P₅₀ was higher in Hyperoxia+RSR-13[40 ± 1 (SE) Torr] than in Control and in Hyperoxia (31 ± 1 Torr). After 15 s of contractions,c_O2was higher in Hyperoxia (97 ± 9 Torr) vs. Control (53 ± 3 Torr) and in Hyperoxia+RSR-13 (197 ± 39 Torr) vs. Hyperoxia. Thetime to reach 63% of the difference between baseline and steady-stateO₂ during contractions was 24.7 ± 2.7 s in Control, 26.3 ± 0.8 s in Hyperoxia, and 24.7 ± 1.1 s in Hyperoxia+RSR-13 (not significant). Enhancement ofperipheral O₂ diffusion (obtainedby increasedc_O2at constant O₂ delivery) duringthe rest-to-contraction (60-70% of peakO₂) transition did notaffect muscle O₂on-kinetics.

     

Mechanical and metabolic determination of VO2 and fatigue during repetitive isometric contractions in situ

Repetitiveisometric tetanic contractions (1/s) of the caninegastrocnemius-plantaris muscle were studied either at optimal length(L_o) or shortlength (L_s;~0.9 · L_o),to determine the effects of initial length on mechanical and metabolicperformance in situ. Respective averages of mechanical and metabolicvariables were(L_o vs.L_s, allP < 0.05) passive tension (preload) = 55 vs. 6 g/g, maximal active tetanic tension(P_o) = 544 vs. 174 (0.38 · P_o)g/g, maximal blood flow () = 2.0 vs. 1.4 ml · min¹ · g¹,and maximal oxygen uptake(O₂) = 12 vs. 9 µmol · min¹ · g¹.Tension at L_odecreased to0.64 · P_o over20 min of repetitive contractions, demonstrating fatigue; there were nosignificant changes in tension atL_s. In separatemuscles contracting atL_o, was set to that measured atL_s (1.1 ml · min¹ · g¹),resulting in decreased O₂(7 µmol · min¹ · g¹),and rapid fatigue, to0.44 · P_o. Thesedata demonstrate that 1)muscles at L_ohave higher andO₂ values than those at L_s;2) fatigue occurs atL_o with highO₂, adjusting metabolic demand (tension output) to match supply; and3) the lack of fatigue atL_s with lowertension, , andO₂ suggestsadequate matching of metabolic demand, set low by shortmuscle length, with supply optimized by low preload. Thesedifferences in tension andO₂ betweenL_o andL_s groupsindicate that muscles contracting isometrically at initial lengthsshorter than L_oare working under submaximal conditions.

     

H2O2 increases sheep tracheal blood flow, permeability, and vascular response to luminal capsaicin

Wells, U. M., S. Duneclift, and J. G. Widdicombe.H₂O₂increases sheep tracheal blood flow, permeability, and vascular response to luminal capsaicin. J. Appl.Physiol. 82(2): 621-631, 1997.Exogenous hydrogenperoxide(H₂O₂)causes airway epithelial damage in vitro. We have studied the effectsof luminalH₂O₂in the sheep trachea in vivo on tracheal permeability tolow-molecular-weight hydrophilic (technetium-99m-labeleddiethylenetriamine pentaacetic acid;^99mTc-DTPA) and lipophilic([¹⁴C]antipyrine;[¹⁴C]AP) tracers andon the tracheal vascular response to luminal capsaicin, whichstimulates afferent nerve endings. A tracheal artery was perfused, andtracheal venous blood was collected. H₂O₂exposure (10 mM) reduced tracheal potential difference(42.0 ± 6.4 mV) to zero. It increased arterial andvenous flows (56.7 ± 6.1 and 57.3 ± 10.0%,respectively; n = 5, P < 0.01, paired t-test) but not tracheal lymph flow(unstimulated flow 5.0 ± 1.2 µl ^· min^{1 ·} cm¹,n = 4). DuringH₂O₂exposure, permeability to ^99mTc-DTPA increased from2.6 to 89.7 × 10⁷ cm/s(n = 5, P < 0.05), whereas permeability to[¹⁴C]AP (3,312.6 × 10⁷ cm/s,n = 4) was not altered significantly(2,565 × 10⁷cm/s). Luminal capsaicin (10 µM) increased tracheal blood flow (10.1 ± 4.1%, n = 5)and decreased venous ^99mTc-DTPAconcentration (19.7 ± 4.0, P < 0.01), and these effects weresignificantly greater after epithelial damage (28.1 ± 6.0 and45.7 ± 4.3%, respectively,P < 0.05, unpairedt-test). Thus H₂O₂increases the penetration of a hydrophilic tracer into tracheal bloodand lymph but has less effect on a lipophilic tracer. It also enhancesthe effects of luminal capsaicin on blood flow and tracer uptake.

     

Pulmonary blood flow redistribution by increased gravitational force

This study was undertaken to assess theinfluence of gravity on the distribution of pulmonary blood flow (PBF)using increased inertial force as a perturbation. PBF was studied inunanesthetized swine exposed toG_x (dorsal-to-ventraldirection, prone position), where G is the magnitude of the force ofgravity at the surface of the Earth, on the Armstrong LaboratoryCentrifuge at Brooks Air Force Base. PBF was measured using 15-µmfluorescent microspheres, a method with markedly enhanced spatialresolution. Each animal was exposed randomly to 1, 2, and3 G_x. Pulmonary vascularpressures, cardiac output, heart rate, arterial blood gases, and PBFdistribution were measured at each G level. Heterogeneity of PBFdistribution as measured by the coefficient of variation of PBFdistribution increased from 0.38 ± 0.05 to 0.55 ± 0.11 to0.72 ± 0.16 at 1, 2, and 3G_x, respectively. At 1G_x, PBF was greatest in theventral and cranial and lowest in the dorsal and caudal regions of thelung. With increased G_x,this gradient was augmented in both directions. Extrapolation of thesevalues to 0 G predicts a slight dorsal (nondependent) region dominanceof PBF and a coefficient of variation of 0.22 in microgravity. Analysisof variance revealed that a fixed component (vascular structure)accounted for 81% and nonstructure components (including gravity)accounted for the remaining 19% of the PBF variance across the entireexperiment (all 3 gravitational levels). The results are inconsistentwith the predictions of the zone model.

     

Magnitude and time course of hemodynamic responses to Mueller maneuvers in patients with congestive heart failure

To simulate theimmediate hemodynamic effect of negative intrathoracic pressure duringobstructive apneas in congestive heart failure (CHF), without inducingconfounding factors such as hypoxia and arousals from sleep, eightawake patients performed, at random, 15-s Mueller maneuvers (MM) attarget intrathoracic pressures of 20 (MM 20) and40 cmH₂O (MM 40),confirmed by esophageal pressure, and 15-s breath holds, as apneic timecontrols. Compared with quiet breathing, at baseline, before theseinterventions, the immediate effects [first 5 cardiac cycles(SD), P values refer to MM 40compared with breath holds] of apnea, MM 20, and MM 40 were, for left ventricular (LV) systolic transmural pressure (Ptm), 1.0 ± 1.9, 7.2 ± 3.5, and 11.3 ± 6.8 mmHg(P < 0.01); for systolic bloodpressure (SBP), 2.9 ± 2.6, 5.5 ± 3.4, and 12.1 ± 6.8 mmHg (P < 0.01); and forstroke volume (SV) index, 0.4 ± 2.8, 4.1 ± 2.8, and6.9 ± 2.3 ml/m²(P < 0.001), respectively.Corresponding values over the last five cardiac cycles were for LVPtm6.4 ± 4.4, 5.4 ± 6.6, and 4.5 ± 9.1 mmHg (P < 0.01); for SBP6.9 ± 4.2, 8.2 ± 7.7, and 24.2 ± 6.9 mmHg (P < 0.01); and for SVindex 0.4 ± 2.1, 5.2 ± 2.8, and 9.2 ± 4.8 ml/m²(P < 0.001), respectively.Thus, in CHF patients, the initial hemodynamic response to thegeneration of negative intrathoracic pressure includes an immediateincrease in LV afterload and an abrupt fall in SV. The magnitude ofresponse is proportional to the intensity of the MM stimulus. By theend of a 15-s MM 40, LVPtm falls below baseline values, yet SVand SBP do not recover. Thus, when 40cmH₂O intrathoracic pressure issustained, additional mechanisms, such as a drop in LV preload due toventricular interaction, are engaged, further reducing SV. The neteffect of MM 40 was a 33% reduction in SV index (from 27 to 18 ml/min²), and a 21% reductionin SBP (from 121 to 96 mmHg). Obstructive apneas can have adverseeffects on systemic and, possibly, coronary perfusion in CHF throughdynamic mechanisms that are both stimulus and timedependent.

     

Oxygen transport in conscious newborn dogs during hypoxic hypometabolism

We questioned whether the decrease inO₂ consumption(O₂) during hypoxia innewborns is a regulated response or reflects a limitation inO₂ availability. Experiments wereconducted on previously instrumented conscious newborn dogs.O₂ was measured at a warmambient temperature (30°C, n = 7)or in the cold (20°C, n = 6),while the animals breathed air or were sequentially exposed to 15 minof fractional inspired O₂(FI_O2): 21, 18, 15, 12, 10, 8, and 6%. In normoxia,O₂ averaged 15 ± 1 (SE)and 25 ± 1 ml · kg¹ · min¹in warm and cold conditions, respectively. In the warmcondition, hypometabolism (i.e., hypoxicO₂ < normoxicO₂) occurred at FI_O2 10%, whereas in thecold condition, hypometabolism occurred atFI_O2 12%. The sameresults were obtained in a separate group(n = 14) of noninstrumented puppies.For all levels of FI_O2 withhypometabolism, the relationships between measures ofO₂ availability (arterialO₂ saturation or content, venousPO₂ or saturation,x-axis) vs.O₂(y-axis) had lower slopes in warm than in coldconditions. Hence, O₂ during hypometabolism in the warm condition was not the maximal attainable for the level of oxygenation. The results do not support thepossibility that the hypoxic drop inO₂ in the newborn reflects a limitation in O₂availability. The results are compatible with the ideathat the phenomenon is one of "regulated conformism" tohypoxia.

     

Reductions in visceral fat during weight loss and walking are associated with improvements in {V}O2 max

The accumulation ofvisceral fat is independently associated with an increased risk forcardiovascular disease. The aim of this study was to determine whetherthe loss of visceral adipose tissue area (VAT; computed tomography) isrelated to improvements in maximal O₂ uptake(O_2 max) during a weight loss(250-350 kcal/day deficit) and walking (3 days/wk, 30-40 min)intervention. Forty obese [body fat 47 ± 1 (SE) %], sedentary(O_2 max 19 ± 1 ml · kg¹ · min¹)postmenopausal women (age 62 ± 1 yr) participated in the study. The intervention resulted in significant declines in body weight (8%), total fat mass (dual-energy X-ray absorptiometry; 17%), VAT(17%), and subcutaneous adipose tissue area (17%) with no changein lean body mass (all P < 0.001). Women with anaverage 10% increase in O_2 max reducedVAT by an average of 20%, whereas those who did not increaseO_2 max decreased VAT by only 10%,despite comparable reductions in body fat, fat mass, and subcutaneousadipose tissue area. The decrease in VAT was independently related tothe change in O_2 max(r² = 0.22; P < 0.01) andfat mass (r² = 0.08; P = 0.05). These data indicate that greater improvements inO_2 max with weight loss and walking areassociated with greater reductions in visceral adiposity in obesepostmenopausal women.