Anaerobic metabolism as an indicator of aerobic function during exercise in cardiac patients

Anaerobic metabolism as an indicator of aerobic function during exercise in cardiac patients

Anaerobic Metabolism as an Indicator of Aerobic Function During Exercise in Cardiac Patients I’XKGi...

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Anaerobic Metabolism as an Indicator of Aerobic Function During Exercise in Cardiac Patients I’XKGi
determine

WhCthEr

patients withhart

disease depend mwe

than nwmat ruhjeets on anaerobic mataholirm to pwfxm the same level of exerti% the rnaerohic threshold, slope of the increasein enrhon dioxide output with respectto oxygen uptake (AVCO,IAVOI) and the slope of the increasein oxygen uptake with resppcct to the increasein work rate (AVOJAWR) both b&w and ahave the anaerobic thrahotd during cxerctw were ewluated. A Mat of 106 palientr with chronic heart diseaseand 42 healthy subjectsperformed a symptom-limited incremental evercisetsl in a amp pattern on z eyeleergcmwtw. Peakoxygw uptake wassignilirantty lower in the patientswith heart diseasethan in the nornut subjects. The anaerobic threshold, which was 20 + 4.6 mllmin per kg in normal subjects, decreased significantly with progressing severity of functional tlw: 16 ? 2.4, 14.1 + 2.5 and 11.3 * 1.5 mUndn pa kg, respeetivtly,in patieotr in class1, classII and classIII. The slop of A~Q~IAWR, which reprzsentr the degreeof aerobic metab+

Initially \pith exercise, carbon dioxide output increases linearly with oxygen uptake and greater aerobic metabolism until the slope of the increase in carbon dioxide output with respect to oxygen uptake (AVC021AVOJ approximates the anaerobx threshold (I). Thereafter, as anaerobic slycolysis comF’ements aerobic metabolism, lactic acidosis develops (Z-4). Jicarbonate would be the primary buffer of lactic acid
I or

where Hi = hydrogen ion. HCO,- = bicarbonate, K* = potassium. Thus, A!%O,IAi’OI would become steeper above the anaerobic threshold because an additional 22 ml of carbon dioxide over that produced by aerobic metabolism must be generated from each milliequivalent of laaic acid

between normal subj~ets and patie& However,~A&JA+O, above the anaerobic threshold became steeper with incrasing severityof heart d&se: I.37 t 0.17 in normal subjects versus 1.55* 0.24, 1.67+ 0.3 and 1.8 + 0.35 resp&iwty, in patirnls in functional classI, classII and tlas 111. The steeperA~CO,IAi’O, sloppabovelhe anaerobicthreshold in patientswith heart diseaseresulted from the greater ~maunt of carbon dloxlde preduetion per unit of oxygen and rrtlected the greater extent of anaerohie metabolism needed to supplement energyoutput. Thb ratio. which wasnot intlurnred hy patient ege or the slopeof the work rate increase,provider a useful indicator of aeroh!efunelion in patienti with heal disear. N Am Coil Cordial 1992;20:1?0-6)

buffered by bicarbonate (2). The breakpoint in the carbon dioxideoutpul-oxygenuptakeplot (V slope analysis). therefore, is rhe anaerobic threshold (3,5,6). Although the an:er. obic threshold has been used lo identify the severity of chronic heart failure (7-IO), some reports (ll,l2) have contradicled the concept uf the anaerobic threshold. If there is. in fact. a threshold phenomenon in lactic acidosis that represents anaerobic metabolism, the slope of AkCO,lAirO, above the anaerobic threshold should become steeper with an increasein anaerobic metabolism without a change in the s!ol)eof AirCOJAirO, below the anaerobicIhreshold. We hypotheiired &at al levels of exercise more intense than those that could be performed with aerobic metabolisn alone, the greater the degree of circulatory impairment, the ercatcr the extent that anaemhic metabo!i%n would he needed to supplement energy output. Thi\ would result in increasing amounts of c&on dioxide production per unit of oxygen consumption. To evaluate lhe contribution of anaerobic metabolism during exercise.we measuredA~COllAirO,along with the slope of the increase in oxygen uptake with respect to the increase in work rate (A902/AWR) (Z-4,13) in patients with various types of hean direare. We also eumined whether

Methods Stud) patients (Table I). WC ctudwd I? hcetthy whject\ without evidence of heart d~raw sod IO6 pauenrx $$rlth chronic bran disease tTob,e iI. Thelc wre 9, men and 57 women: 47 patients were m New York Heart A~~ociatmn functioned cl%s I. 41 m clws II and I! in ~,a\\ Ill. Their diagnoses were coronary artery din\c tn = 301. wlvu!x heart disease In = ?h). huocrtcn*ive hex, disca% tn = 25). dilated cardiomyopathy In = 71and other- heart diseare !n = IR). Excluded from rtudy were ;my parienrx wtb r&t an%ind. as well as those with pure mitral ~cnow or aortjc stenosi% The nature and purpose of the study and the wk* involved were explained and informed conscnt ra, ohtamed from each subject before his or her voluntary conwtt to participate. Exercise pmtoeol. A symptom-limited exercise tc(t aa> employed using iln upright clectromagnctically braked cycle ergometer (Siemens-Elema 1308). After a 4-min rest on the ergomctcr.each subject began the exercise te\t with it 4.min warm-up at 20 W. htl ‘pm, Mowed by a progressive increase in work rate tramp patte,n) (141. Although the slope of the increase in work rate wits initially selected as IO Wlmin ~,~i6s~or:0WimintlW/3s~randomly.l?Wlm~nllW/4aJ was later added to ihe randomization requence (Table ,). Meawrements. Heart rate and a I?-lead electrocardiogram IECC) were monitored throughout the tat. CUB blood pressure wab measured every minute by an automatic indirect manometer (STBP-680F. Collin Denshi) (151. O.ryxen II~IUPP.curhon dio.ride owpttr und ntin~c wntilotion were measured every IO s at rat and during exercise with an Aerobic Processor 39, tNihon Denki Sanei). This system consists of a mixing chamber (2.5 liters), polarogmph oxygen analyzer. infrared carbon dioxide analyzerand a hoi wire spirometer. Gas exchange and flow measurements were corrected for ambient temperature. barometric prersure and water vapor.

Calculationsof the rlcp of the increaw in carbon dioxide output ailh respectto oxygen uptake t&iiCOjdVO,) and the slope of inrreace in oxygen uptake with respectto the ioereare in aurk rate (AVOz,~WR, below and above the maerot,ic thrcctmtd. The BVCOlll’iOi and 1+0,0WR wure co/colatcd ietw and above the anaerobic thwhold tATt a\ foliow 1VCO,i1VO, below the .AT = IVCO, at the AT - i’C0, i,, !,I W] ! IVO, ai the AT - VO, ill Xl W]. lVCOI’AVt,,abovc the AT = [peak *CO: - iiC0, at Ihe ATI [peak VO, - VO, at rhe AT] 1”O.:1WR hclow the AT = IVO. a, ,he AT - \iO. m 21) ‘hi ! iWRat lbe AT - loi. LVO,:LWR above the AT = [peak iiD, - VO, a, the AT] Ima~imai WR WR at the AT]. where WR = work rate. Satisliul methods. Data are reported as mean value I SD. Ccmpansonc of the variable, related to functiunal cluwlication. cardiac letion and slope of the ramp w-t were made by analysis of variance (ANOVA,. Significant difference\ in the F test were then compared by using the Newman-Keuls multiple range test. Differences were wnridered statt\ticallg stgniticant at the p < 0.05 level.

:

!

Results Slope of work rate inc-: anaewbii thre4wld. The mean value (W/min) of the slope ofthe increase in work rate was I5 2 5 4.8 in the normal subjects, 14.9 rf 4.4 in patientm clans 1. 14.8 + 4.1 in those in clarr II and 13.3 t 4.7 in thuae in class III tp = NS). Allhougb relattvely few subject> pcrformcd the IS-Wimin ramp test, there was no Ggnificant diKerenie in the severity ofhean disease with respect to the slope of the work rate increase (10, IS or 20 Winin). Figure shows the respiratory gas exchange of a typical patient with heart disease during the ramp test. Ventilatory cquivalent fo- oxy~een(vE#OJ increased after a period of stability. whereas the ventilatory equivalent for carbon dioxide li/EI~COIl decreased at the work rate indicated by the vertical line. Therefore, oxygen uptake at thts work rate was detincd as the anaerobic threshold. In Figure 2. from the rame patient. carbon d&de output has been plotted as a function of oxygen uptake (V slope plot). The easily distinSuished intercept of the two slopes ofcarbon dioxide output

I

J

11:

with respect !u oxygen uplake (AiTOJAi’O,) is the anaerobic threshold. In this patient, A~C02iA’i~0, helow the anaerobic threshold was approximately I, whereas Ai’COi AVO, above the anaerobic threshold was almost 2. Variables of aerobic function. Heart rate and blood preswe during exercise are sbowr! in Table 2 and the variables of aerobic function obtained by measuring respiratory gas exchange during exercise appear m Table 3. The peak oxygen uptake normalized to each subject’s body weight was 32.4 2 7.1 mllmin per kg in the normal subjects. The value was significantly decreased below normal to 25. 4.8. 21.1 C 4.7 and 16.9 * 2.1 mllmin per kg in palients in class I, class II and clil~s 111.respectively. Similarly. anaerobic threshold. which was 20 i 4.6 mllmin per kg in normal subjects, was significantly decreased with increasing severity of hear, d,sease: 16 f 2.4, 14.1 + 2.5 and 11.3 2 1.5 mllmin per kg, respectively, in patients in functional class 1. class II and class III. The maximal work rate and the work rate at the anaerotic threshold also decreased in accordance with severity of heart disease (Table 3). ReMion between oxygen uptake and carbun dioxide output during exorcise. Oxygen uptake is plotted against work rate for normal subjects and patients with heart disease in Figure 3A. There was a significant difference m oxygen uptake at 20 W among the four groups by analysis of variance (p =

I*

0.002). Oxygen uptake at 20 W in patients m class 111was significantly lower than in lhe other three g,aupr (p < 0.05 hy the Newman-Keels multiple range test). The decrease in oxygen uptake with the severity of heart disease must be more profound at higher work rata because the slope of the increase in oxygen uptake with rapect to the increase in work rate (AVOJAWR) was significantly decreased bolh below and above the anaerobic threshold in relation to diwse progression (Fig. 3A, Table 3). However, carbon dioxide output. which tended to be lower at work rates below the anaerobic threshold in patients with heart disease than m nor.nal subjects, was essentially the same at work rates above the anaerobic threshold (Fig. 3B). The discrepancy between oxygen uptake and carbon dioxide oulput responses during exercise must influence the ratm of aiiCO,/L\eOz (V slope plot). Figure 4A shows the values for oxygen uptake and carbon dioxide output at rest .wd at 20 W. anaerobic threshold and maximal work raw from the lowest to the highest oxygen uptake in all subjects tested, The anaerobic threshold iss ldwer and the upper slope of AiT02iAir0, became steeper in patients with hean disease than in normal subjects. although there was no diAercnce in the lower slope. The upper slope became steeper with an increase in funcliwml class (Fig. 48). i’hr b~(lrreucr of the .slope of the mng test (IO. I5 and 20 Wlmin) on A60,IAWR and A~CO,IA~O, is demonstrated in Figure 5. Boih the work rate a1 ihe anaerobic threshold and the maximal work rate increased sipGficantly with increasing slope ofthe ramp tw: 58.6 + 13.8and 102.7 t 25.6 W for the study at IO Wimin; 74.5 -+_15.9and 134.6 + 25.1 W for the study ni I5 Wlmin and 86.5 * 21.3 and 152.2

+

40.1 w for the swdy at 20 Wimm. The value of A+02JAWR for the study at 20 Wlmin was significantly lower than that for 10 Wlmin. bmb below and above the anaerobic threshold (by Newman.Keuls’ multiple range tesl). However. this slopz had no intkosnce on AiiCOliA’>O, above or below the anaembic threshold (Fit. 58). There wo1sno relorion berween AVCO,&‘O, nbove rhe anaerobic thzsholdand agu in normal subjects ifig. 6). The relation between lhls slope above the anaerobic threchold and peak oxygen uptake is shown in Figure 7; the s!ope increased as the peak oxygen uptake declined. showmg a significantly negative comAation (r = -0.502). A weak negative correlation was also noted between the slope above the anaerobic threshold and anaerobic threshold (y = I.893 - 0.021x. r = -0.297). There was no significant difference in the anaembic threshold, peak oxygen uptake 0: slope above the anaercbic threshold with respect to the type of hean disease.

Di§CUSSiOll Delorminatim of the anaerobic threshold. The anaerobic threshold usually is deremdnt-d by .eas exchange analysis as tbc unypn uptake a which $62 vcnlilatory squivalem for oxygen (‘JEi’?02) increases after being Rat or decrcascd, while the vendlamp equivalent for carbon dioxide (irEI 6C02) remains constant or decreases (16.17).This method is L-=~ .,i .L* @g! the increase in carbon dioxide ..-,- “.. L.._-:serr.$~, .I_ output :enerared from lactic acid buliered by bsarboa?!t would result in ventilatory drive through the chemorecepton. However, chemoreceptors may not behave normally in patienls with Lund disease or chronic hean failure (19% In 1986, Beaver et al. (5) studied the relation between oxygen uptake and carbon dioxide OUtQUlduring exercise in normal subjects and found that the intercept of oxygen uptake and carbon dioxide output plots &’ slope plots) during exercise coincided with the metabolic daclie) acidow thresixld (that is. Ihe anaerobic thxshold). This metnod of

‘“1 A

I

detanning the anaerobic lhrcshold does not rely on Ihe magnitude of the venlilawry adjustment tar metabolic acidosis and ip r&lively unaffected by brealhing irregulantics. T/w unwrohic ~hr~~rlrold. ac rep, crcntcd by the highest level of oxygen uptake lhat can be performed without the development of a sustained lac!i: acidosis. bar been used to estimate the severity of cardiovascular impairment (7-10) and effectiveness of cardiac therapy (X-221. Slope of the iilcrease in carbon dioxide output with rcspecl to oxygen upldke. If because of aeteriorating hcan function. the patient wth heart d~s~abe ih more dependent than the normal subiect on anaerobx metabolism to periorm the same !cvel of r”crci% addil;onal carbon dioxldc would be genelated from lacticwad lo thcprorm study. i! v&ill found that Ihe slune of the incrcare in carbon dioxide OUIDU~ with

rc~pect 10 oxygen uptake IAVCO,lAi’O,l above the anaerobic threshold was steeper in patientr with heart disease than in normal subjects. This difference mw result from decreased oxygen uptake despite the some carbon dioxide cs:puc as that of normal subjects (Fig. 31 and is evidence of an increase in anaerobic metabolism reladve to aerobtc metabolism during exercise in pmients with heart disease. If lhere war no compensatory increae in anaerobic metabolism. the carbon dioxide oulput in these patients would be lower ar work rata above the anaerobic threshold. as noted with oxygen uplake. WC fcund no rclahrn belween Ihc slope of &i’C0,1Aii02 above the anaerobic threshold and age. although ii is well known that the anaerobic threshold and peak oxygen uptake decline with ac (231. The increase in the slope of oxygen uptake with rernect to the increase in

and peak exerciic. going from the lowest to hahesloxy$en optake.

work

rate

relation

(AVCJAWR)has also bee” reported to have no 113.23).Although the reason for this nhenom-

to age

enon has not been clarifi&the explain

why age is not a” important

slope above the ““aerobic The anaerobic oxygen

perform

work without

the sleeper

uptake

slope

faclor

for the steeper

above

which

representing

a rubjecr

lactic acidosis.

A%‘CO,lAiiO,above

in patients with heart disuse

in accordance

production

negative correlation uptake

between

was also found

affected by the patient’s geak oxygen

per unit of oxygen

with the severity

uptake

of circulatory this variable

(Fig.

7). This

motivation,

or maximal

not

slightly

that obsenjed in

the anaerdbic in increasing consumption impairment.

A

and peak oxygen

variable

~a”noL be

which can easily affect work

higher than

lated #he slope of this ratio as (VCO, QCO, at 20 W) / (ii0,

rate. The maximal

results from the relatively

simply

from

exercise. which dioxide AVO,

as a” independent

tw

Above

ventdatio”

high solubility

%‘O, a, of this

of rarbon dioxide in

points:

the anaerobic

the respiratory increases

may increase

slightly.

and other factors of ihe metabolic

linearity

compensation

AVCO,l this

and peak point

at

tc czab3,3

the slope of AirCO,l

depending related

acidosis

of

We calculated threshold

disproportionately

output (increase in i’E/i’COJ,

dxation

can sixe

-

of 11~: ramp test, which

tissues (3.IY.24). We may also have to consider the AiiO, above the anaerobic threshold.

sensitivity

in the patients

threshold

threrhnld

variable in thar in the prese”~ study it included tbe nonlinear

profoundly influenced by the slope of the ramp test, *x5o:nx the slope of AirCOdA’?O,above the anaerobicthreshold

was not. This variable

We calcu-

at anaerobic

28 WL which might accourfi for the underestimation

work rate and work rate at the anaerobic threshold were

of aerobic function

I (Z-4.a value

our study.

at anaernhic

pan of the data at the beginning

However.

re9ects the extep. of

anaerobic metabolism. which would result carbon dioxide

could

1.“~

below the anaerobic rhreqhotd

to be approximately

-

is t”e variab!c

developing

of

might

threshold.

thranold

highest

threshold

same mecham&

ThL Dupe oiAiiCO,/lwOl has been reported

on chemoreceptor

to the magnitude

and

and the actual oxygen

uptake (3).

indicator

with heart disease.

Figure 6. Relation between the slope ui the incrrax in carbon dioxide outpm wit’” respect to oxygen uptake “bow the anaerobic threshold (SZ) and age in “ormaJ subjects (24 me” and 18 women). yo = years at*.

Fiurr 7. Rclatior ‘ds,eeo the slope cf Ihe increase I” carbon dioxide outwt wth respecl 10 oxygen uptake above the araerobic threshold 621 md peak oxygen uptake (VO,) in all 143 subjects iwed.

during a progreaivc wing

a cycle

in&w

agomctcr.

cardiovascular

dysfunctmn.

been considered

found ihal AiiOJAWR ment

in work

Since

rale.

wilh

P~O,IAWR

has

LO raresent

the

cm he mRitcnccd the steeper

in patients

thin.

variable

(thio i*, normally

sfudy. B Gmilar

with heart diwse

rate m normal s;bjccts

decreased

an additional

work rate increment presnt

in v&k wa\

by Ihe ,lope oilhe

the slower Ihc incre-

the AQO,lAWR)

phenomenon

In the

was found in patients

(t ig. 5).

Conclusions. ‘The ‘,teeper 9opc of AVC021Ai10z above Ihe anaerobw threshold m our patients resulted from the greawr rellecled

cubon

dioxide

pru.+chon

per umt of oxygen;

Ihe grearer exie,,, of imxrobic

to supplement

energy output.

this ratio. which reilcctr blc metabolism

metabolism

it

needed

We believe that the slope of

the relalive

lo total metabolic

contribution

oianaero-

responses. can serve a~ a