Inhomogeneities of Ventilation and the Diffusing Capacity to Perfusion in Various Chronic Lung Diseases

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Inhomogeneities of Ventilation and the Diffusing Capacity to Perfusion in Various Chronic Lung Diseases

KAZUHIRO YAMAGUCHI, MASAAKI MORI, AKIRA KAWAI, TOMOAKI TAKASUGI, YOSHITAKA OYAMADA, and EIICHI KODA

Departments of Medicine and Radiology, School of Medicine, Keio University, Tokyo, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Although impairment of gas exchange caused by ventilation-perfusion ( $V$ A/ $Q$ ) mismatch has been extensively analyzed, therehave been no systematic studies focused on determining the distributionsof diffusion properties in close connection with those of $V$ A/ $Q$ .We attempted to clarify the simultaneous distributions of $V$ A/ $Q$ and diffusion capacity to perfusion (D/ $Q$ ) in patients with idiopathicpulmonary fibrosis (IPF) or chronic obstructive pulmonary disease(COPD). To assess pathologic determinants causing functional abnormalities,we compared $V$ A/ $Q$ and D/ $Q$ distributions with the findings onhigh-resolution computed tomography. O ₂, CO₂, and CO togetherwith six foreign inert gases were used as indicator gases. Wetransformed the measured data on indicator gases in arterial bloodinto a continuous distribution of $Q$ in the $V$ A/ $Q$ -D/ $Q$ field.In IPF, active alveolitis or acinitis played a major role in producinglow D/ $Q$ regions impeding gas exchange via a diffusion limitation,whereas extensive fibrosis with minimal inflammation accountedfor low D/ $Q$ as well as low $V$ A/ $Q$ regions. In COPD, no regionswith low D/ $Q$ ratios were observed, but an abnormality in the $V$ A/ $Q$ distribution with low or high $V$ A/ $Q$ ratios was identified.Emphysematous lesions produced high $V$ A/ $Q$ regions, whereas peripheralairway involvement yielded low $V$ A/ $Q$ regions. These findingssuggest that hypoxemia in patients with IPF is caused by inhomogeneousdistributions of D/ $Q$ in combination with those of $V$ A/ $Q$ . Hypoxemiain patients with COPD is attributable primarily to inhomogeneitiesin $V$ A/ $Q$ rather than in D/ $Q$ distributions.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Based on the multiple inert gas elimination technique (MIGET), extensive studies of impaired gas exchange in patients withchronic lung diseases, including chronic obstructive pulmonarydisease (COPD) and interstitial lung diseases, have been performedby several investigators (1). The main conclusion derived fromthese studies is that the principal abnormality impeding pulmonarygas exchange is ventilation-perfusion ( $V$ A/ $Q$ ) inequality. Thisheld true irrespective of the underlying disease, suggesting thatthe reduced arterial P O₂ in various chronic lung diseases canbe accounted for primarily by $V$ A/ $Q$ mismatch, with only a minorcontribution from diffusion-limited O ₂ exchange. Recently, however,applying the MIGET to patients with interstitial lung diseases,Eklund and colleagues (6) and Agusti and coworkers (7) haveshown that abnormalities of gas exchange in interstitial lungdiseases are distorted by a diffusion-limited process during exerciseas well as at rest, highlighting the necessity of reevaluatingthe significance of impaired gas exchange caused by diffusionlimitation in patients with interstitial diseases. On the otherhand, recent studies done by Torres and colleagues (8), Barberaand coworkers (9), and Rossi and colleagues (10) have providedsupport for the earlier reports on COPD (3), all of which demonstratedthat diffusion limitations contribute minimally to the arterialhypoxemia in patients with COPD. All of the aforementioned studiesestimated the significance of diffusion-limited O₂ exchange bycomparing measured Pa_O₂ values with those predicted from MIGETanalysis (1). Although this procedure has been found to bepractically useful for evaluating the overall contribution ofdiffusion-limited gas exchange (2, 3, 6), it may notallow precise assessment of diffusion abnormalities. Determinationof the distribution of diffusion properties, represented by diffusingcapacity (D), appears to be important, along with determiningthe $V$ A/ $Q$ distribution, in clarifying the relationship betweenfunctional and morphologic abnormalities occurring in diseasedlungs. We recently devised a method permitting simultaneous estimationof the representative distribution of $V$ A/ $Q$ and the diffusingcapacity to perfusion (D/ $Q$ ) in the lung using nine gases asindicators (11). Applying this method to patients with a varietyof chronic lung diseases, we have attempted to clarify the distributionsof $V$ A/ $Q$ and of D/ $Q$ simultaneously and the significance of adiffusion limitation on impeded gas exchange in patients witheither idiopathic pulmonary fibrosis (IPF) or COPD. By means ofthe $V$ A/ $Q$ and D/ $Q$ distributions thus determined, we have endeavoredto shed light on the potential relation between pathologic alterationsand the resulting functional abnormalities in patients afflictedwith IPF or COPD.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Patient Selection

The protocols were approved by the institutional review board for human studies, and informed consent was obtained from thesubjects. We studied 52 patients with chronic lung disease sufferingfrom either IPF or COPD. In twenty-seven of them, IPF had beendiagnosed, and 25 had various manifestations of COPD. The diagnosisof IPF was established according to a modified version of thecriteria reported by Fulmer and colleagues (14). High-resolutioncomputed tomography (HRCT) was performed with the patient in thesupine position, holding a breath at deep inspiration, withoutcontrast medium. Images were obtained at 10-mm intervals fromthe apex to the diaphragm (2.0-mm section thickness). Each imagewas photographed at window levels of $-$ 500 Hounsfield units (HU)and window widths of 1,500 HU. Patients suspected of having IPFwere examined by transbronchial lung biopsy (TBLB) to assess thepathologic abnormalities in their lungs. TBLB specimens were generallyobtained from the right lower lung field. In addition, isotopeexaminations with gallium (Ga) were performed in 21 patients.Because precise determination of the IPF disease stage from TBLBspecimens is rather difficult because of limited sampling capacity,we classified the lungs of patients with IPF mainly on the basisof HRCT findings. Recent studies done by Muller and colleagues(15) as well as by Nishimura and coworkers (16) have shownthat HRCT appearance predicts with considerable accuracy lunghistologic features obtained on open lung biopsy, i.e., a ground-glasspattern correlates well with cellular histopathology (alveolitisand/or acinitis), whereas a reticular pattern suggests extensivefibrosis. Therefore, we categorized the patients with IPF intothree groups based on HRCT findings (17). Group I (n = 6): ground-glasswith no obvious reticular pattern (predominantly inflammatoryalveolitis/ acinitis with little fibrosis); Group II (n = 9):reticular pattern associated with honeycombing cysts but withoutdistinct ground-glass opacities (predominantly fibrosis with littlealveolitis/acinitis); Group III (n = 12): a mixture of ground-glassand reticular patterns (coexistence of alveolitis/acinitis withfibrosis). Classification of the patients with IPF from HRCT findingswas independently made by two of the investigators (one is a physicianand the other is a radiologist) who were blind to the detailsof gas exchange and pulmonary function studies. Only the patientscategorized into the same group by the two observers were usedfor the further analysis.

Subjects with FEV₁/FVC (FEV₁%) below the 95% confidence limit of the values predicted from the equation constructed from thedata obtained in nonsmoking Japanese volunteers, with no pulmonarydisorders (18), were assumed to have clinically significantchronic airflow obstruction (CAO). The classification of COPDconformed to that proposed by the American Thoracic Society (19),i.e., chronic pulmonary emphysema (CPE), chronic bronchitis (CB),and peripheral airway disease (PAD). Emphysematous lesions wereexamined by means of HRCT. CT images (2.0-mm section thickness)obtained at the upper (midportion of the intrathoracic trachea)and lower lung field (1 cm above the diaphragm) were photographedat levels of $-$ 500 HU and window widths of 1,500 HU. The extentof emphysema in each section was quantified by calculating therelative area of low CT density (%LDA) using the attenuation maskprogram (20). According to Muller and colleagues (20) andKinsella and coworkers (21), LDA was defined as an area witha CT density below $-$ 910 HU. An average value of the %LDA in theupper and lower lung zones was used as an objective measure ofthe extent of emphysema. Preliminary examinations of the %LDAof normal volunteers (nonsmokers 28 to 73 yr of age, n = 28) indicatedthat the average values and 95% confidence limits of %LDA were6.0 and 19.8%, respectively. In addition, %LDA values in normalsubjects were independent of age. Therefore, we assumed that subjectswith an average %LDA of more than 20% would have pathologicallysignificant emphysematous changes in their lungs. On the basisof these findings, we classified the subjects with significantCAO and pathologic %LDA but with no other remarkable abnormalitieson chest HRCT and minimal productive cough as CPE. Although itis very difficult to precisely classify subjects with chronicbronchitis (CB), we defined such subjects as having persistentcough and expectoration of at least a 3-mo duration for two successiveyears with sustained CAO (19) but without apparent chest radiographic,including HRCT, abnormalities. PAD was considered to exist whenCAO with no emphysematous changes but with bronchiolar abnormalitieson HRCT was evident. Bronchiolar abnormalities were based on therecognition of either centrilobular diffuse fine nodules on HRCT,corresponding to bronchiolitis in the acini, or thickened bronchiolarwalls with a diameter of less than 3 mm, corresponding to abnormalitiesof membraneous bronchioles (22). Among the 13 patients manifestinga CPE component, seven and six had CPE only and CPE associatedwith CB, respectively, There were five subjects who had predominantlyPAD, and seven had both PAD and CB components. Among the subjectsstudied, there were no patients with sustained CAO clearly attributableto CB alone. Recognition of emphysema and bronchiolar abnormalitieson HRCT were again made by the two observers without allowingthem to know the results of gas exchange studies and pulmonaryfunction tests.

Protocol

As ventilatory indicators, we measured VC, FVC, and the expiratory flow-volume curve by means of an electronic spirometer(MFR-8200; Nihon Kohden, Tokyo). Respiratory impedance was examinedby the oscillation method (MZR-4000; Nihon Kohden). FRC, RV, andTLC were measured by the helium-dilution method (Chestac-55V;Chest, Tokyo). Pulmonary function tests were performed within2-wk before or after right heart catheterization. Steady-statediffusing capacity (DL_CO) and AaPO₂ were estimated from the dataobtained during right heart catheterization.

Subjects were placed in a supine position, and a balloon-tipped Swan-Ganz catheter (7F) was introduced into the femoral veinand advanced into the pulmonary artery. An arterial cannula wasinserted into the femoral artery. The patients were given a mixtureof 21% O₂ and 0.1% CO in N₂ as the inspired gas, and saline containinga small quantity of six foreign inert gases, including sulfurhexafluoride (SF6), ethane, cyclopropane, halothane, diethyl ether,and acetone was infused via the antecubital vein at a rate of2 ml/min. After a steady state had been established, samples ofexpired gas and arterial and mixed venous blood were taken simultaneously.We measured the concentrations of O₂ and CO₂ in the expired gaswith a mass spectrometer (WSMR-1400; Western, Chiba), and PO₂,PCO₂, and pH in the blood sample were determined with electrodes(Model 1306; Instrumentation Laboratories, Lexington, MA). Inertgases, with the exception of SF6, were analyzed with gas chromatographequipped with a flame ionization detector (FID) (G.C. 163; Hitachi,Tokyo). SF6 measurements were made with a gas chromatograph withan electron capture detector (G.C. 163; Hitachi). We determinedthe CO concentration in the sample with FID after converting COinto methane using nickel as a catalyst (MT-20; Gasukuro Kogyo,Tokyo).

$V$ A/Q· and D/Q· Analysis

The data obtained during right heart catheterization were analyzed by a recently developed numerical method (11). Briefly,this analytical method is designed to minimize the sum of squaresof deviation (SSQ) between the measured arterial concentrationsof the nine indicator gases and the values predicted from a lungmodel in which gas exchange efficiency is taken to be dominatedby $V$ A/ $Q$ and D/ $Q$ distributions. To minimize the SSQ, we modifiedthe enforced smoothing technique elaborated by Wagner and Evans(23, 24). Twenty lung units were assumed along the $V$ A/ $Q$ and along the D/ $Q$ axis. The $V$ A/ $Q$ ratio is dimensionless, butD/ $Q$ is expressed in milliliters ( STPD)/ (ml · mm Hg). Althoughindicator gases have their own D values, they are mutually relatedvia Krogh diffusion constants. Therefore, the D values of indicatorgases were normalized to that of O₂ in respective lung units.Our previous study (12) demonstrated that the combination ofsix inert gases, O₂, CO₂, and CO allowed characterization, withconsiderable reliability, of the behavior of gas exchange attributedto lung units having $V$ A/ $Q$ ranging from 0.005 to 100 and D/ $Q$ ranging f rom 0.00001 to 1.0. Furthermore, our previous results(11, 12) suggested that diffusion-limited O₂ exchange occursin lung units with D/ $Q$ less than 0.001 regardless of their $V$ A/ $Q$ values. Therefore, the regions with D/ $Q$ of less than 0.001 weredefined as low D/ $Q$ regions. The regions with $V$ A/ $Q$ less than0.1 were taken to be low $V$ A/ $Q$ regions in which the units withshunted blood were included. The regions with $V$ A/ $Q$ exceeding10 were taken as high $V$ A/ $Q$ areas. These regions included deadspace. The final result was expressed as a virtually continuousdistribution of $Q$ in the $V$ A/ $Q$ -D/ $Q$ field. The amount of V·Ain each lung unit was calculated from the $Q$ and $V$ A/ $Q$ values.

Pa_O₂ and AaPO₂ Predicted from MIGET Analysis

To practically confirm the accuracy of the current method in estimating impaired gas exchange caused by the diffusion limitationcontribution to overall arterial hypoxemia, we additionally calculatedthe predicted Pa_O₂ using the well-established MIGET analysis (1,23, 24), assuming that alveolar PO₂ in each gas exchange unitis in equilibrium with that in end-capillary blood. From the predictedPa_O₂, we estimated AaPO₂ (predicted AaPO₂) and compared this valuewith that obtained from the actually measured Pa_O₂ (measured AaPO₂).Mean alveolar PO₂ (PA_O₂) was defined as the ventilation-weightedvalue of alveolar PO₂ in respective gas exchange units, and usedfor calculating both measured and predicted AaPO₂. Predicted AaPO₂was taken to be the value governed by the $V$ A/ $Q$ mismatch alone,whereas measured AaPO₂ was assumed to be determined by diffusion-limitedgas exchange as well as by $V$ A/ $Q$ mismatch. Difference betweenmeasured and predicted AaPO₂ divided by measured AaPO₂ was usedas the indicator exhibiting the relative contribution of diffusionlimitation to overall gas exchange impairment.

Statistical Analysis

Whenever possible, we compared the data obtained from IPF and those from COPD using ANOVA followed by multiple comparisonanalysis with the Scheffe examination. When the data did not showan equal variance, however, we applied the Kruskal-Wallis testto assess statistical significance. Differences in measured AaPO₂and predicted AaPO₂ from the MIGET analysis were estimated bythe paired t test or Wilcoxon's test. A p value less than 0.05was considered to be significant. Values are presented as means± SD.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

HRCT Findings, Ventilatory Functions, and Blood Gas Determinations in IPF

TBLB specimens obtained from Group I of the patients with IPF showed active inflammation in the acini, which was pathologicallyconsistent with desquamative interstitial pneumonia with markedcellular accumulation in distal air spaces with minimal interstitialthickening. The subjects exhibited augmented pulmonary Ga uptakeand marked ground-glass opacities with minimal honeycombing cystson HRCT. Group II patients had an extensive reticular patternassociated with honeycombing cysts but showed minimal ground-glassopacities on HRCT. TBLB specimens revealed findings compatiblewith interstitial fibrosis with honeycombing, in which alveolarcollapse, thickened air-space walls, and minimal interstitialcellular proliferation were observed. Pulmonary Ga uptake wasindistinct in these patients. HRCT obtained in the Group III patientsdemonstrated an extensive reticular pattern with significant ground-glassopacities. TBLB specimens obtained from lesions showing the reticularpattern with honeycombing and from an area of ground-glass opacitiesrevealed, respectively, interstitial fibrosis with few inflammatorycells and cellular infiltration of the alveolar walls in additionto desquamation within the alveolar spaces. Pulmonary Ga uptakein Group III patients showed patchy augmentation.

Lung volumes, including TLC and FRC, were significantly reduced in the Group II and Group III patients compared with thosein Group I; %VC values in Groups II and III were significantlysmaller than those in Group I (Table 1). Other ventilatory parametersdid not differ among the three IPF subgroups. FEV₁% values, peakflow (PFR), and airflow rates at 50% of FVC ( $V$ ₅₀) in subjectswith IPF were well preserved (Table 1).

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TABLE 1

PULMONARY FUNCTION TESTS (IPF AND COPD) AND CT FINDINGS (COPD)^*

Arterial oxygenation was significantly reduced in Groups II and III, resulting in widened AaPO₂ in these subjects comparedwith Group I (Table 2). Pa_CO₂, blood gas determinations in mixedvenous blood, and steady-state diffusing capacity (DL_CO) did notdiffer among the three groups. Pulmonary hemodynamic data, includingcardiac output, pulmonary arterial pressure, and vascular resistance,were statistically the same in the three groups (Table 2).

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TABLE 2

BLOOD GAS, PULMONARY HEMODYNAMICS, AND HEMATOLOGIC DATA OF PATIENTS WITH IPF AND COPD^*

$V$ A/ $Q$ and D/ $V$ Distributions in IPF

The patients with IPF in Group I, who had distinct ground-glass opacities with no obvious honeycombing cysts on HRCT, exhibitedmodest hypoxemia (Table 2). $Q$ distributions along the D/ $Q$ axisin these subjects were markedly inhomogeneous, i.e., bimodal,and D/ $Q$ regions lower than 0.001 did exist, receiving, on theaverage, 7% of total cardiac output (Figure 1 and Table 3). Onthe other hand, $Q$ distributions along the $V$ A/ $Q$ axis in thesesubjects were fairly homogeneous, i.e., only 3% of cardiac outputwas distributed to remarkably low $V$ A/ $Q$ regions, including theshunt compartment. High $V$ A/ $Q$ regions received 39% of total ventilation,most of which was distributed to the dead space compartment (Figure1 and Table 3).

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Figure 1. Representative distributions of $Q$ in a $V$ A/ $Q$ -D/ $Q$ field estimated in IPF patients. X axis: D/ $Q$ (ml/ (ml · mm Hg)); Y axis: $V$ A/ $Q$ (dimensionless); Z axis: fractional perfusion. ( A) GroupI patient: bimodal D/ $Q$ distribution with a modest abnormalityin the $V$ A/ $Q$ distribution. ( B) Another patient with Group I: $V$ A/ $Q$ and D/ $Q$ distributions qualitatively the same as thoseof (A). ( C ) Patient from Group II: bimodal abnormality in the $V$ A/ $Q$ distribution with low $V$ A/ $Q$ regions. The D/ $Q$ distributionwas unimodal, but with recognizable low D/ $Q$ regions. ( D) Patientwith Group III features: low and high $V$ A/ $Q$ regions associatedwith low D/ $Q$ regions.

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TABLE 3

CHARACTERISTICS OF D/Q· AND V · A /Q · DISTRIBUTIONS IN PATIENTS WITH IPF AND COPD^*

Group II subjects, with an extensive reticular pattern associated with honeycombing cysts but minimal ground-glass opacitieson HRCT, showed more severe hypoxemia than that seen in GroupI (Table 2). The $Q$ distributions along the D/ $Q$ axis in GroupII were unimodal, but broad and relative perfusion of low D/ $Q$ regions averaged 10%, whereas their $V$ A/ $Q$ distributions weremarkedly abnormal, and low and high $V$ A/ $Q$ regions received, respectively,15% of cardiac output and 51% of total ventilation, both valuesbeing significantly greater than those obtained in the Group Isubjects (Figure 1 and Table 3).

Group III patients with IPF, demonstrating a mixture of the reticular pattern and ground-glass opacities on HRCT, showed broadbut unimodal $Q$ distributions along the D/ $Q$ axis. The regionswith D/ $Q$ of less than 0.001 received 16% of cardiac output. Therelative perfusion of low D/ $Q$ regions was significantly largerin Group III than in Group II, though the extent of hypoxemiadiffered minimally between the two groups (Table 2). $Q$ distributionsalong the $V$ A/ $Q$ axis in Group III were qualitatively similarto those observed in Group II (Figure 1). Twelve percent of cardiacoutput was distributed to low $V$ A/ $Q$ regions, whereas 56% of totalventilation went to high $V$ A/ $Q$ regions (Table 3). These valueswere essentially the same as those obtained in Group II but significantlylarger than those in Group I.

HRCT Findings, Ventilatory Functions, and Blood Gas Determinations in COPD

The %LDA values in patients in whom PAD dominated were le ss, whereas those in the patients with CPE were distinctly greater,more than 20% corresponding to the upper limit of %LDA obtainedfor nonsmoker volunteers (Table 1). Although %LDA values in thepatients with CPE were significantly greater than in those witheither PAD or PAD associated with CB (PAD+CB), there were no differencesin %LDA values between CPE and CPE associated with CB (CPE+CB);%LDA values were comparable in the patients with PAD and thosewith PAD+CB (Table 1).

There were no differences in any ventilatory parameters between the CPE and CPE+CB groups. Nor did ventilatory indices differbetween the PAD and the PAD+CB groups. TLC and FRC in the patientswith CPE were clearly increased compared with those in patientswith PAD, whereas RV/TLC and %VC values did not differ betweenthese groups of patients. Although FEV₁, PFR, and $V$ ₅₀ deterioratedin all patients with COPD, they were significantly greater inthe group with PAD than in the group with CPE.

With the exception of Pa_O₂, AaPO₂, and DL_CO, there were no differences in blood gas determinations or pulmonary hemodynamicsbetween the CPE and the PAD groups (Table 2). In addition, theseparameters did not differ either between CPE and CPE+CB or betweenPAD and PAD+CB. Arterial hypoxemia was more severe, whereas reducedDL_CO was less evident, in patients with PAD than in those withCPE (Table 2).

$V$ A/ $Q$ and D/ $Q$ Distributions in COPD

There were no statistically significant differences in any values reflecting D/ $Q$ and $V$ A/ $Q$ distributions between patientswith CPE and those with CPE +CB. Therefore, quantitative indicesof D/ $Q$ and $V$ A/ $Q$ distributions were combined in these patients.The same held true for the D/ $Q$ and $V$ A/ $Q$ distributions in patientswith PAD and for those in patients with PAD +CB (Figure 2).

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Figure 2. $V$ A/ $Q$ and D/ $Q$ distributions in COPD. ( A) Patient with CPE only; bimodal $V$ A/ $Q$ distribution with high $V$ A/ $Q$ regions. Therewere no low D/ $Q$ regions. ( B) Patient with both CPE and CB components;inhomogeneity along the $V$ A/ $Q$ axis, but no low D/ $Q$ regions.( C ) Patient with PAD only; bimodal $V$ A/ $Q$ distribution in combinationwith low $V$ A/ $Q$ . There were no regions with low D/ $Q$ ratios. (D) Patient with both PAD and CB features; bimodal abnormalityin the $V$ A/ $Q$ distribution with low $V$ A/ $Q$ areas. No low D/ $Q$ regions were found.

Patients with COPD and CPE (i.e., CPE or CPE+CB) exhibited little perfusion of either low D/ $Q$ or low $V$ A/ $Q$ areas, but theyhad significant ventilation to high $V$ A/ $Q$ areas in proximityto the dead space, resulting in minimal abnormality along theD/ $Q$ axis but a bimodal abnormality along the $V$ A/ $Q$ axis. Relativeperfusion of low D/ $Q$ regions was less than 0.1%, whereas low $V$ A/ $Q$ regions received 4% of cardiac output. The sum of relativeventilation of high $V$ A/ $Q$ regions, including the dead space,amounted to 57% of total ventilation (Table 3).

Although there was no perfusion entering low D $Q$ regions in patients with COPD and prominent PAD features (i.e., PAD and PAD+CB),low $V$ A/ $Q$ regions in these patients received 18% of cardiac output,the value being significantly greater than that obtained in patientswith primarily CPE (Table 3). Relative ventilation distributedto high $V$ A/ $Q$ regions in patients with PAD was not augmentedand was found to account for 37% of total ventilation, most ofwhich was made up of dead space, such that D/ $Q$ distributionswere essentially normal, whereas $V$ A/ $Q$ patterns were bimodal,representing low $V$ A/ $Q$ regions in patients with PAD (Figure 2).

Comparison between Measured and Predicted AaPO₂ in MIGET Analysis

Our patients with IPF showed consistently lower predicted than measured AaPO₂, whereas no significant differences betweenthese two variables were seen in patients with COPD (Figure 3).Measured and predicted AaPO₂ indicated that 34 and 66% of theAaPO₂ in the Group I patients with IPF were, respectively, dueto diffusion-limited O₂ exchange and $V$ A/ $Q$ mismatch. In GroupsII and III patients with IPF, 15 and 21% of the AaPO₂, respectively,were caused by diffusion-limited O₂ exchange. The relative contributionof diffusion limitation to overall AaPO₂ was the greatest in GroupI patients with IPF, but it was small in Groups II and III. TheAaPO₂ in COPD was primarily attributable to $V$ A/ $Q$ mismatch witha minimal contribution from diffusion-limited O ₂ exchange.

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Figure 3. Effect of diffusion-limited gas exchange on AaPO₂ in IPF. Group I: n = 6; Group II: n = 9; Group III: n = 12. Values presentedare means. Closed circles indicate individual data points. Asterisksindicate significantly smaller than the values obtained for GroupI patients.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Critique of Methods

Using O₂, CO₂, CO, and six foreign inert gases, we attempted to predict a representative distribution of $Q$ in the $V$ A/ $Q$ -D/ $Q$ field in terms of the newly developed analytical method (11- 13).Minimization of the SSQ was made by applying the enforced smoothingtechnique (23), by which a stable solution can be obtained evenwhen the number of unknowns exceeds that of equations. Thus, wefound that the newly developed analytical procedure allows theessential features of D/ $Q$ and $V$ A/ $Q$ distributions with a unimodalor a bimodal pattern, along either the D/ $Q$ or the $V$ A/ $Q$ axis,to be defined (12). Separation of $Q$ distribution along the $V$ A/ $Q$ axis was quantitatively coincident with that of the MIGETanalysis. $Q$ distribution along the D/ $Q$ axis was discernibleas long as $Q$ peaks were situated at a distance of a decade inthe $V$ A/ $Q$ -D/ $Q$ field. Although the detectable ranges as wellas the limits of $V$ A/ $Q$ and D/ $Q$ distributions were theoreticallyexamined in our previous report (12), the crucial issue is inclusionof respiratory gases into the estimation of the distributions,leading to the difficulty in predicting the accuracy of the method.Because O₂ and CO₂ were indispensable to determining the $V$ A/ $Q$ and D/ $Q$ distributions and were not withheld from the calculations,they could not be used for looking into the validity of the numericalapproach. Therefore, we examined the applicability and limitsof our method in practical terms, i.e., we compared $Q$ distributionsin the $V$ A/ $Q$ -D/ $Q$ field obtained from patients with differencesbetween the measured AaPO₂ and that predicted from the classicMIGET analysis (Figure 3). In patients with IPF, measured AaPO₂values were significantly greater than those predicted from theMIGET, indicating the existence of diffusion-limited O₂ exchangein IPF. This finding is highly consistent with the evidence thatmost patients with IPF exhibit significant perfusion of low D/ $Q$ regions (Figure 1 and Table 3). On the other hand, patients withCOPD did not show significant differences between measured andpredicted AaPO₂, suggesting that there may be little or no diffusion-limitedO₂ exchange in COPD. Again, this finding supports the resultsof $V$ A/ $Q$ and D/ $Q$ distributions observed in COPD, i.e., no significantperfusion of low D/ $Q$ regions (Figure 2 and Table 3). On thebasis of these observations, we believe that our numerical approachdoes provide a representative description of the abnormal gasexchange caused by $V$ A/ $Q$ and D/ $Q$ inhomogeneities, though itcertainly has the limitations.

To calculate the alveolar gas tension of an indicator gas in a given lung unit, we assumed the absence of stratified inhomogeneitiescaused by impaired diffusive gas mixing in acinar airways. Therefore,the current method would presumably be valuable for estimatingdiffusive resistance imposed by the alveolar-capillary membranebut not for detecting increases in gas phase diffusive resistanceoccurring within the airways in diseased lungs (26).

Limitation of O₂ Exchange by Diffusion in IPF and COPD

We found that diffusion-limited O₂ exchange causes arterial hypoxemia in patients with IPF but not in those with COPD (Figures1-3 and Table 3). The observation of an O₂ diffusion limitationin patients with IPF at rest is at variance with earlier reports(2), which included patients with a wide variety of interstitialpneumonias, but it is in accordance with the recent studies donein carefully selected patients (6, 7). Eklund and colleagues(6) studied the importance of O₂ diffusion- limited exchangein patients with sarcoidosis, whereas Agusti and coworkers (7)used patients with IPF. These investigators (6, 7) confirmedthat, as in the present study, O₂ diffusion-limited gas exchangeis one of the factors causing arterial hypoxemia in patients withinterstitial diseases, even in the resting state. On the otherhand, we found that diffusion limitation contributes minimallyto Pa_O₂ reduction in patients with COPD, which is highly consistentwith earlier reports (3, 5, 8).

Relation between Morphologic Alterations and $V$ A/ $Q$ and D/ $Q$ Inequalities in IPF

The patients with remarkable ground-glass opacities on HRCT (Group I) exhibited bimodal D/ $Q$ distributions, with D/ $Q$ areaslower than 0.001 but only modest abnormalities along the $V$ A/ $Q$ axis (Figure 1 and Table 3). These findings suggest that ground-glassopacities, corresponding to active alveolitis/acinitis, produceprimarily low D/ $Q$ regions that significantly restrict gas exchangevia a diffusion limitation. As reported by Gottlieb and Snider(30), active alveolitis may allow cellular and noncellular exudateto accumulate in both alveolar spaces and the interstitium. Thismay increase the diffusion path in aqueous media in which thediffusivity of gases falls by a factor of 10⁴ in comparison with that in gaseous media (31). Modest $V$ A/ $Q$ abnormalities in the Group I patients may be due to incompletecollapse and distortion of air spaces, probably caused by exudatein alveolar spaces. Although the relative contribution of diffusion-limitedO ₂ exchange to impairment of overall gas exchange was much higherin Group I than in Groups II and III (Figure 3), arterial hypoxemiaand widening of AaPO₂ were less marked in Group I (Table 2),indicating that impaired O₂ exchange may be highly sensitive to $V$ A/ $Q$ inhomogeneities rather than to a diffusion limitation.

Patients with IPF who were allocated to Group II, which was characterized by an extensive reticular pattern but minimal ground-glassopacities on HRCT, demonstrated moderate arterial hypoxemia associatedwith both low $V$ A/ $Q$ and low D/ $Q$ regions (Tables 2 and 3 andFigure 1), such that the hypoxemia in these patients may be attributableto inhomogeneous distribution of $V$ A/ $Q$ as well as D/ $Q$ . Thesefindings lend support to the idea that the reticular pattern onHRCT, corresponding to fibrotic alterations, causes distinct abnormalitiesalong both the $V$ A/ $Q$ and the D/ $Q$ axis. Cassan and colleagues(32), in a morphometric study of patients with IPF and distinctfibrosis, found that the harmonic mean thickness of the alveolar-capillarymembrane increased by 70%. They also found that mean alveolarsurface area was reduced to 41% and capillary surface area to39% of the values in normal control subjects, suggesting thatdiffusion properties were markedly distorted in IPF with fibrosis.An increase in the diffusion path caused by enlarged interstitialspaces and a decrease in the effective surface area result inlow D/ $Q$ regions. Honeycombing cysts, i.e., remodeling of thelung architecture, may create poorly ventilated air spaces, producinglow $V$ A/ $Q$ regions (30). Augmented high $V$ A/ $Q$ regions in GroupII (Figure 1 and Table 3) may be attributable to redistributionof pulmonary blood flow from severely affected portions in lowerlung fields to those maintaining relatively normal structuresin upper lung fields (30).

Patients in Group III, who had features of both Group I and Group II, demonstrated inhomogeneities along both the $V$ A/ $Q$ andthe D/ $Q$ axis (Figure 1 and Table 3). Augmentation of low D/ $Q$ regions in Group III may be attributable to combined impairmentsin diffusion properties, including the accumulation of exudatewithin air spaces (a possible cause in Group I) and increasedthickening of alveolar septa as well as diminished surface areasfor gas exchange (a possible cause in Group II). Arterial hypoxemiaand relative perfusion of low $V$ A/ $Q$ regions did not differ significantlybetween Groups II and III, though perfusion of low D/ $Q$ regionsin Group III significantly exceeded that in Group II (Figure 1and Table 3). These findings again indicate that $V$ A/ $Q$ inhomogeneitiesare more important than diffusion-limited gas exchange in determininga decline in Pa_O₂when significant abnormalities in $V$ A/ $Q$ andD/ $Q$ distributions coexist.

Relation between Morphological Alterations and $V$ A/ $Q$ and D/ $Q$ inequalities in COPD

General characteristics of $V$ A/ $Q$ and D/ $Q$ distributions in patients with COPD can be summarized as follows (Figure 2): (1)irrespective of the COPD subtype, an essential abnormality ispresent along the $V$ A/ $Q$ axis, whereas there is virtually no abnormalityalong the D/ $Q$ axis; (2) patients with CPE have fairly broad distributionsof $Q$ along the $V$ A/ $Q$ axis accompanied by regions with $V$ A/ $Q$ values exceeding 10 but no regions with $V$ A/ $Q$ values below 0.1;( 3) patients with PAD have low $V$ A/ $Q$ but no high $V$ A/ $Q$ regions.

Although we did not have an opportunity to analyze $V$ A/ $Q$ and D/ $Q$ distributions in patients with only CB, the results obtainedin patients with CB in combination with either PAD or CPE demonstratedthat the persistent cough and hypersecretion associated with CBmay not be essential for inducing an inhomogeneous $V$ A/ $Q$ distribution(Figure 2 and Table 3). The subjects who met the criteria forPAD and CB were found to have low $V$ A/ $Q$ areas only, whereas thosewho had features of CPE and CB solely showed high $V$ A/ $Q$ regions.These findings indicate that the most important pathologic factorproducing $V$ A/ $Q$ distribution abnormalities in COPD is eitheremphysematous changes (high $V$ A/ $Q$ areas) or peripheral airwayinvolvement (low $V$ A/ $Q$ areas), whereas CB per se produces minimalinhomogeneity in $V$ A/ $Q$ distributions.

Although emphysematous regions would be expected to decrease the effective surface area for gas exchange (33), we foundno evidence of the existence of low D/ $Q$ areas in subjects withCPE. Thurlbeck and colleagues (33) analyzed alveolar surfaceareas in patients with emphysema of various degrees and showedthat the average alveolar surface area in the patients with pathologicallysignificant emphysematous lesions was 77% of the predicted value,indicating that the extent of alveolar surface area diminutionin emphysema might be much smaller than that in interstitial pneumonia.Furthermore, emphysematous alterations may not expand the diffusionpath. These observations may explain why the subjects with CPEin the current study did not show significant regions with lowD/ $Q$ values.

In conclusion, IPF primarily causes significant abnormalities in D/ $Q$ distributions associated with the formation of low $V$ A/ $Q$ regions. Active alveolitis and/or acinitis appear to be of majorimportance in producing low D/ $Q$ regions, whereas fibrotic alterationsappear to cause both low D/ $Q$ and low $V$ A/ $Q$ regions. The mainabnormality in COPD is an inhomogeneous distribution of $Q$ alongthe $V$ A/ $Q$ axis but not along the D/ $Q$ axis. Emphysematous lesionsyield high $V$ A/ $Q$ regions, whereas peripheral airway involvementproduces low $V$ A/ $Q$ regions.

	Footnotes

Correspondence and requests for reprints should be addressed to Kazuhiro Yamaguchi, M.D., Department of Medicine, School of Medicine, Keio University, 35 Shinanomachi, Shinjuku-ku, Tokyo 160, Japan.

(Received in original form July 22, 1996 and in revised form January 15, 1997).

	References

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