Development of effective treatment for human pulmonary hypertension (PHT) has been hampered by an incomplete understanding of its pathogenesis. We present a rabbit model of PHT based on platelet-activating factor (PAF), a potent phospholipid autacoid synthesized by a variety of mammalian cells. PAF was intravenously infused into rabbits for 4 wk. After the infusion, rabbits underwent pulmonary arterial catheterization for hemodynamic evaluation, and lung tissue was morphometrically analyzed for changes in cross-sectional areas of intima and media, and alteration in number of small pulmonary arteries. The heart was evaluated by the method of Fulton for right ventricular hypertrophy. Mean pulmonary arterial pressure was 20 +/- 2 mm Hg in PAF-treated rabbits compared with 12 +/- 1 mm Hg in vehicle-treated control rabbits. PAF induced a trend toward loss of small muscular pulmonary arteries, measuring 50 to 200 microns in diameter, and right ventricular hypertrophy. There was a decrease in circumference of the internal elastic lamina in vessels accompanying alveolar ducts and in alveolar walls, and a relative increase in the intimal cross-sectional area of these vessels. These lesions were associated with a trend toward medial hypertrophy. No increase in lung water was found. Pressure changes occurred in the absence of alterations in hematocrit and arterial partial pressure of oxygen. We conclude that chronic intravenous infusion of PAF, a naturally synthesized substance, into rabbits provides a potentially useful model for the study of vascular changes associated with PHT.
Recent availability of computerized image analysis has fostered hope that barium injection and landmarking of pulmonary arteries would be unnecessary for morphometric assessment when using this technique. We reasoned that if barium injection altered morphometric variables, it would do so in a linear fashion correlating with incremental increases in injection pressure of the barium. The two goals of the present study were to determine whether barium injection into arteries affected morphometric measurements and to determine whether incremental increases in injection pressure correlated with alterations in morphometric measurements in a linear fashion. Computerized image analysis was used to measure the internal elastic lamina (IEL) and external elastic lamina (EEL). Medial area (MA), luminal area (LA), percentage of medial thickness, IELͱMA, and idealized LA were calculated. Barium injection did not alter morphometric variables in a linear fashion correlating with incremental increases in injection pressure of the barium except the percentage of arteries that filled with barium. Maximum recruitment for pre-acinar arteries occurred at 40 mmHg pressure and 60 mmHg distending pressure for intra-acinar arteries. Incremental increases in injection pressure did not affect IEL, EEL, or calculated morphometric variables. However, IEL, medial thickness, and MA were all smaller in injected vessels than in uninjected vessels. IELͱMA and the ratio of measured vs. idealized LA were both increased in injected lungs. We suspect that vascular injection selects for evaluation, a population of smaller, thin-walled vessels, which in the uninjected lungs are collapsed and hence excluded from analysis. Anat. Rec. 252:92-101, 1998. 1998 Key words: computer-assisted diagnosis; pulmonary artery; pulmonary circulation; pulmonary hypertension; vascular resistance; vascular smooth muscle Computerized interactive morphometric analysis entails measurement of the internal elastic lamina (IEL) circumference and the outer limit of the media, often demarcated in larger vessels, by the external elastic lamina (EEL). The computer then, by using integrals, calculates the actual area occupied by the media and lumen. Computer-assisted morphometric analysis is based on the premise that medial cross-sectional area and IEL circumference of the vessel wall are independent of intravascular distending pressure, thus raising the hope that the practice of uniform vascular distension would no longer be necessary (Cook and Yates, 1972). Traditional morphometric analysis requires preparation of the lungs under uniform conditions to ensure accurate comparisons. Lungs for morphometric evaluation are traditionally fixed after intravascular injection of a barium sulfate/gelatin suspension at a standard supraphysiologic pressure (73 mmHg).
The role of vasoreactivity in PAF-induced pulmonary hypertension (PHT) was assessed in isolated, perfused rabbit lungs. We evaluated the steady-state pulmonary vascular response to five vasoconstrictors: PGF2 alpha, norepinephrine, angiotensin II, PAF, and KCl. Pulmonary arterial pressure and pulmonary vascular resistance (PVR) were significantly greater in lungs of rabbits treated with PAF for 28 days than in control rabbits in response to PGF2 alpha and norepinephrine. When resistance was partitioned by the vascular occlusion method, at baseline the vascular resistance was equally distributed between arterial and venous segments in both experimental groups. Arterial resistance accounted for approximately 76% of PVR during norepinephrine injection and 60% of PVR during PGF2 alpha injection in PAF-treated lungs. Whereas arterial resistance accounted for approximately 63% of PVR during norepinephrine injection and 52% of PVR during PGF2 alpha injection in control lungs, there was no significant difference in the response to angiotensin II, acute PAF, and KCl in lungs from chronic PAF-treated rabbits compared with responses in control rabbit lungs, though the pressor response to acute PAF tended to be blunted in PAF-treated lungs. Chronic PAF treatment results in enhanced pulmonary arterial reactivity to selected autacoids in isolated perfused lungs.
We have previously demonstrated that chronic intravenous platelet-activating factor (PAF) induces morphologic remodeling of pulmonary arteries characterized by a decrease in internal and external elastic lamina circumference, pulmonary arterial contracture, and internal elastic lamina duplication. The mechanism of PAF-induced arterial contracture is unknown. In this study we determined whether PAF caused arterial contracture through cell loss by calculating the number of cell nuclei/total cross-sectional area of arteries. The nuclear ratio was increased in intra- and preacinar pulmonary arteries of PAF-treated rabbits. Hydroxyproline content of lungs stratified by anatomic region was significantly reduced in intra-acinar tissue of PAF-treated rabbits, indicating that PAF-induced vascular contracture was associated with loss of interstitial collagen. We next tested whether these morphologic alterations were associated with decreased pulmonary vascular compliance and increased resistance. Compliance and resistance were determined in isolated, perfused lungs from rabbits chronically treated with PAF. Compliance was calculated: (1) from the slope of the venous occlusion trace (CVO), (2) by increasing left atrial pressure (CLA), (3) by increasing flow (CHF), and (4) by the classic static technique (CAV) of adding volume (2 ml) to a passively drained lung. Vascular compliance was significantly reduced in PAF-treated lungs when measured by all four methods; however, pulmonary vascular resistance was unchanged. We conclude that structural changes that result from chronic intravenous PAF infusion affect the elastic modulus to a greater extent than factors that influence pulmonary vascular resistance.
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