Study of the hysteresis phenomenon in canine anterior cruciate ligaments

Preconditioning is now in common use in biomechanical testing of soft connective tissues. During the first few cycles the tissue behaviour is characterized by a decreasing hysteresis area. However, little is known about the changes occurring during the preconditioning process. The purpose of this study was to investigate the hysteresis phenomenon of ligaments as it is influenced by preconditioning and in vitro enzymatic treatment. Canine anterior cruciate ligament (ACL) was chosen because its mechanical properties and microstructure are relatively well known. A series of experiments were conducted to clarify some of the hysteresis features by combining mechanical testing, enzymatic digestions and pH variations. The area within the hysteresis loops (energy absorption, EA) was measured before and after each treatment. The results showed that the EA before preconditioning is not modified by elastase treatment, however, it was significantly reduced after preconditioning. The fractional EA lost during the preconditioning process increased significantly as compared to the controls. This may be explained by the destruction of elastin, which plays a significant role in the elasticity of ligaments. It was found that hyaluronidase treatment did not significantly affect the hysteresis of preconditioned ligaments. However, the EA during the first cycle decreased significantly as a result of uronic acid digestion leading probably to an exhaustion of the viscous component of the tissue. Hyaluronidase treatment seems to have the same effect as preconditioning on the hysteresis area.     

Mechanical modulation of pressure-volume characteristics of contracted canine airways in vitro

In normal humans and dogs, the airways do not constrict to closure even when maximally stimulated. However, airway closure can be produced in isolated canine lobes and bronchial segments that are stimulated with maximal concentrations of bronchoconstrictors. These observations suggest that under normal conditions, physiological mechanisms to limit bronchoconstriction exist in vivo. In this investigation, we evaluated how mechanical factors that influence airway smooth muscle contractility contribute to the modulation of the pressure-volume characteristics of contracted canine intraparenchymal airways in vitro. Our results demonstrated that maximal and even submaximal contractile stimuli can produce airway closure in bronchi that are allowed to contract under isobaric conditions. However, the effectiveness of bronchoconstrictors is significantly reduced when the airways are subjected to tidal volume oscillations during contraction. In addition, airways contracted isovolumetrically at low volumes exhibit a markedly reduced sensitivity to submaximal concentrations of acetylcholine. This may limit bronchoconstriction at low lung volumes and transpulmonary pressures where the effectiveness of parenchymal stress in keeping the airways open is reduced. Together these factors could provide a mechanism by which bronchoconstriction is limited to low levels of airway resistance under normal conditions in vivo.     

Causes of error of respiratory pressure-volume curves in paralyzed subjects

Respiratory pressure-volume (PV) curves are commonly obtained in paralyzed patients by relating airway pressure to volume changes of a syringe (Vsyr). This is based on the implicit assumption that changes in thoracic volume (Vtho) and Vsyr are equal. We undertook to verify this assumption through simultaneous measurements of Vtho by respiratory inductive plethysmography and Vsyr in six comatose, paralyzed, intubated patients. At any constant Vsyr, Vtho fell and was smaller on deflation than on inflation during inflation-deflation (ID) cycle. The rate of fall was 110 +/- 64 (SD) ml/min. During ID cycles lasting 76 +/- 7 s, thoracic PV curves showed less hysteresis and a larger compliance on deflation than PVsyr curves (12 +/- 2 vs. 18 +/- 6% and 73 +/- 13 vs. 67 +/- 12 ml/cmH2O, P less than 0.05). With PVsyr curves, hysteresis increased and compliance on deflation decreased with increasing rate of fall of Vtho. We submit that the difference between changes in Vsyr and Vtho is best explained by gas exchange and should be taken into account when performing PV curves with a syringe in paralyzed patients.     

Right and left ventricular pressure-volume response to respiratory maneuvers

With respiration, right ventricular end-diastolic volume fluctuates. We examined the importance of these right ventricular volume changes on left ventricular function. In six mongrel dogs, right and left ventricular volumes and pressures and esophageal pressure were simultaneously measured during normal respiration, Valsalva maneuver, and Mueller maneuver. The right and left ventricular volumes were calculated from cineradiographic positions of endocardial radiopaque markers. Increases in right ventricular volume were associated with changes in the left ventricular (LV) pressure-volume relationship. With normal respiration, right ventricular end-diastolic volume increased 2.3 +/- 0.7 ml during inspiration, LV transmural diastolic pressure was unchanged, and LV diastolic volume decreased slightly. This effect was accentuated by the Mueller maneuver; right ventricular end-diastolic volume increased 10.4 +/- 2.3 ml (P less than 0.05), while left ventricular end-diastolic pressure increased 3.6 mmHg (P less than 0.05) without a significant change in left ventricular end-diastolic volume. Conversely, with a Valsalva maneuver, right ventricular volume decreased 6.5 +/- 1.2 ml (P less than 0.05), and left ventricular end-diastolic pressure decreased 2.2 +/- 0.5 mmHg (P less than 0.05) despite an unchanged left ventricular end-diastolic volume. These changes in the left ventricular pressure-volume relationship, secondary to changes in right ventricular volumes, are probably due to ventricular interdependence. Ventricular interdependence may also be an additional factor for the decrease in left ventricular stroke volume during inspiration.     

Creep of the canine pericardium in vivo

In eight open chest dogs we assessed the creep of the pericardium by measuring the increase in surface area of the pericardium, occurring after pericardial surface pressure (Ppe) was rapidly increased by inflating an air-containing balloon positioned between the pericardium and the left ventricular (LV) epicardium. We observed an increase in LV end diastolic pressure (EDP) of 3.6 +/- 3.4 mmHg (1 mmHg = 133.3 Pa) (p less than 0.05) (mean +/- SD) and a reduction in LV anteroposterior (AP) diameter of 8.8 +/- 6.1 mm (p less than 0.01), both of which were stable after 10 s. Mean Ppe increased 11.6 +/- 3.3 mmHg (p less than 0.001). Pericardial surface lengths at 45 and 135 degrees to the long axis of the LV were measured with two pairs of ultrasonic crystals attached to the outer surface of the pericardium. The beam of ultrasound travelling between each pair was directed parallel to the pericardial surface through a film of conducting medium. Initial increase in surface area (calculated as the product of two pericardial lengths) occurring during the first 15 s after balloon inflation was 5.8 +/- 2.5% (p less than 0.001). During the next 30 min, while mean pericardial pressure did not change, pericardial surface area increased another 2.8% (p less than 0.005). This time-dependent 2.8% increase in pericardial surface area (equivalent to an increase in volume of approximately 5%) is due to creep.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dynamic effects of positive-pressure ventilation on canine left ventricular pressure-volume relations.

Positive-pressure ventilation (PPV) may affect left ventricular (LV) performance by altering both LV diastolic compliance and pericardial pressure (Ppc). We measured the effect of PPV on LV intraluminal pressure, Ppc, LV volume, and LV cross-sectional area in 17 acute anesthetized dogs. To account for changes in lung volume independent of changes in Ppc and differences in contractility, measures were made during both open- and closed-chest conditions, during closed chest with and without chest wall binding, and after propranolol-induced acute ventricular failure (AVF). Apneic end-systolic pressure-volume relations (ESPVR) were generated by inferior vena caval occlusions. With the open chest, PPV had no effects. With the chest closed, PPV inspiration decreased LV end-diastolic volume (EDV) along its diastolic compliance curve and decreased end-systolic volume (ESV) such that the end-systolic pressure-volume domain was shifted to a point left of the LV ESPVR, even when referenced to Ppc. The decrease in EDV was greater in control than in AVF conditions, whereas the shift of the ESV to the left of the ESPVR was greater with AVF than in control conditions. We conclude that the hemodynamic effects of PPV inspiration are due primarily to changes in intrathoracic pressure and that the inspiration-induced decreases of LV EDV reflect direct effects of intrathoracic pressure on LV filling. The decreases in LV ESV exceed the amount explained solely by a reduction in LV ejection pressure.     

Normal distribution of ventricular pressure-volume area of arrhythmic beats under atrial fibrillation in canine heart

We previously found the frequency distribution of the left ventricular (LV) effective afterload elastance (E(a)) of arrhythmic beats to be nonnormal or non-Gaussian in contrast to the normal distribution of the LV end-systolic elastance (E(max)) in canine in situ LVs during electrically induced atrial fibrillation (AF). These two mechanical variables determine the total mechanical energy [systolic pressure-volume area (PVA)] generated by LV contraction when the LV end-diastolic volume is given on a per-beat basis. PVA and E(max) are the two key determinants of the LV O(2) consumption per beat. In the present study, we analyzed the frequency distribution of PVA during AF by its chi(2), significance level, skewness, and kurtosis and compared them with those of other major cardiodynamic variables including E(a) and E(max). We assumed the volume intercept (V(0)) of the end-systolic pressure-volume relation needed for E(max) determination to be stable during arrhythmia. We found that PVA distributed much more normally than E(a) and slightly more so than E(max) during AF. We compared the chi(2), significance level, skewness, and kurtosis of all the complex terms of the PVA formula. We found that the complexity of the PVA formula attenuated the effect of the considerably nonnormal distribution of E(a) on the distribution of PVA along the central limit theorem. We conclude that mean (SD) of PVA can reliably characterize the distribution of PVA of arrhythmic beats during AF, at least in canine hearts.