Kal E. Watson

Bacteremic sepsis disturbs alveolar perfusion distribution in the lungs of rats

Objective: Sepsis often leads to lung injury, although the mechanisms that initiate this are unclear. One preinjury phenomenon that has not been explored previously is the effect of bacterial (nonlipopolysaccharide) sepsis on the distribution of alveolar perfusion. The goals of our studies were to measure this. Design: Randomized, controlled, prospective animal study. Setting: University animal laboratory. Subjects: Male Sprague-Dawley rats (450–550 g). Interventions: We induced sepsis by placing gelatin capsules containing Escherichia coli and Bacteroides fragilis into the abdomens of rats (n = 9). Empty capsules (n = 6) were placed into the abdomens of controls. After 24 hrs, 4-&mgr;m-diameter fluorescent latex particles (2 × 108) were infused into the pulmonary circulation. Sepsis was induced in additional rats and controls to assess lung injury, as follows: Lung histology was performed on eight septic rats and on seven controls; lung lavage was performed on three septic rats and three controls after their plasma albumin had been labeled with Evans blue dye. Measurements and Main Results: Confocal microscopy was used to prepare digital maps of latex particle trapping patterns (eight per lung). Analysis of these patterns revealed statistically more clustering (perfusion inhomogeneity) down to tissue volumes less than that of ten alveoli in septic lungs compared with controls (p ≤ .05). Bacterial counts and neutrophil counts were significantly higher in the circulation of septic rats (p ≤ .05). Blood pressures and arterial Po2s were unchanged. Cell counts in histological images were three-fold higher in septic lungs than in controls (p ≤ .05). Lung lavage revealed 0.41 ± 0.03 mL of plasma in the lungs of septic rats, and 0.06 ± 0.05 mL in the lungs of controls (p ≤ .05). Conclusions: Bacterial sepsis caused significant maldistribution of interalveolar perfusion in the lungs of rats in the absence of significant lung injury.

Pulmonary capillary sieving of hetastarch is not altered by LPS-induced sepsis.

BACKGROUND Gram-negative lipopolysaccharide (LPS) has been demonstrated to increase pulmonary capillary permeability as judged by the increased flow of protein-rich lymph from the lungs of sheep infused with LPS. This finding suggests that LPS-injured pulmonary capillaries might be less restrictive than uninjured capillaries to the filtration of large hetastarch molecules. Hetastarch has a broad molecular mass spectrum (35-1,500 kilodaltons (kDa)), and one way to test the restrictiveness of pulmonary capillaries is to measure the size of the largest hetastarch molecules that cross the microvascular barrier and enter the lymph. To evaluate the effects of LPS, we compared hetastarch molecular distributions in the lung lymph of normal and LPS-injured sheep. METHODS Adult sheep (38.2 +/- 0.8 kg) were surgically prepared for the collection of lung lymph, with study initiation after a 5- to 7-day recovery period. Hetastarch (6%) was infused (10 mL/kg) 24 hours before study to allow for stabilization of the hetastarch molecular distribution. On the day of study, LPS (Escherichia coli lipopolysaccharide, 2 microg/kg; n = 6) was infused, and plasma and lymph samples were collected for 12 hours. An additional group of animals not infused with LPS (n = 6) served as controls. Hetastarch molecular distributions in plasma and lymph were measured by using high performance size exclusion chromatography. RESULTS In control sheep, the largest hetastarch molecules in lymph averaged 861 +/- 18 kDa (mean +/- SEM) (plasma, 1,065 +/- 18 kDa). In LPS-treated sheep, the largest hetastarch molecules in lymph averaged 845 +/- 19 kDa (not significant vs. normal) (plasma, 1,025 +/- 14 kDa). Hetastarch concentrations in plasma and lung lymph of normal sheep, respectively, were 0.61 +/- 0.05% and 0.34 +/- 0.07%. In LPS-treated sheep, hetastarch concentrations in plasma and lymph were 0.56 +/- 0.08 (not significant vs. normal) and 0.29 +/- 0.07, respectively (p < or = 0.05). Lymph concentrations were lower after LPS because of increased lymph flows (19.9 +/- 5.4 mL/30 min, compared with 3.6 +/- 0.8 mL/30 min in normal sheep). CONCLUSION Our results suggest that LPS does not alter the diameter of the largest pores perforating the walls of pulmonary capillaries. Rather, the number of these pores in the capillary wall appears to be increased. This increase would explain why lymph flows rise after LPS with little change in the lymph protein concentration. Our results are also consistent with a filtration model in which capillaries are assumed to be perforated by small pores (protein reflection coefficient = 1) as well as large pores (protein reflection coefficient = 0).

Microthrombus formation may trigger lung injury after acute blood loss.

We showed previously that acute blood loss, without resuscitation, caused marked maldistribution of interalveolar perfusion. Because hemorrhage is a known risk factor for the development of lung injury, the goal of our present studies was to determine if there was a correlation between perfusion maldistribution and the subsequent development of lung injury after blood loss. Specifically, we wanted to know if the perfusion maldistribution might be due to microthrombus formation and/or leukocyte sequestration within the pulmonary microcirculation. We bled rats (30% blood loss) and harvested their lungs 45 min or 24 h later. Lungs were prepared for perfusion distribution analysis, Western blot analysis to measure whole-lung fibrinogen concentrations, and for immunohistochemistry to measure fibrin deposition and leukocyte deposition (CD16 fluorescence). Perfusion was significantly maldistributed at 45 min and 24 h (P < 0.05). At 45 min, whole-lung fibrinogen concentrations were less than half that in controls (P < 0.05), whereas numbers of fibrin microthrombi were 2.5-fold greater than control by 45 min (not statistically significant) and were 4.5-fold greater by 24 h (P = 0.01). Leukocyte deposition was two-fold greater than control by 45 min (not statistically significant) and was 4-fold greater by 24 h (P = 0.02). Fibrin-to-leukocyte nearest-neighbor distances remained unchanged (18.1 [SD, 1.1] &mgr;m) even as the numbers of both increased with time after blood loss. Our results suggest that soluble fibrinogen polymerized to insoluble fibrin within minutes after acute blood loss, which caused perfusion maldistribution and attracted leukocytes. The development of lung injury after blood loss may be a consequence of leukocyte chemoattraction to fibrin microthrombi that seem to form within minutes after blood loss.

Evidence for active control of perfusion within lung microvessels

Vasoconstrictors cause contraction of pulmonary microvascular endothelial cells in culture. We wondered if this meant that contraction of these cells in situ caused active control of microvascular perfusion. If true, it would mean that pulmonary microvessels were not simply passive tubes and that control of pulmonary microvascular perfusion was not mainly due to the contraction and dilation of arterioles. To test this idea, we vasoconstricted isolated perfused rat lungs with angiotensin II, bradykinin, serotonin, or U46619 (a thromboxane analog) at concentrations that produced equal flows. We also perfused matched-flow controls. We then infused a bolus of 3 μm diameter particles into each lung and measured the rate of appearance of the particles in the venous effluent. We also measured microscopic trapping patterns of particles retained within each lung. Thirty seconds after particle infusion, venous particle concentrations were significantly lower (P ≤ 0.05) for lungs perfused with angiotensin II or bradykinin than for those perfused with U46619, but not significantly different from serotonin perfused lungs or matched flow controls. Microscopic clustering of particles retained within the lungs was significantly greater (P ≤ 0.05) for lungs perfused with angiotensin II, bradykinin, or serotonin, than for lungs perfused with U46619 or for matched flow controls. Our results suggest that these agents did not produce vasoconstriction by a common mechanism and support the idea that pulmonary microvessels possess a level of active control and are not simply passive exchange vessels.

Inhaled thrombolytics reduce lung microclot and leukocyte infiltration after acute blood loss.

ABSTRACT We showed previously that a 30% blood loss in rats, without resuscitation, caused significant accumulation of microthrombi and leukocytes within the pulmonary circulation by 24 h. We hypothesized that the microthrombi formed spontaneously as a consequence of hemorrhage-induced stasis within the low-pressure pulmonary circuit and that the leukocytes were attracted to them. This suggested that elimination of the microthrombi, using an inhaled thrombolytic agent, could prevent the neutrophil sequestration after blood loss. To test this hypothesis, we removed 30% of the calculated blood volume from isoflurane-anesthetized, male Sprague-Dawley rats (350–500 g) over 5 min and allowed them to recover. Six hours later, we reanesthetized the rats and nebulized tissue plasminogen activator (80 or 320 µg/kg), lactated Ringer’s solution (LRS), or ipratropium bromide (i-bromide) into their lungs. We used i-bromide as a control after we discovered that nebulized LRS had thrombolytic properties. At 24 h, we removed and fixed the lungs and prepared sections for immunohistochemistry using antibodies against fibrinogen (microthrombi) and CD16 (leukocytes). Digital images of each section were obtained using a confocal microscope. Pixel counts of the images showed significantly less accumulation of microthrombi and leukocytes in lungs nebulized with tissue plasminogen activator or LRS than in nonnebulized lungs or in lungs nebulized with i-bromide (P ⩽ 0.05). Lactated Ringer’s solution becomes positively charged when nebulized (unlike i-bromide), suggesting that it eliminated microthrombi by fibrin depolymerization. We confirmed this using an in vitro assay. Our results demonstrate that lyses of microthrombi that accumulate in the lung after acute blood loss prevent subsequent leukocyte sequestration.

Acute hypoxia does not alter inter-alveolar perfusion distribution in unanesthetized rats

Effects of hypoxic vasoconstriction on inter-alveolar perfusion distribution (< or =1000 alveoli) have not been studied. To address this, we measured inter-alveolar perfusion distribution in the lungs of unanesthetized rats breathing 10% O(2). Perfusion distributions were measured by analyzing the trapping patterns of 4 microm diameter fluorescent latex particles infused into the pulmonary circulation. The trapping patterns were statistically quantified in confocal images of the dried lungs. Trapping patterns were measured in lung volumes that ranged between less than 1 and 1300 alveoli, and were expressed as the log of the dispersion index (logDI). A uniform (statistically random) perfusion distribution corresponds to a logDI value of zero. The more this value exceeds zero, the more the distribution is clustered (non-random). At the largest tissue volume (1300 alveoli) logDI reached a maximum value of 0.68+/-0.42 (mean+/-s.d.) in hypoxic rats (n = 6), 0.50+/-0.38 in hypercapnic rats (n.s.) and 0.48+/-0.25 in air-breathing controls (n.s.). Our results suggest that acute hypoxia did not cause significant changes in inter-alveolar perfusion distribution in unanesthetized, spontaneously breathing rats.

Bacteremia Does Not Affect Cellular Uptake of Ultrafine Particles in the Lungs of Rats

To assess the effects of intra‐abdominal bacteremia on lung cellular function in vivo, we used electron microscopy to quantify the uptake of 6 nm diameter, albumin‐coated colloidal gold particles (overall diam. 20.8 nm) by cells in the lungs of rats made septic by the introduction of live bacteria (E.coli and B. fragilis) into their abdomens. Gold particles were instilled into the trachea 24 hr after bacteremia induction, and lungs were harvested and prepared for electron microscopy 24 hr later. Because bacteremia produces an increase in metabolism, we hypothesized that this might be associated with increased cellular uptake of these particles and also with increased permeability of the alveolar epithelial barrier to them, as bacteremia is also associated with lung injury. We quantified particle uptake by counting particle densities (particles/μm2) within type I and type II epithelial cells, capillary endothelial cells, erythrocytes and neutrophils in the lungs of five septic rats and five sham‐sepsis controls. We also counted particle densities within organelles of these cells (nuclei, mitochondria, type II cell lamellar bodies) and within the alveolar interstitium. We found particles to be present within all of these compartments, although we found no differences in particle densities between bacteremic rats and sham‐sepsis controls. Our results suggest that these 6 nm particles were able to freely cross cell and organelle membranes, and further suggest that this ability was not altered by bacteremia. Anat Rec, 2011.

Effect of concentration and hyaluronidase on restriction of hetastarch flux through lung interstitial segments.

The transport properties of lung interstitium were studied by measuring the flow of hetastarch solution (2 and 6%) through 1-cm perivascular interstitial segments of rabbit lungs. Hetastarch (10(4)-10(7) Da) solution has a colloid osmotic pressure similar to that of albumin solution. Driving pressure was 5 cm H(2)O and mean interstitial pressure was 0 cm H(2)O. The flows of 2 and 6% hetastarch solutions were measured before (Q(1)) and after (Q(2)) the addition of 0.02% hyaluronidase. Hetastarch molecular distributions in effluent samples were measured by high-performance size-exclusion chromatography (HPSEC) to determine sieving ratio (C(out)/C(in), downstream-to-upstream concentration ratio). Hyaluronidase significantly (P < 0.0004) increased flow sixfold, but the increase in flow (Q(2)/Q(1)) was reduced through the interstitium around smaller vessels. A similar behavior was observed with the flow of albumin solution without and with hyaluronidase. C(out)/C(in) decreased monotonically with molecular weight, was greater with 6% than with 2% (low colloid osmotic pressure) hetastarch, and increased with hyaluronidase. Modeling the transport through uniform pores, equivalent pore radius was 10 and 15 nm with 2 and 6% hetastarch, respectively, and doubled with hyaluronidase. In conclusion, interstitial pores expand in response to an increase in colloid osmotic pressure both before and after tissue degradation by hyaluronidase.

Negative pressure ventilation enhances acinar perfusion in isolated rat lungs

We compared acinar perfusion in isolated rat lungs ventilated using positive or negative pressures. The lungs were ventilated with air at transpulmomary pressures of 15/5 cm H2O, at 25 breaths/min, and perfused with a hetastarch solution at Ppulm art/PLA pressures of 10/0 cm H2O. We evaluated overall perfusability from perfusate flows, and from the venous concentrations of 4-µm diameter fluorescent latex particles infused into the pulmonary circulation during perfusion. We measured perfusion distribution from the trapping patterns of those particles within the lung. We infused approximately 9 million red fluorescent particles into each lung, followed 20 min later by an infusion of an equal number of green particles. In positive pressure lungs, 94.7 ± 2.4% of the infused particles remained trapped within the lungs, compared to 86.8 ± 5.6% in negative pressure lungs (P ≤ 0.05). Perfusate flows averaged 2.5 ± 0.1 mL/min in lungs ventilated with positive pressures, compared to 5.6 ± 01 mL/min in lungs ventilated with negative pressures (P ≤ 0.05). Particle infusions had little effect on perfusate flows. In confocal images of dried sections of each lung, red and green particles were co-localized in clusters in positive pressure lungs, suggesting that acinar vessels that lacked particles were collapsed by these pressures thereby preventing perfusion through them. Particles were more broadly and uniformly distributed in negative pressure lungs, suggesting that perfusion in these lungs was also more uniformly distributed. Our results suggest that the acinar circulation is organized as a web, and further suggest that portions of this web are collapsed by positive pressure ventilation.

Arterio‐venous anastomoses in isolated, perfused rat lungs

Several studies have suggested that large‐diameter (>25 μm) arterio‐venous shunt pathways exist in the lungs of rats, dogs, and humans. We investigated the nature of these pathways by infusing specific‐diameter fluorescent latex particles (4, 7, 15, 30, or 50 μm) into isolated, ventilated rat lungs perfused at constant pressure. All lungs received the same mass of latex (5 mg), which resulted in infused particle numbers that ranged from 1.7 × 107 4 μm particles to 7.5 × 104 50 μm particles. Particles were infused over 2 min. We used a flow cytometer to count particle appearances in venous effluent samples collected every 0.5 min for 12 min from the start of particle infusion. Cumulative percentages of infused particles that appeared in the samples averaged 3.17 ± 2.46% for 4 μm diameter particles, but ranged from 0.01% to 0.17% for larger particles. Appearances of 4 μm particles followed a rapid upslope beginning at 30 sec followed by a more gradual downslope that lasted for up to 12 min. All other particle diameters also began to appear at 30 sec, but followed highly irregular time courses. Infusion of 7 and 15 μm particles caused transient but significant perfusate flow reductions, while infusion of all other diameters caused insignificant reductions in flow. We conclude that small numbers of bypass vessels exist that can accommodate particle diameters of 7‐to‐50 μm. We further conclude that our 4 μm particle data are consistent with a well‐developed network of serial and parallel perfusion pathways at the acinar level.