Interleukin-6 displays lung anti-inflammatory properties and exerts protective hemodynamic effects in a double-hit murine acute lung injury.

BACKGROUND: Interleukin 6 (IL-6) is a predictive factor of poor prognosis in patients with acute respiratory distress syndrome (ARDS). However, its acute pulmonary hemodynamic effects and role in lung injury have not been investigated in a clinically relevant murine model of ARDS. METHODS: We used adult C57Bl6 wild-type (WT) and IL-6 knock-out (IL-6KO) mice. The animals received intravenous recombinant human IL-6 (rHuIL-6) or vehicle followed by intratracheal lipopolysaccharide (LPS) or saline before undergoing low tidal volume mechanical ventilation (MV) for 5 h. Before sacrifice, right ventricular systolic pressure and cardiac output were measured and total pulmonary resistance was calculated. After sacrifice, lung inflammation, edema and injury were assessed with bronchoalveolar lavage (BAL) and histology. In other experiments, right ventricular systolic pressure was recorded during hypoxic challenges in uninjured WT mice pretreated with rHuIL-6 or rHuIL-6 + non-selective nitric oxide synthase inhibitor L-NAME or vehicle. RESULTS: IL-6KO(LPS+MV) mice showed a faster deterioration of lung elastic properties and more severe bronchoalveolar cellular inflammation as compared to WT(LPS+MV). Treatment with rHuIL-6 partially prevented this lung deterioration. Total pulmonary resistance was higher in IL-6KO(LPS+MV) mice and this increase was abolished in rHuIL-6-treated IL-6KO mice. Finally, rHuIL-6 reduced hypoxic pulmonary vasoconstriction in uninjured WT mice, an effect that was abolished by co-treatment with L-NAME. CONCLUSIONS: In a double-hit murine model of ARDS, IL-6 deficient mice experienced more severe bronchoalveolar cellular inflammation as compared to wild-type littermates. Furthermore, IL-6 deficiency caused marked acute pulmonary hypertension, which may be, at least partially, due to vasoactive mechanisms. A dysregulation of nitric oxide synthase may account for this observation, a hypothesis that will need to be investigated in future studies.

Numerical investigation on red blood cell dynamics in microflow: Effect of cell deformability.

The radial dispersion of red blood cells (RBCs) near the vessel wall can significantly affect the transport dynamics in small vessels. The radial dispersion of RBCs is mainly caused by collisions between RBCs and this can be enhanced by aggregation. The objective of this study is to numerically investigate on the effect of RBC deformability on the radial motion of individual RBCs in a range of flow rates. Immersed Boundary - Lattice Boltzmann Method was utilized to study the radial motion of RBCs in a two-dimensional flow domain. The RBC flow simulations were performed at 40% hematocrit in a microvessel with diameter of 25µm and length of 100µm. The dispersion of less deformable RBCs was notably greater than that of normal RBCs at all flow rates and this effect seemed to be more pronounced when the flow rate was increased. The cell dispersion was higher near the vessel wall than the flow center regardless of flow rate and RBCs deformability. Thus, the dispersion of RBCs could be enhanced with flow rate and RBC rigidity. Our findings would be especially useful in investigating blood flows in arterioles and venules.

New findings on venous thrombogenesis.

Venous thrombosis (VT) is the third most common cause of cardiovascular death worldwide. Complications from VT and pulmonary embolism are the leading cause of lost disability-adjusted life years. Risks include genetic (e.g., non-O blood group, activated protein C resistance, hyperprothrombinemia) and acquired (e.g., age, surgery, cancer, pregnancy, immobilisation, female hormone use) factors. Pathophysiologic mechanisms that promote VT are incompletely understood, but involve abnormalities in blood coagulability, vessel function, and flow (so-called Virchow's Triad). Epidemiologic studies of humans, animal models, and biochemical and biophysical investigations have revealed contributions from extrinsic, intrinsic, and common pathways of coagulation, endothelial cells, leukocytes, red blood cells, platelets, cell-derived microvesicles, stasis-induced changes in vascular cells, and blood rheology. Knowledge of these mechanisms may yield new therapeutic targets. Characterisation of mechanisms that mediate VT formation and stability, particularly in aging, are needed to advance understanding of VT.

The function of ultra-large von Willebrand factor multimers in high shear flow controlled by ADAMTS13.

The paradigm that platelet aggregation, which contributes to bleeding arrest and also to thrombovascular disorders, initiates after signaling-induced platelet activation has been refuted in past recent years. Platelets can form aggregates independently of activation when soluble von Willebrand factor (VWF) is present and the shear rate exceeds a certain threshold where active A1 domains become exposed in soluble VWF multimers and can bind to platelet glycoprotein Ib. Subsequently - fostering each other - VWF can self-assemble into large nets combining with platelets into large conglomerates, which are entirely reversible when they enter a flow region with shear rates below the threshold. In addition the threshold changes from approximately 20 000 s⁻¹ in wall parallel flow to approximately 10 000 s⁻¹ in stagnation point flow. VWF containing ultra-large multimers - as when just released from endothelial storage sites - has been shown to have the highest binding potential to platelets and to each other, thus facilitating rapid platelet accrual to sites of vessel injury and exposed subendothelial structures, i.e. collagen. The VWF nets as well as the platelet-VWF conglomerates are controlled by the cleaving protease ADAMTS13 within minutes under high shear flow. Therewith the hemostatic potential is delivered where needed and the thrombogenic potential is highly controlled twofold: by flow and enzymatic proteolytic cleavage.

Correlation of axial blood velocity to venular and arteriolar diameter in the human eye in vivo.

The axial blood velocity (Vax) association with microvessel diameter (D) was studied at 104 different postcapillary venules (4 µm <  D <  24 µm) and 30 different precapillary arterioles (6 µm≤D≤12 µm) in the human conjunctiva of normal healthy humans. Venular diameter sizes were classified as "very small" (Group 1, 4.4 µm≤D <  8.9 µm), "small" (Group 2, 8.9 µm≤D <  13.8 µm), "medium" (Group 3, 13.8 µm≤D <  19.1 µm) and "large" (Group 4, 19.1 µm≤D≤23.5). The Spearman's correlation coefficient (rs) in all 4 venular groups was less than 0.36 and not statistically significant (n = 26, p≥0.08). Similar correlation results were observed for the arteriolar group (rs) ≈ 0) for the peak systolic, the average and the end systolic axial velocities. Vax was significantly (p <  0.001) lower in Group 1 in comparison to that in Group 2 and significantly (p <  0.01) lower in Group 2 in comparison to that in Group 3. However, Vax was not significantly lower in Group 3 in comparison to that in Group 4. Average Vax and standard deviation was 0.48 ± 0.13, 0.64 ± 0.16, 0.82 ± 0.25 and 0.88 ± 0.32 mm/s for Groups 1, 2, 3 and 4 respectively. The above results reinforce the importance of measuring D in microvascular hemodynamics. Higher diameters suggest higher axial velocities but Vax does not change significantly within the limits of each of the aforementioned groups.

Cerebral blood volume estimation by ferumoxytol-enhanced steady-state MRI at 9.4 T reveals microvascular impact of α1 -adrenergic receptor antibodies.

Cerebrovascular abnormality is frequently accompanied by cognitive dysfunctions, such as dementia. Antibodies against the α1 -adrenoceptor (α1 -AR) can be found in patients with Alzheimer's disease with cerebrovascular disease, and have been shown to affect the larger vessels of the brain in rodents. However, the impact of α1 -AR antibodies on the cerebral vasculature remains unclear. In the present study, we established a neuroimaging method to measure the relative cerebral blood volume (rCBV) in small rodents with the ultimate goal to detect changes in blood vessel density and/or vessel size induced by α1 -AR antibodies. For this purpose, mapping of R2 * and R2 was performed using MRI at 9.4 T, before and after the injection of intravascular iron oxide particles (ferumoxytol). The change in the transverse relaxation rates (ΔR2 *, ΔR2 ) showed a significant rCBV decrease in the cerebrum, cortex and hippocampus of rats (except hippocampal ΔR2 ), which was more pronounced for ΔR2 * than for ΔR2 . Immunohistological analyses confirmed that the α1 -AR antibody induced blood vessel deficiencies. Our findings support the hypothesis that α1 -AR antibodies lead to cerebral vessel damage throughout the brain, which can be monitored by MRI-derived rCBV, a non-invasive neuroimaging method. This demonstrates the value of rCBV estimation by ferumoxytol-enhanced MRI at 9.4 T, and further underlines the significance of this antibody in brain diseases involving vasculature impairments, such as dementia.

The importance of liver microcirculation in promoting autoimmune hepatitis via maintaining an inflammatory cytokine milieu--a mathematical model study.

In autoimmune diseases, inflammatory cytokine concentrations are important for initiating and maintaining the status of autoimmunity. Autoimmune hepatitis (AIH) is an inflammatory liver disease characterized by a loss of immune tolerance against specific antigens located in hepatocytes. During the progression of the disease, antigen-presenting cells and different classes of T-helper cells secrete specific cytokines important for maintaining the disease. As these cytokines are secreted into the local liver environment, the blood flow in liver sinusoids might influence the local cytokine concentration. Considering the liver tissue as a porous medium, based on Darcy׳s law, the microcirculation within a liver lobule was modelled. Using realistic physiological pressure differences and tissue permeabilities, the blood velocity inside the sinusoids could be calculated and validated with blood velocity data obtained via Orthogonal Polarization Spectral Imaging (OPSI). Furthermore, oxygen consumption is modelled to obtain Rappaport׳s acinus model. Finally, steady state spatial distributions of secreted cytokines within the liver lobule could be estimated for specified realistic production rates of T-helper cells. It could be demonstrated that the characteristics of the liver microcirculation have an important impact on establishing inflammatory cytokine levels within the portal fields and the vascular septa promoting the occurrence of interface hepatitis.

[Effects of physical stimulation of spontaneous arteriolar vasomotion on microcirculation and the immune system in diabetes and impaired wound healing]. / Wirkungen einer physikalischen Stimulierung der spontanen arteriolären Vasomotion auf Mikrozirkulation und Immunsystem bei Diabetes und Wundheilungsstörungen.

BACKGROUND: Whether and to what extent the complementary use of a biorhythm-defined physical stimulation of insufficient spontaneous arteriolar vasomotion contributes to increasing the therapeutic success of established treatment concepts were examined. MATERIALS AND METHODS: In a placebo-controlled study on a biometrically defined sample of older diabetes patients with impaired wound healing, measurements of representative features of the functional status of the microcirculation and the immune system were investigated using high-resolution methods (intravital microscopy, reflective spectrometry, white light spectroscopy combined with laser Doppler microflow measurements). The stimulation signal corresponding to physiological spontaneous arteriolar vasomotion was transmitted using an electromagnetic alternating field of low magnetic flux density. RESULTS: During the 27-day treatment and observation period, a complementary treatment effect of the applied biorhythm-defined physical vasomotion stimulation could be detected.

Sequential binding of αVß3 and ICAM-1 determines fibrin-mediated melanoma capture and stable adhesion to CD11b/CD18 on neutrophils.

Fibrin (Fn) deposition defines several type 1 immune responses, including delayed-type hypersensitivity and autoimmunity in which polymorphonuclear leukocytes (PMNs) are involved. Fn monomer and fibrinogen are multivalent ligands for a variety of cell receptors during cell adhesion. These cell receptors provide critical linkage among thrombosis, inflammation, and cancer metastasis under venous flow conditions. However, the mechanisms of Fn-mediated interactions among immune cells and circulating tumor cells remain elusive. By using a cone-plate viscometer shear assay and dual-color flow cytometry, we demonstrated that soluble fibrinogen and Fn had different abilities to enhance heterotypic aggregation between PMNs and Lu1205 melanoma cells in a shear flow, regulated by thrombin levels. In addition, the involvement of integrin α(v)ß(3), ICAM-1, and CD11b/CD18 (Mac-1) in fibrin(ogen)-mediated melanoma-PMN aggregations was explored. Kinetic studies provided evidence that ICAM-1 mediated initial capture of melanoma cells by PMNs, whereas α(v)ß(3) played a role in sustained adhesion of the two cell types at a shear rate of 62.5 s(-1). Quantitative analysis of the melanoma-PMN interactions conducted by a parallel-plate flow chamber assay further revealed that at a shear rate of 20 s(-1), α(v)ß(3) had enough contact time to form bonds with Mac-1 via Fn, which could not otherwise occur at a shear rate higher than 62.5 s(-1). Our studies have captured a novel finding that leukocytes could be recruited to tumor cells via thrombin-mediated Fn formation within a tumor microenvironment, and α(v)ß(3) and ICAM-1 may participate in multistep fibrin(ogen)-mediated melanoma cell adhesion within the circulation.

CCL20 and ß-defensin-2 induce arrest of human Th17 cells on inflamed endothelium in vitro under flow conditions.

CCR6 is a chemokine receptor that is expressed at the cell surface of Th17 cells, an IL-17- and IL-22-secreting population of CD4(+) T cells with antipathogenic, as well as inflammatory, properties. In the current study, we have determined the involvement of CCR6 in human Th17 lymphocyte migration toward inflamed tissue by analyzing the capacity of its ligands to induce arrest of these cells onto inflamed endothelium in vitro under flow conditions. We show that polarized, in situ-differentiated, skin-derived Th17 clones activated via the TCR-CD3 complex produce CCL20 in addition to IL-17 and IL-22. The latter cytokines induce, in a synergic fashion, the production of human ß-defensin (hBD)-2, but neither hBD-1 nor hBD-3, by epidermal keratinocytes. Both CCL20 and hBD-2 are capable of inducing the arrest of Th17 cells, but not Th1 or Th2 cells, on HUVEC in an CD54-dependent manner that is CCR6 specific and independent from the expression of CXCR4, reported to be an alternative receptor for hBD-2. In addition, Ag-specific activation induces a transient loss of CCR6 expression, both at the transcriptional and protein level, which occurs with slow kinetics and is not due to endogenous CCL20-mediated internalization of CCR6. Together, these results indicate that Ag-specific activation will initially contribute to CCR6-mediated Th17 cell trafficking toward and sequestration in inflamed tissue, but that it eventually results in a transitory state of nonresponsiveness to further stimulation of these cells with CCR6 ligands, thus permitting their subsequent migration out of the inflamed site.

Mechanisms of leukocyte distribution during sepsis: an experimental study on the interdependence of cell activation, shear stress and endothelial injury.

INTRODUCTION: This study was carried out to determine whether interactions of cell activation, shear stress and platelets at sites of endothelial injury explain the paradoxical maldistribution of activated leukocytes during sepsis away from local sites of infection towards disseminated leukocyte accumulation at remote sites. METHODS: Human umbilical venous endothelial cells (HUVEC) and polymorphonuclear neutrophils (PMN) were activated with lipopolysaccharide at 100 and 10 ng/ml to achieve adhesion molecule patterns as have been reported from the hyper- and hypo-inflammatory stage of sepsis. To examine effects of leukocyte activation on leukocyte-endothelial interactions, activated HUVEC were perfused with activated and non-activated neutrophils in a parallel plate flow chamber. Adhesion molecule expression and function were assessed by flow cytometry and blocking antibodies. In a subset of experiments the sub-endothelial matrix was exposed and covered with platelets to account for the effects of endothelial injury. To investigate interactions of these effects with flow, all experiments were done at various shear stress levels (3 to 0.25 dyne/cm(2)). Leukocyte-endothelial interactions were analyzed by videomicroscopy and analysis of covariance. RESULTS: Activation of neutrophils rendered adhesion increasingly dependent on shear stress reduction. At normal shear stress, shedding of L-selectin decreased adhesion by 56%. Increased rolling fractions of activated PMN at low shear stress revealed impaired integrin affinity despite numerical up-regulation of CD11b. On sub-maximally activated, intact HUVEC shear stress became the prevailing determinant of adhesion. Presence of a platelet-covered injury with high surface density of P-selectin was the strongest variable for adhesion. When compared to maximally activated HUVEC, platelets increased neutrophil adhesion by 2.7-fold. At sub-maximal activation a 10-fold increase was observed (P < 0.05 for all). CONCLUSIONS: L-selectin shedding and integrin dysfunction render leukocyte adhesion increasingly susceptible to shear stress and alternative adhesion receptors. In combination, these effects inhibit recruitment to normally perfused sites with intact endothelium and favor maldistribution towards sites with compromised perfusion or endothelial injury.

Neutrophil adhesion and activation under flow.

Neutrophil recruitment into inflamed tissue in response to injury or infection is tightly regulated. Reduced neutrophil recruitment can result in a reduced ability to fight invading microorganisms. During inflammation, neutrophils roll along the endothelial wall of postcapillary venules and integrate inflammatory signals. Neutrophil activation by selectins and chemokines regulates integrin adhesiveness. Binding of activated integrins to their counter-receptors on endothelial cells induces neutrophil arrest and firm adhesion. Adherent neutrophils can be further activated to undergo cytoskeletal rearrangement, crawling, transmigration, superoxide production, and respiratory burst. Signaling through G-protein-coupled receptors, selectin ligands, Fc receptors and outside-in signaling through integrins are all involved in neutrophil activation, but their interplay in the multistep process of recruitment is only beginning to emerge. This review provides an overview of signaling in rolling and adherent neutrophils.

Microparticle adhesive dynamics and rolling mediated by selectin-specific antibodies under flow.

In vitro studies were performed to characterize the relative performance of candidate receptors to target microparticles to inflammatory markers on vascular endothelium. To model the interactions of drug-bearing microparticles or imaging contrast agents with the vasculature, 6 micron polystyrene particles bearing antibodies, peptides, or carbohydrates were perfused over immobilized E- or P-selectin in a flow chamber. Microparticles conjugated with HuEP5C7.g2 (HuEP), a monoclonal antibody (mAb) specific to E- and P-selectin, supported leukocyte-like rolling and transient adhesion at venular shear rates. In contrast, microparticles conjugated with a higher affinity mAb specific for P-selectin (G1) were unable to form bonds at venular flow rates. When both HuEP and G1 were conjugated to the microparticle, HuEP supported binding to P-selectin in flow which allowed G1 to form bonds leading to stable adhesion. While the microparticle attachment and rolling performance was not as stable as that mediated by the natural ligands P-selectin Glycoprotein Ligand-1 or sialyl Lewis(x), HuEP performed significantly better than any previously characterized mAb in terms of mediating microparticle binding under flow conditions. HuEP may be a viable alternative to natural ligands to selectins for targeting particles to inflamed endothelium.

Expression of P-selectin at low site density promotes selective attachment of eosinophils over neutrophils.

The selective interaction of neutrophils with E-selectin and eosinophils with P-selectin has been previously reported, but the relevance of selectin site density and fluid shear has not been studied in detail. We have developed a new approach to examine these interactions in cell suspensions that integrates an on-line cone-plate viscometer with a flow cytometer. We find that eosinophils and neutrophils both use P-selectin glycoprotein ligand-1 to form stable conjugates with P-selectin Chinese hamster ovary cell transfectants, with a preferential adhesion of eosinophils. Further, the difference in cell adhesion between neutrophils and eosinophils is magnified at P-selectin expression levels below approximately 20 sites/microm2, a range likely to be relevant to endothelial cell expression levels in conditions associated with eosinophilia. The unique behavior is retained over shear rates ranging from 100 to 1500/s but is magnified at low shear. Results from parallel-plate flow chamber assays suggest that preferential eosinophil adhesion reflects an enhanced efficiency of initial PSGL-1 bond formation with P-selectin rather than a unique ability of eosinophils to mediate rolling interactions of longer duration on low-density P-selectin substrates. These differences may account in part for the increase in eosinophil accumulation in allergic diseases.

The roles of L-selectin, beta 7 integrins, and P-selectin in leukocyte rolling and adhesion in high endothelial venules of Peyer's patches.

Lymphocyte trafficking into Peyer's patches requires beta 7 integrins and L-selectin. Here, we use intravital microscopy to examine leukocyte rolling and adhesion in Peyer's patch high endothelial venules (HEV) of wild-type, L-selectin-deficient (L-/-), beta 7 integrin-deficient (beta 7-/-), and beta 7/L(-/-) mice. Although the leukocyte rolling flux fraction was reduced by 70%, Peyer's patches in L-/- mice were of normal size and cellularity. In beta 7-/- mice, the rolling flux fraction was normal, but the number of adherent leukocytes in HEV was greatly reduced. The median leukocyte rolling velocity was reduced in L-/- mice and increased in beta 7-/- mice, suggesting that beta 7 integrins and L-selectin mediate rolling in Peyer's patch HEV at different velocities. beta 7/L(-/-) exhibited both a low rolling flux fraction and low adhesion and had severely reduced Peyer's patch size and cellularity. The residual rolling in these mice was completely blocked by a P-selectin mAb. A significant P-selectin component was also detected in the other genotypes. Twenty-six percent of B and T lymphocytes isolated from Peyer's patches of wild-type mice expressed functional ligands for P-selectin, and this fraction was increased to 57% in beta 7/L(-/-) mice. Peyer's patch HEV were found to express P-selectin under the conditions of intravital microscopy, but not in situ. Our data suggest a novel P-selectin dependent mechanism of lymphocyte homing to Peyer's patches. In situ, beta 7 integrins and L-selectin account for all lymphocyte homing to Peyer's patches, but P-selectin-dependent rolling, as induced by minimal trauma, may support trafficking of effector T lymphocytes to Peyer's patches.

Important contributions of P-selectin glycoprotein ligand-1-mediated secondary capture to human monocyte adhesion to P-selectin, E-selectin, and TNF-alpha-activated endothelium under flow in vitro.

In this study, an in vitro flow model and a blocking mAb to P-selectin glycoprotein ligand-1 (PSGL-1) were used to define the role of PSGL-1 in monocyte attachment and rolling on E- and P-selectin and in attachment and accumulation on 6-h TNF-alpha-activated HUVEC. KPL1, an adhesion-blocking mAb directed against the tyrosine sulfate motif of PSGL-1, abolished monocyte-adhesive interactions with P-selectin, but only partially blocked monocyte interaction with E-selectin. Further analysis showed that on E-selectin, KPL1 blocked only secondary (i.e., monocyte/monocyte) interactions, but did not block primary (i.e., monocyte/E-selectin) interactions, with secondary adhesion accounting for 90% of the total adhesive interactions on either E- or P-selectin. On cytokine-activated HUVEC, monocytes initially attached and formed linear strings of adherent cells, which involved both primary and secondary adhesion. PSGL-1 or L-selectin mAb reduced string formation, and the combination of PSGL-1 and L-selectin mAb prevented monocyte strings and inhibited 86% of accumulation. Monocyte attachment and rolling on purified adherent monocytes were also critically dependent on PSGL-1 on the adherent monocytes. These studies document that secondary interactions between monocytes, mediated by PSGL-1, are crucial for monocyte initial attachment, rolling, and accumulation on activated endothelium under laminar shear flow.

[Lack of stimulation of CD11b/CD18 induced leukocyte adhesioin by platelet activating factor (PAF) and f-MLP in malignant tumor endothelium in experimental pancreas cancer of the rat]. / Fehlende Stimulierbarkeit der CD11b/CD18-vermittelten Leukozytenadhäsion durch Platelet-Activating-Faktor (PAF) und f-MLP im malignen Tumorendothel beim experimentellen Pankreaskarzinom der Ratte.

UNLABELLED: The interaction between immunocompetent cells and tumor-endothelium is essential for effective immunologic recognition. In the present study we evaluated resting and CD11b/CD18-mediated leukocyte adhesion on tumor-endothelium of experimental pancreatic carcinoma and in healthy pancreatic venules. METHODS: 22 male Lewis rats (120-140 g) were anesthetized. Duct-like pancreatic carcinoma (DSL6A, Am. J. Pathol. 1993; 143:292) was induced by intrapancreatic implantation of tumor fragments between inert polymethylmetacrylat plates. After 4 wks the tumor-bearing pancreas was exposed and the microcirculation studied. Parameters in tumor vessels (15-40 microns) and healthy pancreatic collecting venules (20-40 microns) included: Erythrocyte velocity, Leukocyte adhesion, Vessel diameter and wall shear rate. Measurements were obtained before and 5 min after adding f-MLP (100 mM) or PAF (50 mM), two CD11b/CD18 agonists of different potency to the immersion chamber. RESULTS: [table: see text] CONCLUSION: In experimental pancreatic carcinoma leukocyte adhesion of low affinity is reduced despite comparable wall shear rates. The CD11b/Cd18-mediated adhesion of high affinity, which is inducible by f-MLP and PAF in healthy pancreatic venules, is absent in tumor vessels. This may be a mechanism by which malignant tumors escape immune control.

E-selectin preferentially supports neutrophil but not eosinophil rolling under conditions of flow in vitro and in vivo.

The selectin family of adhesion molecules is composed of the L-, E-, and P-selectins, which promote leukocyte rolling during inflammation. Although E-selectin supports neutrophil and lymphocyte rolling, its ability to mediate eosinophil rolling under conditions of flow in vitro and in vivo has not been determined. Using function-blocking mAbs raised against rabbit E-selectin, we have determined whether E-selectin supports human eosinophil rolling in comparison to human neutrophil rolling in IL-1-stimulated rabbit mesenteric venules utilizing intravital microscopy. Anti-rabbit E-selectin mAbs 8B9 and 8G9 were found to inhibit neutrophil rolling but had no significant effect on eosinophil rolling. Likewise, mAb 8B9 F(ab')2 fragments were found to block neutrophil rolling, but did not significantly alter the flux of rolling eosinophils. Isotype-matched Abs and a nonblocking anti-rabbit E-selectin mAb 2A5 failed to inhibit both neutrophil and eosinophil rolling on venular endothelium. In support of these in vivo observations, significant numbers of human neutrophils but not eosinophils were found to avidly roll on monolayers of E-selectin transfectants under physiologic condition of flow in vitro. Under subphysiologic conditions of shear (0.17-0.5 dyn/cm2), eosinophils rolled on E-selectin, albeit in lower numbers (three- to sevenfold) compared with neutrophils. In addition, the rolling velocity of eosinophils was significantly higher compared with neutrophils on E-selectin transfectants. These studies suggest that at physiologic shear rates, E-selectin is likely to function as a major vascular adhesion receptor in mediating neutrophil but not eosinophil rolling in inflamed postcapillary venules.

Histometric studies on biopsies of tuberculin skin tests showing evidence of ischaemia and necrosis.

In a study of tuberculin skin tests in 216 consecutive untreated pulmonary tuberculosis patients, one showed central necrosis at 48 h: there was no effective blood flow at the centre of this lesion, but the periphery was markedly hyperaemic. Many dermal capillaries and venules contained deposits of fibrin, but none was occluded completely: the surviving cells in the dermal infiltrate were almost all macrophages. Five patients with strongly positive reactions at 48 h showed slower blood flow at the centre of the reaction than at the periphery (central relative slowing, CRS), possibly indicating central ischaemia short of necrosis: no fibrin deposits were seen in the dermal vessels of these skin test sites. The cellular infiltrate in the dermis was similar in distribution, but more abundant than that seen in uncomplicated positive reactions of comparable clinical size and with blood flow velocity maximal at the centre. At 48 h, lymphocytes were more numerous than macrophages in both groups, CD8 lymphocytes were more abundant in CRS reactions, but CD4 and CD25 (activated) T-lymphocytes and macrophages had a similar density in both groups. Epidermal CD1 cells were less frequent in CRS reactions than in uncomplicated positive reactions. Although CRS reactions showed more intense inflammation than the uncomplicated controls, none of the histometric measurements correlated with the extent of CRS. Follow-up studies showed that CRS reactions reverted to a normal hyperaemic blood flow pattern 5 days after antigen injection.(ABSTRACT TRUNCATED AT 250 WORDS)