IL-6: A Janus-like factor in abdominal aortic aneurysm disease

AbstractBackground and aimsAn abdominal aortic aneurysm (AAA) is part of the atherosclerotic spectrum of diseases. The disease is hallmarked by a comprehensive localized inflammatory response with striking IL-6 hyperexpression. IL-6 is a multifaceted cytokine that, depending on the context, acts as a pro- or anti-inflammatory factor. In this study, we explore a putative role for IL-6 in AAA disease.MethodsELISA’s, Western blot analysis, real time PCR and array analysis were used to investigate IL-6 expression and signaling in aneurysm wall samples from patients undergoing elective AAA repair. A role for IL-6 in AAA disease was tested through IL-6 neutralization experiments (neutralizing antibody) in the elastase model of AAA disease.ResultsWe confirmed an extreme disparity in aortic wall IL-6 content between AAA and atherosclerotic disease (median [5th–95th percentile] aortic wall IL-6 content: 281.6 [0.0–1820.8] (AAA) vs. 1.9 [0.0–37.8] μg/g protein (atherosclerotic aorta), (p < 0.001). Array analysis followed by pathway analysis showed that IL-6 hyper-expression is followed by increased IL-6 signaling (p < 0.000039), an observation confirmed by higher aneurysm wall pSTAT3 levels, and SOCS1 and SOCS3 mRNA expression, (p < 0.018).Remarkably, preventive IL-6 neutralization i.e. treatment started one day prior to the elastase-induction resulted in >40% 7-day mortality due to aortic rupture. In contrast, delayed IL-6 neutralization (i.e. neutralization started at day 4 after elastase induction) did not result in ruptures, and quenched AAA growth (p < 0.021).ConclusionsAAA disease is characterized by increased IL-6 signaling. In the context of the elastase model of AAA disease, IL-6 appears a multi-faceted factor, protective upon acute injury, but negatively involved in the perpetuation of the disease process

Имитационное моделирование технологии управления процессом производства

Предложено использование комплекса имитационного моделирования для получения информации при контроле функционирования и управлении технологическим процессом производства.Запропоновано використання комплексу імітаційного моделювання для одержання інформації при контролюванні функціонування та управління технологічним процесом виробництва.Complex of simulation modeling for obtaining information when checking an operation and control of technological process of production is offered to use

CXCL8 hyper-signaling in the aortic abdominal aneurysm

There are indications for elevated CXCL8 levels in abdominal aortic aneurysm disease (AAA). CXCL8 is concurrently involved in neutrophil-mediated inflammation and angiogenesis, two prominent and distinctive characteristics of AAA. As such we considered an evaluation of a role for CXCL8 in AAA progression relevant. ELISA's, real time PCR and array analysis were used to explore CXCL8 signaling in AAA wall samples. A role for CXCL8 in AAA disease was tested through the oral CXCR1/2 antagonist DF2156A in the elastase model of AAA disease. There is an extreme disparity in aortic wall CXCL8 content between AAA and aortic atherosclerotic disease (median [IQR] aortic wall CXCL8 content: 425 [141–1261] (AAA) vs. 23 [2.8–89] (atherosclerotic aorta) µg/g protein (P < 1 · 10−14)), and abundant expression of the CXCR1 and 2 receptors in AAA. Array analysis followed by pathway analysis showed that CXCL8 hyper-expression in AAA is followed increased by IL-8 signaling (Z-score for AAA vs. atherosclerotic control: 2.97, p < 0.0001). Interference with CXCL8 signaling through DF2156A fully abrogated AAA formation and prevented matrix degradation in the murine elastase model of AAA disease (p < 0.001). CXCL8-signaling is a prominent and distinctive feature of AAA, interference with the pathway constitutes a promising target for medical stabilization of AAA

A potential role for glycated cross-links in abdominal aortic aneurysm disease

BACKGROUND: Diabetes is a risk factor for atherosclerotic disease but negatively associated with the development and progression of abdominal aortic aneurysm (AAA). Advanced glycation end products (AGEs) are increased in diabetes and renders the vascular matrix more resistant to proteolysis. We assessed the concentration of AGEs in AAA biopsies obtained from diabetic and nondiabetic patients and hypothesized that (nonenzymatic) glycation of AAA tissue protects against proteolytic breakdown of collagen. METHODS: AAA biopsies were collected from 30 diabetic and 30 matched nondiabetic AAA patients at the time of open repair. Aortic control samples from 10 nondiabetic and 16 diabetic patients were collected, and concentrations of the AGE cross-link pentosidine was measured. Furthermore, noncross-linking AGEs (adducts), as well as proteolytic enzymes known to play a role in aneurysm development (matrix metalloproteinase [MMP]-2, MMP-9, cathepsin B and S) were quantified. Ex vivo, nondiabetic AAA biopsies were glycated and measured subsequently for collagen type I release. RESULTS: Pentosidine concentrations in AAA wall biopsies were increased in patients with diabetes compared with nondiabetics 9.4 (5.0-13.5) vs 6.0 (2.5-9.6) pmol/μmol lysine (P = .02). Increased pentosidine concentrations were also observed in nonaneurysmatic aortic wall biopsies from diabetic patients. In diabetic AAA vascular wall tissue, pentosidine concentration was negatively correlated with aortic diameter (r = -0.43; P = .02). Ex vivo glycated AAA biopsies were resistant against MMP-induced collagen type I degradation as compared with controls (7.0 vs 10.4 μg/L; P = .02). No differences were observed for AGEs that are not forming cross-links. CONCLUSIONS: These findings suggest that cross-linking AGEs like pentosidine play a protective role in AAA progression in diabetic patients

A potential role for glycated cross-links in abdominal aortic aneurysm disease

BACKGROUND: Diabetes is a risk factor for atherosclerotic disease but negatively associated with the development and progression of abdominal aortic aneurysm (AAA). Advanced glycation end products (AGEs) are increased in diabetes and renders the vascular matrix more resistant to proteolysis. We assessed the concentration of AGEs in AAA biopsies obtained from diabetic and nondiabetic patients and hypothesized that (nonenzymatic) glycation of AAA tissue protects against proteolytic breakdown of collagen. METHODS: AAA biopsies were collected from 30 diabetic and 30 matched nondiabetic AAA patients at the time of open repair. Aortic control samples from 10 nondiabetic and 16 diabetic patients were collected, and concentrations of the AGE cross-link pentosidine was measured. Furthermore, noncross-linking AGEs (adducts), as well as proteolytic enzymes known to play a role in aneurysm development (matrix metalloproteinase [MMP]-2, MMP-9, cathepsin B and S) were quantified. Ex vivo, nondiabetic AAA biopsies were glycated and measured subsequently for collagen type I release. RESULTS: Pentosidine concentrations in AAA wall biopsies were increased in patients with diabetes compared with nondiabetics 9.4 (5.0-13.5) vs 6.0 (2.5-9.6) pmol/μmol lysine (P = .02). Increased pentosidine concentrations were also observed in nonaneurysmatic aortic wall biopsies from diabetic patients. In diabetic AAA vascular wall tissue, pentosidine concentration was negatively correlated with aortic diameter (r = -0.43; P = .02). Ex vivo glycated AAA biopsies were resistant against MMP-induced collagen type I degradation as compared with controls (7.0 vs 10.4 μg/L; P = .02). No differences were observed for AGEs that are not forming cross-links. CONCLUSIONS: These findings suggest that cross-linking AGEs like pentosidine play a protective role in AAA progression in diabetic patients

Superior in vivo compatibility of hydrophilic polymer coated prosthetic vascular grafts

Protein adsorption, cell adhesion and graft patency was compared in hydrophilic versus hydrophobic polymer-coated prosthetic vascular grafts. We hypothesize that in vivo compatibility of hydrophilic polymer-coated prosthetic vascular grafts is superior to in vivo compatibility of hydrophobic grafts. A pairwise side-to-side common carotid artery interposition graft was placed eight female landrace goats (mean weight 55 kg). Protein adsorption was assessed using Western Blot in two hydrophilic and two hydrophobic grafts harvested after three days. Graft patency was monitored for 28 days in six goats with continuous wave Doppler ultrasonography. Adherence of endothelial cells, leukocytes and platelets was determined with ELISA and compared between the two graft types after 28 days. After three days, more ApoA-I, albumin and VEGF and less fibrin adsorbed to hydrophilic grafts. After 28 days, compared to hydrophobic grafts, higher numbers of endothelial cells were present on hydrophilic grafts (P=0.016), and less thrombocytes and leukocytes (P=0.012 and 0.024, respectively). Two out of eight hydrophobic grafts lost patency, while none of the hydrophilic grafts failed (P=0.157). Hydrophilic polymer-coated vascular grafts have superior in vivo compatibility when compared to hydrophobic grafts as characterized by reduced platelet and leukocyte adherence as well as higher endothelializatio

Osteoprotegerin is associated with aneurysm diameter and proteolysis in abdominal aortic aneurysm disease

Objective: Serum osteoprotegerin (OPG) concentrations have previously been associated with growth of abdominal aortic aneurysms (AAAs). In vitro experiments showed that OPG promotes matrix metalloprotease (MMP) release from monocytes and vascular smooth muscle cells. We hypothesized that OPG expression is increased in human AAAs and is associated with proteolysis. Methods and Results: AAA biopsies were collected from 329 patients. We assessed the concentrations of OPG, cathepsins A, B, and S as well as the activity of MMP-2 and MMP-9. The AAA wall infiltration by macrophages, lymphocytes, and plasma cells was estimated by immunohistochemistry. The concentration of OPG correlated positively with aortic diameter (70 mm: 24.0 [13.5–52.9] ng OPG/mg total amount of protein, P=0.020), cathepsin A (r=0.221, P=0.005), B (r=0.384, P<0.001), and S (r=0.467, P<0.001), MMP-2 (r=0.180, P<0.001), MMP-9 (r=0.178, P<0.001), and the number of lymphocytes (P<0.001) and plasma cells (P=0.001). OPG immunostaining was predominantly demonstrated in plasma cells. Conclusion: The concentration of aortic wall OPG is positively associated with established markers of AAA severity and pathogenesis. OPG appeared to be associated with lymphocytes and plasma cells. These human data support previous experimental data suggesting a role for OPG in AAA pathogenesis

Histology of carotid aneurysms.

<p>A-D, dissection; E and F, degeneration. A, overview of aneurysm due to dissection. Elastin-van Giesson (EvG) stain. Bar = 1.5 mm. B, higher magnification of the same staining as A. Arrow indicates the disrupted internal elastic lamina. Bar = 500 μm. C, Hematoxylin and eosin staining of the same panel as B. m, media; t, organized thrombus that replaces the absent media. Bar = 500 μm. D, CD34 immunostain showing endothelial coverage of the thrombus (in brown). Bar = 250 μm. E, overview of an aneurysm due to degeneration. Elastin-van Giesson (EvG) stain. Bar = 4 mm. F, higher magnification of the same staining as E. In black remnants of the elastic fibers of the media. Bar = 1 mm.</p

Histology of control sample: fibrous cap atheroma.

<p>Histology of control sample. Sample taken just distal from the bifurcation. Elastin-van Giesson (EvG) stain. In black the elastic fibers are clearly present and well organized. Atherosclerotic changes, atheroma with a lipid core. E, Elastin; Lip, Lipid core; Lum ext., lumen of the external carotid artery; Lum int., lumen of the internal carotid artery.</p

In vivo aneurysm.

<p>Aneurysm of a left saccular carotid artery visible between the internal carotid artery (ICA) and the external carotid artery (ECA) and originating from a dorsal loop in the ICA. The common carotid artery is ligatured in red, the ECA is identified with transparent ligatures. A, aneurysm of the ICA; BIF, carotid bifurcation; H, nervus hypoglossus; S, suture; VL, vessel loop.</p