KannelWMcGeeD: Diabetes and cardiovascular disease: The Framingham studyJAMA1979, 241:2035–2038.
2.
ChmielewskaJRanbyMWimanB: Evidence for a rapid inhibitor to tPA in plasmaThromb Res1983, 31:427–463.
3.
DeclerckPJVerstrekenMCollenD: Measurement of different forms of plasminogen activator inhibitor-1 (PAI-1) using various monoclonal antibody based enzyme-linked immunosorbent assaysFibrinolysis1990, 4 (suppl 2):132–133.
4.
DeclerckPJAlessiMCVerstrekenMKruithofEKOJuhan-VagueICollenD: Measurement of plasminogen activator inhibitor-1 in biological fluids with a murine monoclonal antibody based enzyme-linked immunosorbent assayBlood1988, 1:220–225.
5.
AuwerxJBouillonRCollenDGeboersJ: Tissue-type plasminogen activator antigen and plasminogen activator inhibitor in diabetes mellitusArteriosclerosis1988, 8:68–72.
6.
ChomikiNHenryMAlessiMCAnfossoFJuhan-VagueI: Plasminogen activator inhibitor-1 expression in human liver and healthy or atherosclerotic vessel wallsThromb Haemost1994, 72:44–53. ∗ In atherosclerotic vessels, PAI-1 expression was observed in neovessels surrounding the lesion, in intimai cells and in smooth muscle cells. This local increase in PAI-1 could lead to fibrin deposition during plaque rupture, contributing to the development and progression of the lesion.
7.
PadróTEmeisJJSteinsMSchmidKWKienastJ: Quantification of plasminogen activators and their inhibitors in the aortic vessel wall in relation to the presence and severity of atherosclerotic diseaseArterioscler Thromb Vasc Biol1995, 15:893–902. ∗ Quantitative analyses of activity and antigen levels of individual components of the fibrinolytic system was analysed in serial sections of aortic tissue obtained during autopsy. An excess of PAI-1 over plasminogen activators was found in atherosclerotic lesions of the human aorta.
8.
MiskinRAxelrodJHGriepAELeeEBelinDVassalliJD et al.: Human and murine urokinase cDNAs linked to the murine A-crystallin promoter exhibit lens and non-lens expression in transgenic miceEur J Biochem1990, 190:31–38.
9.
GrisJCSchvedJFFeugeasOAguilar-MartinezPArundASanchezN: Impact of smoking, physical training and weight reduction on FVII and haemostatic markers in sedentary menThromb Haemostas1990, 64:516–520.
10.
FolsomARQamhiehHTWingRRJefferyRWStinsonVLKullerLH et al.: Impact of weight loss on plasminogen activator inhibitor (PAI-1), factor VII, and other hemostatic factors in moderately overweight adultsAtheroscler Thromb1993, 13:162–169.
11.
GoughSCLMcCormackLRicePJSGrantPJ: The fibrinolytic response to exercise at diagnosis and after 12 months in patients with type 2 diabetes mellitusFibrinolysis1994, 8:372–377.
12.
GrantPJKruithofEKOFellyCPFelberJPBachmannF: Short-term infusions of insulin, triacylglycerol and glucose do not cause acute increases in plasminogen activator inhibitor-1 concentrations in manClin Sci1990, 79:513–516.
13.
Vuorinen-MarkkolaHPuhakainenIYki-JärvinenH: No evidence of short-term regulation of plasminogen activator inhibitor activity by insulin in manThromb Haemost1992, 67:117–120.
14.
McCormackLStricklandMHGrantPJ: Plasminogen activator inhibitor-1 antigen concentrations during insulin and oral glucose tolerance tests in obese manFibrinolysis1993, 7:225–228.
15.
BarriocanalLAMishraVTarbitMKestevenPAlbertiKGMMWalkerM: The effect of triglyceride infusion on the regulators of fibrinolysisFibrinolysis1995, 9:243–246.
16.
GrantPJSticklandMHBoothNAPrenticeCRM: Metformin causes a reduction in post venous occlusion plasminogen activator inhibitor-1 in type 2 diabetic patientsDiabetic Med1991, 8:361–365.
17.
NagiDKYudkinJS: Effects of metformin on insulin resistance, risk factors for cardiovascular disease, and plasminogen activator inhibitor in NIDDM subjectsDiabetes Care1993, 16:4621–4629.
18.
JainSKNagiDKSlavinBMLumbPJYudkinJS: Insulin therapy in type 2 diabetic subjects suppresses plasminogen activator inhibitor (PAI-1) activity and proinsulin-like molecules Independently of glycaemic controlDiabetic Med1993, 10:27–32.
19.
PanahlooAMohamed-AliVDenverEYudkinJS: The effect of hypoglycaemic therapy in subjects with non-insulin-dependent diabetes on insulin sensitivity, fibrinolysis and lipids [abstract]Diabetic Med1995, 12:P76.
20.
NordtTSawaHFujiiSSobelE: Induction of plasminogen activator inhibitor type-1 (PAI-1) by proInsulin* and Insulin in vivoCirculation1995, 91:764–770. ∗ The first in-vivo study, showing that infusions of proinsulin as well as insulin increase plasma PAI-1 activity in rabbits. PAI-1 messenger RNA was increased in aorta and liver. The results suggest that elevated levels of both proinsulin and insulin in NIDDM may increase plasma PAI-1 activity.
21.
AlessiMCJuhan-VagueIKooistraTDeclerckPJCollenD: Insulin stimulates the synthesis of plasminogen activator inhibitor 1 by the human hepatocellular cell line HepG2Thromb Haemost1988, 60:491–494.
22.
KooistraTBosmaPJTönsHAMvan den BergAPMeyerPPrincenHMG: Plasminogen activator inhibitor 1: Biosynthesis and mRNA level are increased by insulin in cultured human hepatocytesThromb Haemost1989, 62:723–728.
23.
GrantPJRüeggMMedcalfRL: Basal expression and insulin-mediated induction of PAI-1 mRNA in HepG2 cellsFibrinolysis1991, 5:81–86.
24.
SchneiderDJSobelBE: Augmentation of synthesis of plasminogen activator inhibitor type 1 by insulin and insulin-like growth factor type I: Implication for vascular disease in hyperinsulinemic statesProc Natl Acad Sci USA1991, 88:9959–9963.
25.
SchneiderDJNordtTKSobelBE: Stimulation by proinsulin of expression of plasminogen activator inhibitor type-1 in endothelial cellsDiabetes1992, 41:890–895.
26.
AnfossoFChomikiNAlessiMCVaguePJuhan-VagueI: Plasminogen activator inhibitor-1 synthesis in the human hepatoma cell line Hep G2: Metformin inhibits the stimulating effect of insulinJ Clin Invest1993, 91:2185–2193. ∗ An insulin-resistant state was induced in HepG2 cells by preincubation with insulin. Increased PAI-1 synthesis was demonstrated in these ‘resistant’ cells, an effect that was blocked by the drug metformin.
27.
KlassenKJNordtTKSchneiderDJSobelBE: Constitutive biosynthesis of plasminogen activator inhibitor type-1 (PAI-1) by cultured human aortic endothelial cells independent of insulinCoronary Artery Dis1993, 4:713–719.
28.
NordtTSchneiderDSobelE: Augmentation of synthesis of plasminogen activator inhibitor type-1 by precursors of insulin. A potential risk factor for vascular diseaseCirculation1994, 89:321–330.
29.
AlessiMCAnfossoFHenryMPeirettiFNalboneGJuhan-VagueI: Up-regulation of PAI-1 synthesis by insulin and proinsulin in HepG2 cells but not in endothelial cellsFibrinolysis1995, 9:237–242.
30.
PyöräläKSavolainenSKaukolaSHaapakoskiJ: Plasma insulin as coronary heart disease risk factor: Relationship to other risk factors and predictive value during 9_* year follow-up of the Helsinki policeman study populationActa Med Scand1985, 701 (suppl):38–52.
31.
Juhan-VagueIRoulCAlessiMCArdissoneJPHeimMVagueP: Increased plasminogen activator inhibitor activity in non insulin dependent diabetic patients: Relationship with plasma insulinThromb Haemost1989, 61:370–373.
32.
Juhan-VagueIThompsonSGJespersenJ: Involvement of the hemostatic system in the insulin resistance syndrome: A study of 1500 patients with angina pectorisAtheroscler Thromb1993, 13:1865–1873. ∗ A strong relationship was observed between plasma insulin and PAI-1 in 1484 patients in the ECAT angina pectoris study.
NagiNKHendraTJRyleAJCooperTMTempleRCClarkPMS et al.: The relationship of concentrations of insulin, intact proinsulin and 32,33 split proinsulin with cardiovascular risk factors in type 2 (non-insulin-dependent) diabetic subjectsDiabetologia1990, 33:532–537.
35.
GallowayJAHooperSASpradlinCTHoweyDCFrankBHBowsherRR et al.: Biosynthetic human proinsulin: Review of chemistry, in vitro and in vivo receptor binding, animal and human pharmacology studies, and clinical trial experienceDiabetes Care1992, 15:666–692.
36.
PanahlooAMohamed-AliVLaneAGreenFHumphriesSYudkinJS: Determinants of PAI-1 activity in treated type 2 diabetes and its relation to a polymorphism in the PAI-1 geneDiabetes1995, 44:37–42. ∗ A cross-sectional study in 146 patients with NIDDM, relating PAI-1 activity to cardiovascular risk factors, the 4G/5G promoter poymorphism of the PAI-1 gene and hypoglycaemic therapy. The PAI-1 genotype-triglyceride interaction and insulin sensitivity were the major determinants of PAI-1 activity.
37.
Potter van LoonBJKluftCRadderJKBlankensteinMAMeindersAE: The cardiovascular risk factor plasminogen activator inhibitor type 1 is related to insulin resistanceMetabolism1993, 42:945–949.
38.
MaielloMBoeriDPodestaFCaglieroEVichiMOdettiP et al.: Increased expression of tissue plasminogen activator and its inhibitor and reduced fibrinolytic potential of human endothelial cells cultured in elevated glucoseDiabetes1992, 41:1009–1015.
39.
NordtTKKlassenJKSchneiderDJSobelBE: Augmentation of synthesis of plasminogen activator inhibitor type-1 in arterial endothelial cells by glucose and its Implication for local fibrinolysisArterioscler Thromb1993, 13:1822–1828.
40.
AuwerxJBouillonRCollenDGeboersJ: Tissue-type plasminogen activator antigen and plasminogen activator inhibitor in diabetes mellitusArteriosclerosis1988, 8:68–72.
41.
MansfieldMWSticklandMHCarterAMGrantPJ: Polymorphism of the plasminogen activator inhibitor-1 gene in type 1 and type 2 diabetes, and in patients with diabetic retinopathyThromb Haemost1994, 71:731–736.
42.
WestKMAhujaMMSBennettPHCzyczkAde AcostaOMFullerJH: The role of circulating glucose and triglyceride concentrations and their interactions with other ‘risk factors’ as determinants of arterial disease in nine diabetic population samples from the WHO Multinational StudyDiabetes Care1983, 6:361–369.
43.
FontbonneAMEschwègeEMCambienFRichardJLDucimetièrePThibultN: Hypertriglyceridaemia as a risk factor of coronary heart disease mortality in subjects with impaired glucose tolerance or diabetes: Results from the 11 year follow-up of the Paris Prospective studyDiabetologia1989, 32:300–304.
44.
LaaksoMLehtoSPenttiläPyörälä K: Lipids and lipoproteins predicting coronary heart disease mortality and morbidity in patients with non-insulin-dependent diabetesCirculation1993, 88:1421–1430.
45.
VaguePJuhan-VagueIAillaudMFBadierCViardRAllessiMC: Correlations between blood fibrinolytic activity, plasminogen activator inhibitor levels, plasma insulin and relative body weight in normal and obese subjectsMetabolism1986, 35:250–253.
46.
MehtaJMehtaPLawsonDGoldeenT: Plasma tissue plasminogen activator inhibitor levels in coronary artery disease: Correlation with age and serum triglyceride concentrationsJ Am Coll Cardiol1987, 9:263–268.
47.
Asplund-CarlsonAHamstenAWimanBCarlsonLA: Relationship between plasma plasminogen activator inhibitor-1 activity and VLDL triglyceride concentration, insulin levels and Insulin sensitivity: Studies in randomly selected normo- and hypertriglyceridaemic menDiabetologia1993, 36:817–825. ∗ VLDL triglyceride concentrations in normo- and hypertriglyceridaemic men were the major determinant of plasma PAI-1 activity.
48.
MussoniLMannucciLSirtoriMCameraMMadernaPSironiL et al.: Hypertriglyceridemia and regulation of fibrinolytic activityArterioscler Thromb1992, 12:19–27.
49.
Stiko-RahmAWimanBHamstenANilssonJ: Secretion of plasminogen activator inhibitor-1 from cultured human umbilical vein cells is induced by very low density lipoproteinArteriosclerosis1990, 10:1067–1073.
50.
TremoliECameraMMadernaPSironiLPratiLColliS et al.: Increased synthesis of plasminogen activator inhibitor-1 by cultured human endothelial cells exposed to native and modified LDLs. An LDL receptor-independent phenomenonArterioscler Thromb1993, 13:338–346.
51.
LatronYChautanMAnfossoFAlessiMCNalboneGLafontHJuhan-VagueI: Stimulating effect of oxidised low density lipoprotein on plasminogen activator inhibitor-1 synthesis by endothelial cellsAtheroscler Thromb1991, 6:1821–1829.
52.
KugiyamaKSakamotoTMisumiISugiyamaSOhgushiMOgawaH et al.: Transferable lipids in oxidised low-density lipoprotein stimulate plasminogen activator inhibitor-1 and inhibit tissue-type plasminogen activator release from endothelial cellsCirc Res1993, 73:335–343.
53.
EtinginOHajjarDHajjarKHarpelPNachmanR: Lipoprotein(a) regulates plasminogen activator inhibitor-1 expression in endothelial cells. A potential mechanism in thrombogenesisJ Biol Chem1991, 266:2459–2465.
54.
LevinEGMilesLAFlessGMScanuAMBaynhamPCurtissLK et al.: Lipoproteins inhibit the secretion of tissue plasminogen activator from human endothelial cellsArterioscler Thromb1994, 14:438–442.
55.
ZysowBRLawnRM: The relationship of lipoprotein(a) to haemostasisCurr Opin Lipidol1993, 4:484–489.
56.
PalabriciaTMLiuACAronovitzMJFurieBLawnRMFurieBC: Antifibrinolytic activity of apolipoprotein(a): Transgenic mice are resistant to tissue plasminogen activator-mediated thrombolysisNature Med1995, 1:256–259. ∗ A direct effect in vivo of apolipoprotein(a) on fibrinolysis was demonstrated in transgenic mice expressing the apolipoprotein (a) gene.
57.
BastardJPBruckertERobertJJAnkriAGrimaldiAJardelC et al.: Are free fatty acids related to plasma plasminogen activator inhibitor 1 in android obesity?Int J Obesity1995, 19:836–838.
58.
DawsonSHamstenAWimanBHenneyAHumphriesS: Genetic variation at the plasminogen activator inhibitor-1 locus is associated with altered levels of plasminogen activator inhibitor-1 activityArterioscler Thromb1991, 11:183–190.
59.
DawsonSJWimanBHamstenAGreenFHumphriesSHenneyA: The two allele sequence of a common polymorphism in the promoter of the plasminogen activator inhibitor-1 (PAI-1) gene responds differently to IL-1 in HEPG2 cellsJ Biol Chem1993, 268:10739–10745. ∗ A common single-base-pair insertion(5G)/deletion (4G) polymorphism was detected in the promoter region of the PAI-1 gene. In young survivors of myocardial infarction, individuals possessing the 4G allele had higher plasma PAI-1 activity.
60.
ErikssonPKallinBvan T HooftFMBåvenholmPHamstenA: Allele specific increase in basal transcription of the plasminogen activator inhibitor 1 gene is associated with myocardial infarctionProc Natl Acad Sci USA1995, 92:1851–1855. ∗ The prevalence of the 4G-allele of the 4G/5G promoter polymorphism of the PAI-1 gene was significantly higher in young patients with myocardial infarction. The 4G-allele-specific increase in plasma PAI-1 activity was related to differential binding of transcription factors.
61.
MansfieldMWSticklandMHGrantPJ: Plasminogen activator inhibitor (PAI-1) promoter polymorphism and coronary artery disease in non-insulin-dependent diabetesThromb Haemost1995, 74:1032–1034.
62.
YeSGreenFRScarabinPYNicaudVBaraLDawsonSJ et al.: The 4G/4G genetic polymorphism in the promoter of the ploasminogen activator inhibitor-1 gene is associated with differences in plasma PAI-1 activity but not with risk of myocardial infarction in the ECTIM studyThromb Haemost1995, 74:837–841.
63.
MansfieldMWSticklandMHGrantPJ: Environmental and genetic factors in relation to elevated circulating levels of plasminogen activator inhibitor-1 in Caucasian patients with non-insulin-dependent diabetes mellitusThromb Haemost1995, 74:842–847.
64.
MeadeTWRuddockVStirlingYChakrabartiRMillerGJ: Fibrinolytic activity, clotting factors and long-term incidence of ischaemic heart disease in the Northwick Park heart studyLancet1993, 342:1076–1079. ∗ Low fibrinolytic activity, as measured by the dilute clot lysis time, appeared to be a strong determinant of CAD.
65.
HamstenAWimanBDe FaireUBlombãckM: Increased plasma level of a rapid inhibitor of tissue plasminogen activator in young survivors of myocardial infarctionN Engl J Med1985, 40:113–121.
66.
HamstenADe FaireUWalldiusGDahlenGSzamosiALandouC: Plasminogen activator inhibitor in plasma: Risk factor for recurrent myocardial infarctionLancet1987, ii:3–9.
67.
YudkinJSHendraTJ: Vascular events and diabetes: Acute myocardial infarction and strokeInternational Textbook of Diabetes Mellitus. London: John Wiley & Sons Ltd, 1992.
68.
GrayRPYudkinJSPattersonDL: Plasminogen activator inhibitor: A risk factor for myocardial infarction in diabetic patientsBr Heart J1993, 69:228–232.
69.
GrayRPYudkinJSPattersonDL: Enzymatic evidence of impaired reperfusion in diabetic patients after thrombolytic therapy for acute myocardial infarction: A role for plasminogen activator inhibitor?Br Heart J1993, 70:530–536.
70.
JoklRLaiminsMKleinRLLyonsTJLopes-VirellaMFColwellJA: Platelet plasminogen activator inhibitor-1 in patients with type II diabetesDiabetes Care1994, 17:818–823.
71.
RidkerPMVaughanDEStampferMJMansonJEHennekensCH: Endogenous tissue-type plasminogen activator and risk of myocardial infarctionLancet1993, 341:1165–1168. ∗ Elevated t-PA antigen was associated with increased risk of future myocardial infarction.
72.
JanssonJHOlofssonBONilssonTK: Predictive value of tissue plasminogen activator mass concentration on long-term mortality in patients with coronary artery disease a 7-year follow-upCirculation1993, 88:2030–2034. ∗ Concentrations of t-PA antigen were related to the long-term risk of death in patients with angina and angiographically proven CAD. This paradoxical effect and increase in t-PA antigen probably reflects t-PA-PAI-1 complex formation.
73.
ThompsonSGKienastJPykeSDMHaverkateFVan de LooJCW, for the European Concentrated Action on Thrombosis and Disabilities Angina Pectoris Study Group: Haemostatic factors and the risk of myocardial infarction or sudden death in patients with angina pectorisN Engl J Med1995, 332:635–641. ∗ Plasma concentrations of fibrinogen, von Willebrand factor antigen, and t-PA antigen were independent predictors of subsequent myocardial infarction or sudden death from coronary artery disease among 3000 subjects in the ECAT Angina Pectoris study.
74.
García FradeLJde la CalleHTorradoMCLaraJICuellarLGarcía AvelloA: Hypofibrinolysis associated with vasculopathy in noninsulin dependent diabetes mellitusThromb Res1990, 59:51–59.
75.
HaitasBBarnesAJCederholm-WilliamsSAMooreJShgryMECTurnerRC: Abnormal endothelial release of fibrinolytic activity and fibronectin in diabetic microangiopathyDiabetologia1984, 27:493–496.
76.
WalmsleyDHamptonKKGrantPJ: Contrasting fibrinolytic responses in type 1 (insulin-dependent) and type 2 (non-insulin dependent) diabetesDiab Med1991, 8:954–959.
77.
MaserREEllisDErbeyJROrchardTJ: Little relationship of plasminogen activator inhibitor (PAI-1) with complications of insulin-dependent diabetes diabetes mellitus: Pittsburg Epidemiology of Diabetes Complications studyFibrinolysis1995, 9:139–144.
78.
University Group Diabetes Program: A study of the effects of hypoglycemic agents on vascular complications in patients with adult-onset diabetesDiabetes1970, 19 (suppl 2):747–830.
79.
FujiiSSobelBE: Direct effects of gemfibrozil on the fibrinolytic system: Diminution of plasminogen activator inhibitor type 1Circulation1992, 85:1888–1893. ∗ Pharmacological concentrations of gemfibrozil directly affected PAI-1 synthesis by decreasing basal PAI-1 secretion in HepG2 cells and also that induced by epidermal growth factor and transforming growth factor-β.
80.
BrownSLSobelBEFujiiS: Attenuation of the synthesis of plasminogen activator inhibitor type 1 by niacin: A potential link between lipid lowering and fibrinolysisCirculation1995, 92:767–772. ∗ Niacin not only decreases the constitutive synthesis of PAI-1 by HepG2 cells but also attenuates the induction of PAI-1 synthesis by transforming growth factor-β. Niacin may potentiate fibrinolysis, reducing the induction of atherothrombosis by clot-associated mitogens.
81.
LundgrenCHBrownSLNordtTKSobelBDFujiiS: Elaboration of type-1 plasminogen activator inhibitor from adipocytesCirculation1996, 93:106–110. ∗ Expression of PAI-1 was demonstrated in adipose tissue suggesting a novel mechanism by which obesity leads to increased plasma PAI-1 and, consequently, accelerated atherosclerosis.
82.
SamadSYamamotoKLuskutoffDJ: Distribution and regulation of plasminogen activator inhibitor-1 in murine adipose tissue in vivoJ Clin Invest1996, 97:37–46.
