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Ann.N.Y.Acad.Sci.ISSN0077-8923 ANNALS OF THE NEW YORK ACADEMY OF SCIENCES Issue:InnateInflammationandStroke Introduction to innate inflammation: the common denominator of risk factors leading to stroke and TIA Ihavebeengiventhedifficulttaskoftryingtopresentaclinician’sreactiontothebasicscienceand clinicallyorientedpresentationsinthissymposium.Iwillnotcommentonthetechnicalaspects of the basic science—it would be improper for me to do so. Instead I will attempt to extract a broad view of the extensive and very diverse information discussed—that is, characterize the forestfromthetrees. Threeanalogiesoccurtome. (1) New York City, the location of this meeting. The epidemiological data indicate striking variations in traditional atherosclerotic risk factors (hypertension, dyslipidemia, diabetes, metabolicsyndrome,obesity,inactivity,andsmoking),genedistributionthataffectsthese riskfactors,andthepresenceandextentofinflammationandinflammatorymarkers.The basicsciencestudiesalsoshowaremarkablevariability,dependingonthefactorsstudiedand theexperimentalprotocols.Sohowshouldaclinicianconcludewhatfactorsareimportant in an individual patient? In any geographical region, for example, New York, that would depend whether one studied, for instance, Chinatown, the Bronx, the Bowery, the Lower East Side, or Brooklyn. The diversities impress me more than the similarities, so that so- calledpersonalizedmedicine characterizationofrisks andmarkersshouldbeemphasized ratherthanlargegroupandpopulation-basedapproaches. (2) An Agatha Christie mystery. In many of her whodunits, the reader is captivated trying to identifythemurdererfromthecharactersthataredescribedindetailastheplotproceeds andthedetectivedoeshissleuthing.However,thereadermaydiscover,intheverylastor penultimatechapter,thatanewentrant,acousinorfriendofoneofthepreviouslydescribed characters,wastheculprit,muchtothefrustrationofthereader.Thestorylineissimilar withregardtogenetics,andinflammatoryandatheroscleroticriskfactors.Newersubstances, genes, and markers are discovered annually. Often these new entities are more specific or morepowerful,ormorerepresentativethantheolderestablishedones.Researchisamoving target,renderingitproblematictohitchone’sstarontoanysinglepresentfinding.Basicand clinicalresearchmustcontinuouslyconsiderandintegratenewfindings.Thismakesmuch of the research findings time related and not finally definitive. Clinicians must keep their eyesandearswelltunedtothelatestdevelopmentsandviewthesecritically. (3) The Magus, a novel by John Fowles that I recently reread. Fowles plays many tricks on readersbyfrequentlyalteringimpressionsofthecharactersandtheirmotivationsandtheir goodandeviltiters.Similarly,bothclinicalandbasicscienceresultsabouttherelevanceand importanceofvariousmarkers,genes,andfindingsvaryconsiderably.Oftenthisdepends on quantification, for example, too little and too much alcohol intake is not good, and sometimesthisdependsontheanimalorsex,age,orethniccharacterizationoftheindividual orpopulationstudied.SomestudiesfindputativefactorXtobeveryimportant,andthese findingsarehypedinthemedia,onlyforclinicianstofindthatanotherstudyrepudiatedthe doi:10.1111/j.1749-6632.2010.05727.x Ann.N.Y.Acad.Sci.1207(2010)vii–viii(cid:2)c 2010NewYorkAcademyofSciences. vii Introduction Caplan findingsofthepriorstudies.FactorY:forexample,cheesemaybetargetedascontributingto hyperlipidemiaandthedevelopmentofatheroscleroticplaques,andyet,later,newevidence shows that cheese intake promotes healthy results. At times agents predicted from basic ◦ researchtohavegreatpromisearefoundintrialstobeineffectiveorevenharmful—a180 turnaround. An example is the Enlimomab stroke trial discussed by Gregory del Zoppo. Use of a humanized murine anti-ICAM-1 antibody to inhibit endothelial cell ICAM-1– mediated adhesion of polymorphonuclear leukocytes was posited from basic research to reducethedevelopmentofstroke.Inthistrialthetreatmentwasactuallyharmful,andthe placebo-treatedpatientgroupactuallydidbetterthanthosetreatedwiththeantibody. Clinicians must be very wary of first impressions and hypotheses generated by laboratory andanimalresearch.Positedtreatmentsmustbetestedthoroughlyandindifferentgroupsand differentsituations.Thingsarenotalwayswhattheyfirstseem.Asinthissymposium,frequent andintensecommunicationamongclinicians,epidemiologists,andbasicresearchersmustgoon, andeachgroupmustlisten,butcritically,totheothersifprogressistobemade.Wearealong wayfromunderstandingthecomplexentitiesofinflammationandatherosclerosisandeonsaway fromoptimalpreventionandtreatment. LouisR.Caplan HarvardMedicalSchool Boston,Massachusetts [email protected] viii Ann.N.Y.Acad.Sci.1207(2010)vii–viii(cid:2)c 2010NewYorkAcademyofSciences. Ann.N.Y.Acad.Sci.ISSN0077-8923 ANNALS OF THE NEW YORK ACADEMY OF SCIENCES Issue:InnateInflammationandStroke How inflammation modulates central nervous system vessel activation and provides targets for intervention— a personal perspective JohnHallenbeck NationalInstituteofNeurologicalDisordersandStroke,NationalInstitutesofHealth,Bethesda,Maryland Addressforcorrespondence:JohnHallenbeck,M.D.,NationalInstituteofNeurologicalDisordersandStroke,National InstitutesofHealth,10CenterDriveMSC1401,Building10/Room5B02,Bethesda,[email protected] Iheredescribealineofresearchthatgrewoutofstudiesofspinalcord–damagingdecompressionsickness,focusedon theblood–endothelialinterface,thatwasinfluencedbythelocalShwartzmanphenomenon,addressedinnateimmune andinflammatorymechanisms,andultimatelyarrivedatmucosaltoleranceapproachestopreventstroke.Intranasal instillationofE-selectinisunderdevelopmentasanovelmeansoftargetingimmunomodulationtoactivatingblood vesselswithinthevasculartreesupplyingthebrain.Thegoalofthisformoffocusedimmunomodulationistoprevent recurrentstrokesinpatientsthathavepreviouslysufferedtransientischemicattacksorstrokes. Keywords: tolerance;stroke;cytokines;immunomodulation;endothelium;E-selectin IbeganmyresearchcareerasaBerryPlandrafteeat responsesinadditiontothedirecteffectsoflocalen- theNavalMedicalResearchInstitute,NationalNaval ergyfailureandmembranefailure.Itseemedhighly Medical Center in Bethesda Maryland in 1971, af- possiblethatthebloodflowingthroughanischemic ter having completed a neurology residency at the injuryzonecouldbecomeactivatedbythedamaged University of Michigan. My entrance into stroke or stressed tissue resembling in a general way the research was somewhat unconventional in that I activationofbloodbybubblesorotherforeignsur- moved from studies of spinal cord damage in de- faces.Furtherexaminationofthispossibilityledto compression sickness to an abiding interest in the theconceptof“blood-damagedtissueinteraction,” mechanisms that induce brain damage in strokes. aforerunnerofreperfusioninjurythatleadstopro- Amajormechanismunderlyingthepredilectionfor gressiveimpairmentofmicrovascularperfusion.4,5 spinalcorddamageincentralnervoussystem(CNS) Anintriguingmodeloffocalbloodvesselactiva- decompressionsicknessturnedouttobetheaccu- tionisthelocalizedShwartzmanreactionthatwas mulation of bubbles and activated blood products first described by Gregory Shwartzman in 1928.6 in the epidural vertebral venous system (Batson’s There is a preparatory step in which endotoxin Plexus), ultimately leading to venous obstruction, acting as a danger-associated molecular pattern compromisedtransportofnitrogenoutofthelipid- (DAMP) is injected intradermally where it acts richspinalcord,andlocalnucleationofgasbubbles through toll-like receptors7 to release proinflam- inthecord.1,2Animportantfactorintheactivation matorycytokinesandlocallyactivatebloodvessels ofbloodandlocalbloodvesselsinthevenousplexus in the skin. This will lead to some local erythema was the 40–100 A˚ zone of electrokinetic forces at thatsubsidesintheabsenceofanyfurtherstimula- bubble–bloodinterfaces(Lee&Hairston)thatacti- tion.If,however,thereisaprovocativestep,acriti- vatedthecontactactivationsystemincludingcoagu- callytimedactivationofthecoagulationsystembya lation,fibrinolysis,complement,kinins,etc.3Given smallnontoxicdoseofendotoxinadministeredin- this background, I viewed stroke from the start as travenously18–24hafterthepreparatorystep,areas a process in which blood and tissue responses to ofpetechialhemorrhageappearinthepreparedskin ischemic stress were likely to be extremely multi- andtheseenlargeandcoalesceintoanareaofhem- factorialandtoincludeinflammatoryandimmune orrhagicnecrosisthatapproachesthesizeofasilver doi:10.1111/j.1749-6632.2010.05785.x Ann.N.Y.Acad.Sci.1207(2010)1–7(cid:2)c 2010NewYorkAcademyofSciences. 1 CNSvesselactivationfocus—personalperspective Hallenbeck positivemacrophageswereincreasedinratswiththe strokeriskfactor,hypertension(e.g.,spontaneously hypertensive rats [SHR] and stroke-prone sponta- neously hypertensive rats [SHR-SP]) compared to normotensive controls (e.g., Wistar Kyoto [WKY] rats).10 In addition, in vitro carotid ring produc- tionoftumornecrosisfactor(TNF)-(cid:2)inresponse toarangeofendotoxindoseswaselevatedinSHR versusWKYrats.11 Weinferredfromthesestudies thatstrokeriskfactorsactedtoaugmentbloodves- selactivationwithinthecerebrovascularcirculatory network. RosenbergandAirdconductedstudiesofthedif- ferencesinthemolecularmechanismsthatprovide Figure 1. Responsestosingle1.8mg/kgintracisternaldoses ofendotoxinarecomparedfromgroupsofratswithandwith- the primary regulation of hemostasis in vascular outstrokeriskfactors.Foreachgroup,nisSprague-Dawleyrats bedsofdifferentorgansandalsonotedthatavari- (SD)37,SDdiabetic(SDDIB)26,SD24-monthsold(SD2Y)13, etyofdifferentsystemiccoagulationdisorderssuch spontaneouslyhypertensiverats(SHR)26,stroke-pronespon- asproteinCdeficiency,heparin-bindingsiteofan- taneouslyhypertensiverats(SHR-SP)4,SHRretiredbreeder tithrombin III mutation, factor V Leiden variant, rats(SHR-RB)4,andWistarrats(W)7. andprothrombinG20210Amutationleadtoorgan- specificthrombosisratherthanadiffusethrombotic dollar.8 Our group wondered whether established diathesis with disseminated intravascular coagula- risk factors for stroke could act locally to prepare tion. They concluded that hemostatic potential is blood vessels in the brain for a modified Shwartz- not regulated by a synchronous, systemic mech- man reaction in response to a provocative inflam- anism but is instead controlled asynchronously matory stimulus such as intracisternally or intra- segmentbysegmentwithinthevasculartreeofan venouslyinjectedendotoxin.Strokeriskfactorssuch organ.12–14Thelocalendotheliumofavascularseg- as hypertension, diabetes, advanced age, and ge- ment was viewed as integrating signals that come neticpredispositiontostrokewerefoundsufficient fromtheblood,thebloodvesselwall,andthesur- to prepare rat brainstem tissues such that a single roundingparenchymaltissue;inresponsetothison- intracisternalorintravenousinjectionofendotoxin goingendothelialintegrationofsignalsthatinclude provokedthereaction,andaffectedrats-manifested cytokines, mechanical forces, circulating lipopro- neurologic deficits accompanied by pathologic le- teins,coagulationfactors,componentsoftheextra- sions (Fig. 1). Brain infarcts developed in only a cellular matrix, and DAMPs, the properties of the small proportion of rats without recognized risk luminal endothelium within a given segment can factors after endotoxin injection.9 This work sug- cyclefromanantiinflammatoryandanticoagulant gestedthatoneroleofstrokeriskfactorsistoprime phenotypeatoneextremetoaproinflammatoryand vesselactivationandendothelialdysfunctionasoc- procoagulantphenotypeattheotherextreme.Such cursintheShwartzmanreaction,butthatasecond cycling occurs innocuously in normal individuals, systemic activation of inflammation and coagula- butifthehemostaticpotentialinavascularsegment tion was necessary to precipitate local thrombosis risesabovesomehomeostaticthresholdascanoccur orhemorrhageandcauseastroke,namely,a“two- in the presence of stroke risk factors, local throm- hitphenomenon.” bosisorvesseldamagewithhemorrhagebecomesa Weexaminedthispossibilityfurtherwithaseries threat. ofstudiesthatcomparedthenumbersofperivascu- Our studies of the patterns of immunoreactive larmacrophagesinbrainvesselsandtheendotoxin- TNF-(cid:2) (proinflammatory, prothrombotic), heme induced levels of secreted proinflammatory cy- oxygenase-1 (HO-1, oxidative stress marker), and tokinesfromisolatedcarotidringsamonganimals manganesesuperoxidedismutase(MnSOD,antiox- withriskfactorsforstrokeandthosewithoutsuch idant) around the brain vessels of rats with and risk factors. The numbers of perivascular ED2- withoutriskfactorsforstrokeprovidesomesupport 2 Ann.N.Y.Acad.Sci.1207(2010)1–7(cid:2)c 2010NewYorkAcademyofSciences. Hallenbeck CNSvesselactivationfocus—personalperspective phenotype and express tissue factor, IL-1, TNF-(cid:2), coagulationfactorbinding/activation,adhesionre- ceptors,plasminogenactivatorinhibitor-1,platelet activatingfactor,endothelin,chemokines,andvon Willebrandfactor.17 Onecouldeasilydichotomizethemolecularpro- cesses that regulate the phenotype of the luminal endotheliumintoasubsetthatispotentiallyharm- ful, the procoagulant and proinflammatory medi- ators, and a subset that is potentially salutary, the anticoagulantandanti-inflammatorymediators.It turnsoutnottobethatsimple.18Forinstance,TNF- Figure2. Patternsofmanganesesuperoxidedismutase(Mn- (cid:2) would seem to be an archetypal “bad guy” that SOD) expression around brain vessels of spontaneously hy- induces both inflammation and cytotoxicity. This pertensive stroke-prone rats. These patterns were coincident with the expression patterns of immunoreactive TNF-(cid:2) and cytokine, however, can be harmful19–22 or bene- hemoxygenase-1inserialsections.Theconcentricringsofim- ficial23,24 or act as a preconditioning stimulus to munoractiveMnSODappeartoexpandradiallyfromscattered induce stress tolerance25–28 depending on the cir- vessel epicenters out into the brain parenchyma in a non- cumstances. Indeed, an examination of TNF-(cid:2) synchronousmanner.Theconcentriccirclessuggestthatthese function within the conventional “ischemic cas- responsesoccurinwavesofactivationanddeactivationofindi- cade” can provide a semi-quantitative insight into vidualvascularsegments. the complexity and multifactorality of the regula- tory network in cells. A widely accepted series of for the dynamic segmental control model of generalpathobiologicalmechanismsthataresetinto hemostasis described above.15 Within brain sec- motionbybrainischemiawouldincludemetabolic tions from rats without stroke risk factors, cross- failure,membranefailure,excitotoxicity,apoptosis, sectionedvesselsexhibitedscatteredcoincidentvas- oxidative/nitrativestress,pathologicalgeneexpres- cular and perivascular halos of immunoreactive sion, neurovascular unit dysfunction, and inflam- TNF-(cid:2),HO-1,andMnSODthatappearedtoperi- matory/immune responses.29 Cytokines constitute odicallybeginasthinringsoutliningandhighlight- onlyonesubsetoftheinflammatory/immuneme- ing a vessel then expanding centrifugally into the diators and there are over 100 of these signaling surroundingparenchymabeforefading.Repeating molecules. Drilling down further, one of these cy- cyclesoftheexpandingimmunoreactivityofthese tokines is TNF-(cid:2), which reacts with two different regulatorymoleculeswereclearlyvesselcentricand receptors.Astudymappingtheproteininteraction werelikelytohavebeenresponsestocyclicactiva- networkthatlinksTNF-(cid:2)receptoractivationwith tionandinactivationofdiscretevascularsegments activationofonlyoneofitstranscriptionfactortar- because the number and intensity of the perivas- gets, nuclear factor (cid:3)B (NF(cid:3)B), showed that there cular rings was significantly increased in rats with are221protein–proteininteractionsthatmodulate stroke risk factors and in risk factor-free rats that NF(cid:3)B activation.30 Once activated, NF(cid:3)B can in- receivedintravenousendotoxin(Fig.2). fluence the expression of more than 150 genes.31 Mediatorsoftheanticoagulant/antiinflammatory Bygoingthroughthementalexerciseofscalingthis phenotype of the luminal endothelium in a vas- levelofcomplexitybackthroughotherrecognized cular segment can include prostacyclin, nitric strokepathobiologicalmechanisms,onecangaina oxide, heparin-like glycosaminoglycans, throm- greaterappreciationoftheextraordinarycomplex- bomodulin, protein C, protein S, tissue-type ityandmultifactoralityofthedynamicnetworkthat plasminogen activator, tissue factor pathway in- controlsthecellularresponsesrelatedtoischemia. hibitor, hemoxygenase-1, MnSOD, and adeno- In the mid-1990s, Kyra Becker, an outstand- sinediphosphatase/5(cid:3)-nucleotidase.16Inresponseto ing postdoctoral fellow with a strong interest proinflammatorymediatorslikeTNF-(cid:2),interleukin in immunology, joined our group. She decided (IL)-1, and lipopolysaccharide (LPS), luminal en- to address the stroke cytoprotection problem by dothelium can make a “Jekyll to Hyde” change in augmenting endogenous immune regulatory Ann.N.Y.Acad.Sci.1207(2010)1–7(cid:2)c 2010NewYorkAcademyofSciences. 3 CNSvesselactivationfocus—personalperspective Hallenbeck ensemblesthatfunctionbroadlywithinthedynamic E-selectin polypeptide that included much of the network rather than by identifying and targeting extramembranousportionthatleukocytereceptor. asingleinflammatoryorimmunemechanismthat E-selectinexpressionisvirtuallyconfinedtoluminal wouldhavearelativelycircumscribednetworkfunc- endotheliumanditisnotconstitutivelyexpressed. tion. Specifically, she proposed to apply to studies Itisonlyexpressedinvesselsegmentsthatarebe- of brain ischemia the mucosal tolerance model32 coming activated. We were struck (a) because lo- that was known to modulate immune responses calreleaseofimmuneandinflammatorymediators and had shown efficacy in experimental autoim- contributestolocalvesselactivation,appropriately muneencephalitismodels.Inthemucosaltolerance targeted local immunomodulation could counter model,serialtransmucosaladministration of“low thatactivationand(b)becauseT-lymphocytesare dose”antigeninthemicrogramrangewilleitheren- key players in the regulation of the immune sys- countergut-associatedlymphoidtissueifdelivered tem, induction of mucosal tolerance to E-selectin orallyorwillencounternasal-associatedlymphoid could potentially serve to target regulatory T cells tissue if instilled intranasally. CD4+ lymphocytes to activating blood vessel segments, provide local canbeprimedbyantigenpresentingcells(APCs)to immunomodulation,andreducetheriskofstroke differentiateintoregulatoryTcellsthatwilltraffic inindividualswithstrokeriskfactors. through the body and secrete IL-10 (Tr1 cells) or Our initial study was in spontaneously hyper- TGF(cid:4) (Th3 cells) when the antigen to which they tensive, stroke-prone rats (SHRSP/Izm) that had have been primed is again presented to them by been kindly supplied by Y. Yamori from the Dis- APCs. If the priming antigen can be presented ei- ease Model Cooperative Research Association to therlocallyorwithindraininglymphnodes(from MariaSpatzinconsiderationofhermanyyearsas whichtheregulatoryTcellscanreturntothelocusof a mentor for Japanese visiting fellows at the NIH. inflammation),theseregulatoryTcellscanrelease After initial dose–response studies we instilled in immunomodulatorycytokinesandlocallysuppress thenonboostergroup,5mgofrecombinanthuman inflammationandimmuneresponsesregardlessof E-selectin(rhES)intranasallyonaneveryotherday whether or not the presented antigen is actually scheduleforfivedosesandthenfollowedtheanimals causing the inflammation. This process is termed untiltheydevelopedstrokes,othercomplicationsof “bystander suppression.” A brain antigen, myelin severe hypertension such as heart failure or renal basicprotein(MBP)wasfedbygavagetorats,and failure,oruntilcompletionofthe56-weekstudy.We theanimalsweresubsequentlyprotectedfromtran- alsogaverepeatedfive-doseschedulesofE-selectin sient middle cerebral artery occlusion-induced is- intranasally at 21-day intervals to a booster group chemicbraindamagecomparedtoratsfedanonspe- of animals and followed them as described above. cific,nonmammalianprotein,ovalbumin.Inaddi- Control animals received single or booster sched- tion,MBPsensitizationinanotheranimalgroupled ules of intranasal instillation of either phosphate toincreasedischemicbraindamage.Furtherstud- bufferedsaline(PBS)oranonmammalianprotein, iesthatincludeddemonstrationofantigen-specific ovalbumin,andalsohadcorrespondingfollow-ups. suppression of delayed-type hypersensitivity vali- Incomparisontotheothergroups,theanimalsthat dated the presence of an antigen-specific state of receivedboosterinstillationsofrhESshowedamas- immune tolerance.33 This work showed that en- sivelyreducedincidenceofischemicstrokeandthe dogenous immunomodulation mechanisms could absenceofparenchymalhemorrhages34(Fig.3). be harnessed to change immune network dynam- On the basis of this study, we began to further ics in acute stroke in order to suppress brain cell develop intranasal instillation of E-selectin for the damage. secondarypreventionofstroke.Wereasonedthatif A limiting factor in the application of this ap- a stroke-preventive agent that is already on board proachtoacutestroketreatmentisthattheinduc- had some cytoprotective capacity, it would confer tionofmucosaltolerancebyserialexposureofanti- added value because the earlier a therapeutic can gens to a mucosal surface such as the gut or the be administered aftera stroke, thehigher the like- nasalmucosatakesseveraldaystodevelop.Webe- lihood of a beneficial response. We therefore per- came aware in the late 1990s that Protein Design formedpermanentmiddlecerebralarteryocclusion Laboratories had produced a recombinant human (MCAO) studies in SHR-SP rats and found that 4 Ann.N.Y.Acad.Sci.1207(2010)1–7(cid:2)c 2010NewYorkAcademyofSciences. Hallenbeck CNSvesselactivationfocus—personalperspective Figure 3. Comparisonsareshownoftheaveragenumberofbraininfarctsperanimal(A),theaverageareaofbraininfarcts per animal (B), the average number of brain intraparenchymal hemorrhages per animal (C), and the average area of brain intraparenchymalhemorrhagesperanimal(D)ineachof4experimentalgroups.Theexperimentalgroupsreceivedeitherasingle scheduleoffiveeveryotherday5(cid:3)gdosesofintranasallyinstilledovalbumenorE-selectin,ortheyreceivedboosterrepetitionof thesedosagescheduleseverythreeweekstomaintainanymucosaltolerancethathadbeeninduced. E-selectintolerizationstronglyreducedinfarctvol- Inourcurrentworkonthisproject,wearecar- umescomparedtoPBScontrols.35 Inaddition,we rying out the necessary bridging studies to show replicatedthisfindingbyadoptivetransferofspleen equivalencebetweenhomologousratormurineE- cells from E-selectin tolerized donor animals into selectin antigen in rodents and heterologous hu- naive SHR-SP showing that E-selectin tolerization manE-selectininrodents.Wearealsoconducting isacell-mediatedphenomenon. safetyanddosestudiesthatexaminebothintended We have also shown the efficacy of mucosal to- biological/immunomodulatory responses and po- lerization to E-selectin in reducing white matter tentialtoxicity/immunotoxicityconsequencesofex- damageandfunctional/behavioraldeficitsinmod- tended periods of E-selectin nasal instillation. An elsofvascularcognitiveimpairment,36inaugment- additional goal is to validate techniques that can ingadultneurogenesisandimprovingfunctionalre- be applied in our future clinical trials to provide covery after stroke,37 in suppressing subarachnoid accessiblebiomarkersoffunctionalactivityandim- hemorrhage-delayedvasospasm,38 and(inunpub- munotoxicity. This workwillleadinto nonhuman lished work) in improving neurological outcome primatestudiesthatposethatthefinalhurdlebefore in an experimental autoimmune encephalomyeli- filinganINDandconductingaPhaseIclinicaltrial. tis model of multiple sclerosis, and in reducing of We hope to immunomodulate the intricately aorticplaqueburdeninamodelofatherosclerosis interconnected ensembles of molecular mecha- inapolipoproteinE(ApoE)-nullmice.Thesestud- nisms in the dynamic network that function in a ieshaveinvolveddifferentsetsofinvestigatorsand stroke-prone individual and can lead to a stroke. havebeenconductedinseveraldifferentlabs. We have chosen an approach that has relatively Ann.N.Y.Acad.Sci.1207(2010)1–7(cid:2)c 2010NewYorkAcademyofSciences. 5 CNSvesselactivationfocus—personalperspective Hallenbeck plurifunctional effects in the network and is con- 12. Aird,W.C.2005.Spatialandtemporaldynamicsoftheen- sonant with a prescient quote from Oscar Ratnoff dothelium.J.Thromb.Haemost.3:1392–1406. (who identified Factor XII Hageman factor) that 13. Edelberg,J.M.,P.D.Christie&R.D.Rosenberg.2001.Regu- lationofvascularbed-specificprothromboticpotential.Circ. influencedmegreatlyearlyinmycareer.Inacom- Res.89:117–124. prehensive review that integrated hemostasis, fib- 14. Rosenberg,R.D.&W.C.Aird.1999.Vascular-bed-specific rinolysis, immunity, and inflammation,39 he con- hemostasisandhypercoagulablestates.N.Engl.J.Med.340: cludedhisarticlewiththeinsightthatinvestigators 1555–1564. interestedinanygivensystem(e.g.,complementor 15. 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Ann.N.Y.Acad.Sci.1207(2010)1–7(cid:2)c 2010NewYorkAcademyofSciences. 7 Ann.N.Y.Acad.Sci.ISSN0077-8923 ANNALS OF THE NEW YORK ACADEMY OF SCIENCES Issue:InnateInflammationandStroke Innate inflammation as the common pathway of risk factors leading to TIAs and stroke GregoryJ.delZoppo1,2 andPhilipB.Gorelick3 1DivisionofHematology,DepartmentofMedicine,and2DepartmentofNeurology,UniversityofWashingtonSchoolof Medicine,Seattle,Washington.3DepartmentofNeurologyandRehabilitation,UniversityofIllinoisCollegeofMedicineat Chicago,Chicago,Illinois Addressforcorrespondence:Prof.GregoryJ.delZoppo,DivisionofHematology,DepartmentofMedicine,Universityof WashingtonSchoolofMedicine,Box359756atHarborviewMedicalCenter,325NinthAvenue,Seattle,WA98104. [email protected] Intheearlymomentsofischemicstroke,theprocessesofthrombosis,ischemia,andinflammationareintimately interrelated,settinginmotionaninjurythatleadstoinfarctionandpermanentdamage.Ofthese,thepotentialroles thatinnateinflammationcanplayintheevolutionofbraintissuedamageinresponsetotheischemicinjuryarenot wellunderstood.Observationsinthesettingsofatheroscleroticcardiovasculardiseaseandcerebralischemiahave muchtoteacheachother.Thefollowingprovidesanintroductoryoverviewoftheconference“InnateInflammation astheCommonPathwayofRiskFactorsLeadingtoTransientIschemicAttacksandStroke:Pathophysiologyand Potential Interventions,” which took place May 9–10, 2010 at the New York Academy of Sciences. This meeting wasconvenedtoexploreaspectsofthecellularandtissueresponsestoinnateinflammation.Afacultyofleading expertswasassembledtodiscusstheroleofinflammationinlaboratorymodelsofstrokeandmyocardialinfarction, definepossiblenovelmeansfromlaboratoryevidencetoalleviateorpreventinflammationunderlyingstrokeand cardiovasculardisease,andpresentinformationoncurrentexamplesofclinicaltranslationoftheseunderstandings inrelationtohumanstrokeandmyocardialinfarction. Keywords: neurovascularunit;innateinflammation;infection;stroke;cognitiveimpairment/Alzheimer’sdisease Occlusion of a brain-supplying artery initiates a clear.Toexplaintheobservationthatprotectionof complextime-dependentseriesofeventsthatevolve neurons alone, demonstrated experimentally, has intopermanentstructuralinjuryintheterritoryat- been inadequate to lead to functional benefit in riskandleadtotheclinicalsignsofischemicstroke. clinicalstroke,aconceptualshifthasoccurred.The Bothexperimentalandclinicaltrialworksofthelast “neurovascularunit”isaconceptualframeworkthat 30 years have shown that recanalization of an oc- linksmicrovesselandneuronfunction,andtheirre- cludedarterywithinhoursoftheonsetofischemia sponsestoinjury.Italsorepresentsastructuralar- can limit the volume of permanent injury, de- rangementthatlinksmicrovesselcomponentswith pendinguponthelocationofthevascularterritory neuronsviatheircommonastrocytes.1,2Itassumes involved.Theevolutionofischemicinjurytotheul- thatthefunctionofthe“unit”canbemodifiedor timateinfarctioninvolvestheactivationofinflam- regulated by other cells associated with the unit. matory processes. Injury to the microvasculature Componentsoftheneurovascularunitincludethe without overt clinically detectable focal ischemia endothelium,astrocytesandtheirend-feet,theex- canproducemoresubtlebraininjurythatalsoin- tracellular matrix between these cell components, volvesinflammatorypathways.Hence,thrombosis, pericytes, neurons and axons, and other cells that ischemia,andinflammationareinterrelatedincen- can modulate the function, including microglia, tralnervoussystem(CNS)injury. oligodendroglia,mastcells,andperhapsothercells Theimportanceofmicrovesselintegrityfornor- fromothersources.2,3 malbrainfunctionandforlimitingthefunctional Each of these cell types can respond with a disturbances of neurons during ischemia is now repertoire of signals, receptors, and cell function doi:10.1111/j.1749-6632.2010.05762.x 8 Ann.N.Y.Acad.Sci.1207(2010)8–10(cid:2)c 2010NewYorkAcademyofSciences.

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