BioMed Research International Cerebral Vasospasm after Aneurysmal Subarachnoid Hemorrhage: Mechanism and Therapies Guest Editors: Chih-Lung Lin, Aaron S. Dumont, John H. Zhang, Mario Zuccarello, and Carl Muroi Cerebral Vasospasm after Aneurysmal Subarachnoid Hemorrhage: Mechanism and Therapies BioMed Research International Cerebral Vasospasm after Aneurysmal Subarachnoid Hemorrhage: Mechanism and Therapies Guest Editors: Chih-Lung Lin, Aaron S. Dumont, John H. Zhang, Mario Zuccarello, and Carl Muroi Copyright©2014HindawiPublishingCorporation.Allrightsreserved. Thisisaspecialissuepublishedin“BioMedResearchInternational.”AllarticlesareopenaccessarticlesdistributedundertheCreative CommonsAttributionLicense,whichpermitsunrestricteduse,distribution,andreproductioninanymedium,providedtheoriginal workisproperlycited. Contents CerebralVasospasmafterAneurysmalSubarachnoidHemorrhage:MechanismandTherapies, Chih-LungLin,AaronS.Dumont,JohnH.Zhang,MarioZuccarello,andCarlMuroi Volume2014,ArticleID679014,3pages UpregulationofRelaxinafterExperimentalSubarachnoidHemorrhageinRabbits,YuichiroKikkawa, SatoshiMatsuo,RyotaKurogi,AkiraNakamizo,MasahiroMizoguchi,andTomioSasaki Volume2014,ArticleID836397,9pages PatientOutcomesfollowingSubarachnoidHemorrhagebetweentheMedicalCenterandRegional Hospital:WhetherAllPatientsShouldBeTransferredtoMedicalCenters,Tsung-YingLin, ChiehHsinWu,Wei-CheLee,Chao-WenChen,Liang-ChiKuo,Shiuh-LinHuang,Hsing-LinLin, andChih-LungLin Volume2014,ArticleID927803,5pages TheRoleofMicroclotFormationinanAcuteSubarachnoidHemorrhageModelintheRabbit, LukasAndereggen,VolkerNeuschmelting,MichaelvonGunten,HansRudolfWidmer,JavierFandino, andSergeMarbacher Volume2014,ArticleID161702,10pages TheHarmfulEffectsofSubarachnoidHemorrhageonExtracerebralOrgans,ShengChen,QianLi, HaijianWu,PaulR.Krafft,ZhenWang,andJohnH.Zhang Volume2014,ArticleID858496,12pages Inflammation,Vasospasm,andBrainInjuryafterSubarachnoidHemorrhage,BrandonA.Miller, NefizeTuran,MonicaChau,andGustavoPradilla Volume2014,ArticleID384342,16pages AlterationofBasilarArteryRho-KinaseandSolubleGuanylylCyclaseProteinExpressioninaRat ModelofCerebralVasospasmfollowingSubarachnoidHemorrhage,Chih-JenWang,Pei-YuLee, Bin-NanWu,Shu-ChuanWu,Joon-KhimLoh,Hung-PeiTsai,Chia-LiChung,NealF.Kassell, andAij-LieKwan Volume2014,ArticleID531508,8pages ToLookBeyondVasospasminAneurysmalSubarachnoidHaemorrhage,GiuliaCossu, MahmoudMesserer,MauroOddo,andRoyThomasDaniel Volume2014,ArticleID628597,14pages ProgesteroneAttenuatesExperimentalSubarachnoidHemorrhage-InducedVasospasmby UpregulationofEndothelialNitricOxideSynthaseviaAktSignalingPathway,Chia-MaoChang, Yu-FengSu,Chih-ZenChang,Chia-LiChung,Yee-JeanTsai,Joon-KhimLoh,andChih-LungLin Volume2014,ArticleID207616,6pages TheRoleofArteriolesandtheMicrocirculationintheDevelopmentofVasospasmafterAneurysmal SAH,MasatoNaraoka,NaoyaMatsuda,NorihitoShimamura,KenichiroAsano,andHirokiOhkuma Volume2014,ArticleID253746,9pages ProphylacticIntra-ArterialInjectionofVasodilatorforAsymptomaticVasospasmConvertsthePatient toSymptomaticVasospasmduetoSevereMicrocirculatoryImbalance,NorihitoShimamura, MasatoNaraoka,NaoyaMatsuda,KiyohideKakuta,andHirokiOhkuma Volume2014,ArticleID382484,7pages ImpactofClippingversusCoilingonPostoperativeHemodynamicsandPulmonaryEdemaafter SubarachnoidHemorrhage,NobutakaHorie,MitsutoshiIwaasa,EijiIsotani,ShunsukeIshizaka, TooruInoue,andIzumiNagata Volume2014,ArticleID807064,9pages MagnesiumLithospermateB,anActiveExtractofSalviamiltiorrhiza,MediatessGC/cGMP/PKG TranslocationinExperimentalVasospasm,Chih-ZenChang,Shu-ChuanWu,andAij-LieKwan Volume2014,ArticleID272101,9pages Incidence,NationalTrend,andOutcomeofNontraumaticSubarachnoidHaemorrhageinTaiwan: InitialLowerMortality,PoorLong-TermOutcome,Hsing-LinLin,Kwan-MingSoo,Chao-WenChen, Yen-KoLin,Tsung-YingLin,Liang-ChiKuo,Wei-CheLee,andShiuh-LinHuang Volume2014,ArticleID274572,5pages CerebralVasospasminPatientsover80YearsTreatedbyCoilEmbolizationforRupturedCerebral Aneurysms,TomohitoHishikawa,YujiTakasugi,TomohisaShimizu,JunHaruma,MasafumiHiramatsu, KojiTokunaga,KenjiSugiu,andIsaoDate Volume2014,ArticleID253867,5pages TherapeuticImplicationsofEstrogenforCerebralVasospasmandDelayedCerebralIschemiaInduced byAneurysmalSubarachnoidHemorrhage,DaleDing,RobertM.Starke,AaronS.Dumont, GaryK.Owens,DavidM.Hasan,NohraChalouhi,RickyMedel,andChih-LungLin Volume2014,ArticleID727428,9pages DescriptionoftheVasospasmPhenomenafollowingPerimesencephalicNonaneurysmalSubarachnoid Hemorrhage,DaphnaPrat,OdedGoren,BelaBruk,MatiBakon,MosheHadani,andSagiHarnof Volume2013,ArticleID371063,8pages Hindawi Publishing Corporation BioMed Research International Volume 2014, Article ID 679014, 3 pages http://dx.doi.org/10.1155/2014/679014 Editorial Cerebral Vasospasm after Aneurysmal Subarachnoid Hemorrhage: Mechanism and Therapies Chih-LungLin,1,2AaronS.Dumont,3JohnH.Zhang,4MarioZuccarello,5andCarlMuroi6,7 1DepartmentofNeurosurgery,KaohsiungMedicalUniversityHospital,Kaohsiung807,Taiwan 2FacultyofMedicine,GraduateInstituteofMedicine,CollegeofMedicine,KaohsiungMedicalUniversity,Kaohsiung807,Taiwan 3DepartmentofNeurosurgery,TulaneUniversity,NewOrleans,LA70112,USA 4DepartmentsofNeurosurgery,Physiology,andAnesthesiology,LomaLindaUniversitySchoolofMedicine,LomaLinda,CA92354, USA 5DepartmentofNeurosurgery,UniversityofCincinnati,Cincinnati,OH45219,USA 6NeurocriticalCareUnit,DepartmentofNeurosurgery,UniversityHospitalZurich,Frauenklinikstrasse10,8091Zurich,Switzerland 7DepartmentofNeurosurgery,KantonsspitalAarau,Tellstrasse,5001Aarau,Switzerland CorrespondenceshouldbeaddressedtoChih-LungLin;[email protected] Received13August2014;Accepted13August2014;Published8September2014 Copyright©2014Chih-LungLinetal.ThisisanopenaccessarticledistributedundertheCreativeCommonsAttributionLicense, whichpermitsunrestricteduse,distribution,andreproductioninanymedium,providedtheoriginalworkisproperlycited. Although cerebral vasospasm (CV) after aneurysmal sub- is presented in up to 70% of SAH patients, only 20–30% of arachnoidhemorrhage(SAH)hasbeenrecognizedformore allSAHpatientssufferfromclinicallysymptomaticCV[3]. thanhalfacentury,itspathophysiologicmechanismremains Nonetheless, it is now evident that CV alone is inadequate elusive [1]. Delayed CV has classically been considered as tocompletelyexplainDCIfollowinganeurismalrupture[2, the leading and treatable cause of mortality and morbidity 4]. Recent studies on the treatment of CV have failed to in patients following aneurysmal SAH. Despite intensive solidly support the correlation between angiogram-shown research efforts, SAH-induced CV remains incompletely improvement in CV and prognosis. Besides, various drugs understood from both the pathogenic and the therapeu- proveneffectiveforbetterfunctionaloutcomeshavedemon- tic perspectives. Many pathological processes have been strated their independency of CV reduction. Currently, a proposed to explain the pathogenesis of delayed CV after multifactorial etiology for DCI has emerged, whereas the SAH,includingendothelialdamage,smoothmusclecontrac- role of CV has shifted from the major and most significant tion,changinginvascularresponsiveness,andinflammatory determinant to one contributing factor, just like any other and/or immunological response of the vascular wall [2]. At factors, to the process. The study of the pathophysiology present, the most important and critical aspects of SAH- of DCI has become more broad-minded with several other induced CV are its failure to consistently respond to treat- differentmechanismsbeingactivelyinvestigated. ment and only partial success could be achieved in both The term “early brain injury” (EBI) was first postulated experimentalmodelsandclinicaltrials. in 2004, more than 40 years after delayed CV was first For patients with SAH surviving the early phase, sec- described, to explain the acute pathophysiological events ondaryischemia(ordelayedcerebralischemia,DCI)ispop- occurringwithin72hoursofSAH[5,6].Theseeventsinclude ularlyconsideredastheleadingdeterminantofpoorclinical cerebral autoregulation and blood-brain barrier disruption, outcome.AmongstthecomplicationsafterSAH,CVhasbeen activationofinflammatorypathways,excitotoxicity,oxidative regarded as the major cause of DCI. However, there have stress,andactivationofapoptosis[7].Thesearedirecteffects beenanincreasingnumberofevidencessupportingmultiple ofbloodclotinthesubarachnoidspaceandalsooftransient etiologiesofDCIotherthanCV.AlthoughradiographicCV cerebral ischemia, leading to brain injury not confined to 2 BioMedResearchInternational Subarachnoid hemorrhage 0hours Excitotoxicity Cerebral autoregulation disruption Blood-brain barrier Early brain injury Oxidative stress activation disruption of apoptosis Activation of Activation of apoptosis inflammatory pathways 72hours Activation of proapoptotic pathways Arteriolar constriction Disruption of the Delayed cerebral ischemia Thrombosis and dysfunction blood-brain barrier in microcirculation Cerebral vasospasm Cortical spreading ischemia Endothelial damage Smooth muscle contraction Change in vascular responsiveness Inflammatory and/or immunological Figure1:Themechanismsofearlybraininjuryanddelayedcerebralischemiafollowingsubarachnoidhemorrhage. thesiteofhemorrhage.ManymechanismsofEBIcontribute extracerebral organs damage and long-term complications tothepathogenesisofDCIandarehenceaccountableforthe after aneurysmal and nonaneurysmal SAH are also pre- poor outcomes. Causes of DCI have been attributed to the sented. Medical resources utilization in patients following combined effects of delayed CV, activation of proapoptotic SAH between the medical center and regional hospital is pathways, disruption of the blood-brain barrier, arteriolar reportedonanationwidepopulation-basedstudy. constriction, thrombosis and dysfunction in microcircula- DCI, a result of different pathological pathways, is a tion, and cortical spreading ischemia, all brought about by complexprocessandhasshownitsimportanceastheleading EBI[2]. determinantofpoorfunctionaloutcomeinpatientssurviving Accumulating data have suggested that apoptosis is a the initial hemorrhagic insult of SAH. The possible mecha- key mediator of secondary brain injury after SAH [8]. nismsofEBIandDCIafterSAH,aswellastheirrelationship Approximately, 50% of SAH survivors remain permanently withCV,areillustratedinFigure1.TheimportanceofCVin disabledbecauseofcognitivedysfunctionanddonotreturn DCIhaslongbeenoveremphasized.CVisnotthesoleornec- to their previousfunctions[9]. CV alone could not explain essaryprocessleadingtoDCI.Treatmentstrategiestargeting the whole subtle changes in behavior and memory. In this at CV prevention alone are not adequate. Considering CV aspect,apoptosisinducedbyglobalischemiashouldbetaken as the only monitor of therapeutic effectiveness or the lone intoconsideration. prognosticmarkercanbemisleading.Strategiesfocusingon Inthisspecialissue,anupdatereviewofthemechanism the detection and treatment of EBI as an alleviation of the and treatment of CV and DCI after aneurysmal SAH is occurrenceofDCItosubsequentlyimproveoveralloutcome presented.Therolesofmechanismsincludingmicroclotfor- couldmakepromisingfuturestudyblueprints. mation,downregulationofendothelialnitricoxidesynthase, Chih-LungLin and upregulation of relaxin are discussed. Treatment with AaronS.Dumont progesterone, which attenuates experimental SAH-induced JohnH.Zhang CV by upregulationofendothelialnitricoxide synthasevia CarlMuroi Akt signaling pathway, is investigated. Besides, a study on MarioZuccarello MagnesiumLithospermateB,anactiveextractofsalviamil- tiorrhizamediatingsGC/cGMP/PKGtranslocationtoreduce References CV, is reported. Furthermore, new strategies using 17𝛽- estradiol, targeting at several CV-preventing mechanisms, [1] D.A.Cook,“Mechanismsofcerebralvasospasminsubarach- have brought light to the reduction of CV and secondary noidhaemorrhage,”PharmacologyandTherapeutics,vol.66,no. braininjuryafterSAH.Thetreatmentandoutcomeincluding 2,pp.259–284,1995. BioMedResearchInternational 3 [2] R.L.Macdonald,“Pathophysiologyandmoleculargeneticsof vasospasm,”ActaNeurochirurgica,vol.77,supplement,pp.7–11, 2001. [3] N. W. C. Dorsch, “Cerebral arterial spasm: a clinical review,” BritishJournalofNeurosurgery,vol.9,no.3,pp.403–412,1995. [4] E. Tani, “Molecular mechanisms involved in development of cerebralvasospasm.,”NeurosurgicalFocus,vol.12,no.3,pp.1–4, 2002. [5] J.B.Bederson,A.L.Levy,W.H.Dingetal.,“Acutevasoconstric- tionaftersubarachnoidhemorrhage,”Neurosurgery,vol.42,no. 2,pp.352–362,1998. [6] G. Kusaka, M. Ishikawa, A. Nanda, D. N. Granger, and J. H. Zhang, “Signaling pathways for early brain injury after subarachnoidhemorrhage,”JournalofCerebralBloodFlowand Metabolism,vol.24,no.8,pp.916–925,2004. [7] F.A.Sehba,R.M.Pluta,andJ.H.Zhang,“Metamorphosisof subarachnoidhemorrhageresearch:fromdelayedvasospasmto earlybraininjury,”MolecularNeurobiology,vol.43,no.1,pp.27– 40,2011. [8] W. J. Cahill, J. H. Calvert, and J. H. Zhang, “Mechanisms of earlybraininjuryaftersubarachnoidhemorrhage,”Journalof CerebralBloodFlowandMetabolism,vol.26,no.11,pp.1341– 1353,2006. [9] K. M. Buchanan, L. J. Elias, and G. B. Goplen, “Differing perspectivesonoutcomeaftersubarachnoidhemorrhage:the patient,therelative,theneurosurgeon,”Neurosurgery,vol.46, no.4,pp.831–840,2000. Hindawi Publishing Corporation BioMed Research International Volume 2014, Article ID 836397, 9 pages http://dx.doi.org/10.1155/2014/836397 Research Article Upregulation of Relaxin after Experimental Subarachnoid Hemorrhage in Rabbits YuichiroKikkawa,SatoshiMatsuo,RyotaKurogi,AkiraNakamizo, MasahiroMizoguchi,andTomioSasaki DepartmentofNeurosurgery,GraduateSchoolofMedicalSciences,KyushuUniversity,3-1-1Maidashi, Higashi-ku,Fukuoka,Fukuoka812-8582,Japan CorrespondenceshouldbeaddressedtoYuichiroKikkawa;[email protected] Received9March2014;Accepted24June2014;Published16July2014 AcademicEditor:Chih-LungLin Copyright©2014YuichiroKikkawaetal. This is an open access article distributed under the Creative Commons Attribution License,whichpermitsunrestricteduse,distribution,andreproductioninanymedium,providedtheoriginalworkisproperly cited. Background. Although relaxin causes vasodilatation in systemic arteries, little is known about its role in cerebral arteries. We investigated the expression and role of relaxin in basilar arteries after subarachnoid hemorrhage (SAH) in rabbits. Methods. MicroarrayanalysiswithrabbitbasilararteryRNAwasperformed.MessengerRNAexpressionofrelaxin-1andrelaxin/insulin- likefamilypeptidereceptor1(RXFP1)wasinvestigatedwithquantitativeRT-PCR.RXFP1expressioninthebasilararterywas investigatedwithimmunohistochemistry.Relaxinconcentrationsincerebrospinalfluid(CSF)andserumwereinvestigatedwith anenzyme-linkedimmunosorbentassay.Usinghumanbrainvascularsmoothmusclecells(HBVSMC)preincubatedwithrelaxin, myosinlightchainphosphorylation(MLC)wasinvestigatedwithimmunoblottingafterendothelin-1stimulation.Results.After SAH,RXFP1mRNAandproteinweresignificantlydownregulatedonday3,whereasrelaxin-1mRNAwassignificantlyupregulated onday7.TherelaxinconcentrationinCSFwassignificantlyelevatedondays5and7.Pretreatmentwithrelaxinreducedsustained MLCphosphorylationinducedbyendothelin-1inHBVSMC.Conclusion.UpregulationofrelaxinanddownregulationofRXFP1 afterSAHmayparticipateindevelopmentofcerebralvasospasm.DownregulationofRXFP1mayinduceafunctionaldecreasein relaxinactivityduringvasospasm.Understandingtheroleofrelaxinmayprovidefurtherinsightintothemechanismsofcerebral vasospasm. 1.Introduction the mechanism of vasospasm and find new therapeutic targets. Cerebralvasospasmisoneofthemostimportantcerebrovas- Relaxin is a small peptide hormone (6kDa) that is culareventsfollowingsubarachnoidhemorrhage(SAH)and primarily produced by the corpus luteum, decidua, and is characterized by delayed and prolonged contraction of placentaduringpregnancy[3].Threerelaxingeneshavebeen cerebral arteries that may cause cerebral ischemia and lead identifiedinhumansandaredesignatedasrelaxin-1(RLN1), to death or neurological deficits in patients with SAH [1]. relaxin-2 (RLN2), and relaxin-3 (RLN3). Human relaxin-2 Therefore,thepreventionaswellastreatmentofvasospasm is the only form of circulating relaxin that is substantially isimportantinthemanagementofSAHpatients.Although increased during pregnancy [4]. Human relaxin-2 is func- increasedproductionofspasmogensandincreasedvascular tionally equivalent to relaxin-1 in all other mammals [5]. responsiveness can be attributed to cerebral vasospasm, Recently, RLN mRNA expression has also been detected the mechanism of cerebral vasospasm remains elusive, and innonreproductivetissuesincludingarteries,heart,kidney, thuseffectivetherapeuticstrategiesarenotavailable.Recent liver,andlung[6–8]. randomizedclinicaltrialshaveshownthatcurrentlyavailable Fourrelaxinreceptorgeneshavebeenidentified.Theyare antivasospasticdrugsarenotsufficienttoimproveoutcome relaxin/insulin-likefamilypeptidereceptorsandarenamed [2]. Therefore, further research efforts are needed to clarify RXFP1 (RXFP1), RXFP2 (RXFP2), RXFP3 (RXFP3), and