do model polymer therapeutics sufficiently diffuse through …gala.gre.ac.uk/id/eprint/17632/7/17632...
TRANSCRIPT
1
Domodelpolymertherapeuticssufficientlydiffusethrougharticularcartilagetobeaviable
therapeuticroute?
AlisonPowell1,BruceCaterson1,ClareHughes1,AlisonPaul2,CraigJames2,StephenHopkins2,
OmarMansour3andPeterGriffiths3
1SchoolofBiosciences,CardiffUniversity,TheSirMartinEvansBuilding,
MuseumAvenue,Cardiff,CF103AX
2SchoolofChemistry,CardiffUniversity,MainBuilding,ParkPlace,CF103TB
3DepartmentofPharmaceutical,ChemicalandEnvironmentalSciences,FacultyofEngineering
andScience,UniversityofGreenwich,MedwayCampus,CentralAvenue,ChathamMaritime,
KentME44TB
2
Abstract
Theabilityofapolymertherapeutictoaccesstheappropriatesubcellularlocationiscrucialto
itsefficacy,andisdefinedtoalargepartbythemanyandcomplexcellularbiologicaland
biochemicalbarrierssuchaconstructmusttraverse.Itisshownherethatmodeldextrin
conjugatesareabletopassthroughacartilaginousextracellularmatrixintochondrocytes,with
littleperturbationofthematrixstructure,indicatingthattargetingofpotentialtherapeutics
throughacartilaginousextracellularmatrixshouldprovepossible.Rapidchondrocytictargeting
ofdrugswhichrequireintracellularisationfortheiractivity,anduniformextracellular
concentrationsofdrugswithanextracellulartarget,isthusenabledthoughpolymer
conjugation.
3
Introduction
Articularcartilagelinestheloadbearingjointsofthebodyactingtoreducefrictionandabsorb
mechanicalloads.Itisananeural,avascular,hypocellulartissue,composedofadense
extracellularmatrixcontrolledandsecretedbythechondrocyteswithinit.Thechondrocytes
compriselessthan2%ofthevolumeofmaturearticularcartilagewiththeremainder
comprisingahighlyorganisednetworkofcollagenfibrils,proteoglycansandwater.Thematrix
macromoleculesofarticularcartilagegivethetissueitsuniquestructureandfunction.These
structuralmacromoleculesincludecollagens(mainlytypeII),proteoglycansandnon-
collagenousproteins.ThetypeIIcollagenfibrilmeshworkgivesthecartilageitsformand
tensilestrength.Theproteoglycansandnon-collagenousproteinsofarticularcartilagebindto
thecollagenmeshworkorbecomemechanicallyentrappedwithinit.Themajorproteoglycanof
articularcartilageisaggrecan,whichhasnumerousglycosaminoglycanchainsattachedtoits
coreproteinandformshugemultimolecularaggregateswithhyaluronanandalinkprotein.
Hydrationoftheglycosaminoglycanchainsofaggrecanprovidescartilagewithits
compressibilityfunctions.
MorethantenmillionpeopleintheUKhavelong-termhealthproblemsduetoarthritisora
relatedcondition1.Themostcommonarthriticdiseasesareosteoarthritisandrheumatoid
arthritis,bothofwhichinvolveerosionofthecartilagecushioningtheendsofboneswithinthe
joint.Symptomsincludejoint-painandstiffness,whichcanleadtodisability.Cartilage
degenerationinarthritisisdueultimatelytotheenzymaticdegradationofthecartilage
extracellularmatrix.Thecomplexityanddensityofthecartilageextracellularmatrixresultsina
barriertothepassageofmoleculesthroughthematrix,howeveritsmaintenanceiscrucialfor
tissuefunction.Inthesynovialjointthearticularsurfaceislubricatedandnourishedbysynovial
fluid,afiltrateofbloodplasmacontaininghighlevelsoftheglycosaminoglycanhyaluronanand
theproteoglycanlubricin(SZP)2.Therelativeviscosityofsynovialfluidprovidesanadditional
barriertodiffusionofmoleculesintochondrocytes.
1. Arthritisandwork(03.2017)http://www.arthritisresearchuk.org/policy-and-public-affairs/reports-and-
resources/reports/work-report.aspx
2. Rhee,D.K.,Marcelino,J.,Baker,M,Gong,Y.,Smits,P.,Lefebvre,V.,Jay,G.D.,Stewart,M.,Wang,H.,Warman,M.L.andCarpten,J.D.(2005)Thesecretedglycoproteinlubricinprotectscartilagesurfacesandinhibitssynovialcellovergrowth.TheJournalofClinicalInvestigation.115:622-631
4
Currenttherapiesforarthritismainlytreattheclinicaldiseasesymptomsratherthantargeting
thedegradativeenzymesthemselves.Treatmentssuchassteroidalandnon-steroidalanti-
inflammatorydrugsarestillthemainstayoftreatment3,4andcanhaveadversesideeffects
includinghighbloodpressure5,6,7,osteoporosis8,cataracts9,10andgastrointestinalbleeding11.
Thenewlyreleasedanti-TNFdrugs(Etanercept,InfliximabandAdalimumab)whichblockthe
pro-inflammatorycytokineTNFinrheumatoidandpsoriaticarthritis12,13areefficaciousforonly
asmallcohortofpatientsandareonlyprescribedforUKpatientswithsevereandcrippling
formsofthediseaseastheycarrytheriskofserioussideeffectsduetoimmuno-suppression14.
Inrecentyears,anumberofcompoundshavebeenidentified,ininvitrostudies,thatareable
toinhibittheinitiallossoftheextracellularmatrixcomponentaggrecan,viaoftenunknown
mechanisticinhibitionoftheproteasesADAMTS-4and/or-5.Thesecompoundshavenotably
3. Marini,S.,Fasciglione,G.F.,Monteleone,G.,Maiotti,M.,Tarantino,U.&Coletta,M.(2003)Acorrelation
betweenkneecartilagedegradationobservedbyarthroscopyandsynovialproteinasesactivities.ClinicalBiochemistry36:295-304;
4. Brandt,K.D.&Slowman-Kovacs,S.(1986)Nonsteroidalanti-inflammatorydrugsintreatmentofosteoarthritis.ClinicalOrthopaedics213:84-91
5. Gabriel,S.E.&Wagner,J.L.(1997)Costsandeffectivenessofnonsteroidalanti-inflammatorydrugs.Theimportanceofreducingsideeffects.ArthritisCareResearch10:56-63
6 Hammer,F.&Stewart,P.M.(2006)Cortisolmetabolisminhypertension.BestPracticeandResearchClinicalEndocrinologyandMetabolism20:337-353
7 Reiche,M.L.(2005)Complicationsofintravitrealsteroidinjections.ClinicalCare76:450-460
8 Ledford,D.,Apter,A.,Brenner,A.M.,Rubin,K.,Frieri,M.&Lukert,B.(1998)Osteoporosisinthecorticosteroidtreatedpatientwithasthma.JournalofAllergyandClinicalImmunology102:353-363
9 Moore,P.(1997)Inhaledcorticosteroidsincreasecataractrisk.TheLancet350:120
10 UrbanR.C.&Cotlier,E.(1986)Corticosteroid-inducedcataracts.SurveyofOphthalmology31:102-110
11 Tringham,V.M.&Cochrane,P.(1979)Aspirin,paracetamol,diflunisalandgastrointestinalbloodloss.TheLancet320:1409
12 Punzi,L.,Podswiadek,M.,Sfriso,P.,Oliviero,F.,Fiocco,U.&Todesco,S.(2007)PathogenicandclinicalrationaleforTNF-blockingtherapyinpsoriaticarthritis.AutoimmunityReviews6(8):524-528
13 Berthelot,J-M.,Varin,S.,Cormier,G.,Tortellier,L.,Guillot,P.,Glemarec,J.&Maugars,Y.(2007)25mgetanerceptonceweeklyinrheumatoidarthritisandspondylarthropathy.JointBoneSpine74(2):144-147
14 Maillard,H.,Ornetti,P.,Grimault,L.,Ramon,J-F.,Ducamp,S.M.,Saidani,T.,Tavernier,C.&Maillefert,J.F.(2005)Severepyogenicinfectionsinpatientstakinginfliximab.Aregionalcohortstudy.JointBoneSpine72:330-334
5
includedtheneutraceuticalglucosamine15,16,17andthesulphatedsugarderivativepentosan
polysulphate18,19.Inaddition,thephysiologicalinhibitorofADAMTS-4and-5,TIMP-3,hasbeen
showntoablatetheinitiallossofaggrecanincytokineinduceddegradativemechanisms20.
Theideathatwater-solublepolymersfunctioningascarriersofdrugsthroughconjugationviaa
biodegradablespacer/linkercouldfacilitatetargeteddrugreleasewasfirstputforwardinthe
mid-1970’s21.Thelasttwodecadeshaveseensuccessfulclinicalapplicationofpolymer
conjugatestotargettherapeuticagentsforthetreatmentofarangeofdiseasesincludingage
relatedmaculardegeneration,cancerandliverdisease22,23,24,25.Thesetherapeuticconjugates
haveutilisedanumberofpolymersasdrugdeliveryvehiclesincludingN-(2-hydroxypropyl)
15 Largo,R.,Alvarez-Soria,M.A.,Diez-Ortego,I.&Calvo,E.(2003)GlucosamineinhibitsIL-1b-inducedNFkB
activationinhumanosteoarthriticchondrocytes.OsteoarthritisandCartilage11:290-298
16 Maillard,H.,Ornetti,P.,Grimault,L.,Ramon,J-F.,Ducamp,S.M.,Saidani,T.,Tavernier,C.&Maillefert,J.F.(2005)Severepyogenicinfectionsinpatientstakinginfliximab.Aregionalcohortstudy.JointBoneSpine72:330-334
17 Ilic,M.Z.,Martinac,B.&Handley,C.J.(2003)Effectsoflong-termexposuretoglucosamineandmannosamineonaggrecandegradationinarticulatcartilage.OsteoarthritisandCartilage11:1-10
18 Smith,J.G.,Hannon,R.L.,Brunnberg,L.,Gebski,V.&Cullis-Hill,D.(2002)Amulticentreclinicalstudyoftheefficacyofsodiumpentosanpolysulphateandcarprofenincanineosteoarthritis(osteoarthrosis).
19 Rogachefsky,R.A.,Dean,D.D.,Howell,D.S.&Altman,R.D.(1994)Treatmentofcanineosteoarthritiswithsodiumpentosanpolysulphateandinsulin-likegrowthfactor-1.AnnaloftheNewYorkAcademyofSciences732:392-394
20 Gendron,C.,Kashiwagi,M.,Hughes,C.E.,Caterson,B.&Nagase,H.(2003)TIMP-3inhibitsaggrecanases-mediatedglycosaminoglycanreleasefromcartilageexplantsstimulatedbycatabolicfactors.FEBSLetters555:431-436
21 Vasey,P.A.,Kaye,S.B.,Morrison,R.,Twelves,C.,Wilson,P.,Duncan,R.,Thomson,A.H.,Murray,L.S.,Hilditch,T.E.,Murray,T.,Burtles,S.,Fraier,D.,Frigerio,E.&Cassidy,J.(1999)PhaseIClinicalandPharmacokineticstudyofPK1[N-(2-Hydroxypropyl)methacrylamideCopolymerDoxorubicin]:Firstmemberofanewclassofchemotherapeuticagents-drug-polymerconjugates.ClinicalCancerResearch5:83-94
22 Duncan,R.(2005)Targetingandintracellulardeliveryofdrugs.InEncyclopediaofMolecularCellBiologyandMolecularMedicine,EditorMeyers,R.A.,PublishedbyWiley-VCH,Verlag,GmbH&Co.KGaA,Weinheim,Germany,pp163-204
23 Duncan,R.(2006)Polymerconjugatesasanticancernanomedicines.NatureReviewsCancer6:688-701
24 Duncan,R.,Ringsdorf,H.&Satchi-Fainaro,R.(2006)Polymertherapeutics–PolymersasDrugs,ConjugatesandGeneDeliverySystems:Past,presentandfutureopportunities.AdvancedPolymerScience192:1-8
25 Yasukawa,T.,Ogura,Y.,Sakurai,E.,Tabata,Y.&Kimura,H.(2005)Intraocularsustaineddrugdeliveryusingimplantablepolymericdevices.AdvancedDrugDeliveryReviews57:2033-2046
6
methacrylamide(HPMA)26,27,poly(ethyleneglycol)(PEG)28,29,30anddextrin31,32.Conjugationof
drugstopolymershasallowedforspecifictargetingofthetherapeuticactivityofadrugtothe
diseasedtissue.Thisresultsinareductioninthedoserequiredforefficacyoftreatmentanda
reductioninpotentialtoxicityofthedrugs.
Expandingthismodalitytothetreatmentofarthriticjoints,requiresthatsuchpolymersin
ordertodelivertheirdrugpayloadmustbeabletopassthroughacartilaginousextracellular
matrixrichinnegativelychargedproteoglycans,eithertoreachtheirchondrocytictargets,orto
achieveevendistributionthroughoutthecartilageextracellularmatrix.Intheselectionof
suitabletargetingpolymersandpolymerconjugatesforthetreatmentofarthriticdisease,
quantifyingwhetherthesecompoundscanindeedpassthroughthebarrierspresentedbythe
synovialjointwithoutinducingtheirdisruptionwillbeofvitalimportance.Ofthepotential
barrierspresentwebelievethattheinteractionsofpolymersandpolymerconjugateswith
proteoglycans,withinthecartilageextracellularmatrixaswellascoatingitssurface,willbethe
mostinfluentialontheirmovement.Thisstudyfocusedoninvestigatingtheinteractionsof
polymersandpolymerconjugateswiththecartilageproteoglycansaggrecanandlubricinas
wellassynovialfluid.
26 Duncan,R.,Vicent,M.J.,Greco,F.&Nicholson,R.I.(2005)Polymer-drugconjugates:towardsanovel
approachforthetreatmentofendocrine-relatedcancer.Endocrine-RelatedCancer12:189-199
27 Nan,A.,Nanayakkara,N.P.D.,Walker,L.A.,Yardley,V.,Croft,S.L.&Ghandehari,H.(2001)N-(2-hydroxypropyl)methacrylamide(HPMA)copolymersfortargeteddeliveryof8-aminoquinolineantileishmanialdrugs.JournalofControlledRelease77:233-243
28 Ould-Ouali,L.,Noppe,M.,Langlois,X.,Willems,B.,Riele,P.T.,Timmerman,P.,Brewster,M.E.,Arien,A.&Preat,V.(2005)Self-assemblingPEG-r(CL-co-TMC)copolymersfororaldeliveryofpoorlywatersolubledrugs:acasestudywithrisperidone.JournalofControlledRelease102:657-668
29 Cheng,J.,Teply,B.A.,Sherifi,I.,Sung,J.,Luther,G.,Gu,F.X.,Levy-Nissenbaum,E.,Radovic-Moreno,A.F.,Langer,R.&Farokhzad,O.C.(2007)FormulationoffunctionalisedPLGA-PEGnanoparticlesforinvivotargeteddrugdelivery.Biomaterials28:869-876
30 Yu,D.,Peng,P.,Dharap,S.S.,Wang,Y.,Mehlig,M.,Chandna,P.,Zhao,H.,Filpula,D.,Yang,K.,Borowski,V.,Borchard,G.,Zhang,Z.&Minko,T.(2005)Antitumoractivityofpoly(ethyleneglycol)-camptothecinconjugate:Theinhibitionoftumorgrowthinvivo.JournalofControlledRelease110:90-102
31 Hreczuk-Hirst,D.,Chicco,D.,German,L.&Duncan,R.(2001)Dextrinsaspotentialcarriersfordrugtargeting:tailoredratesofdextrindegradationbyintroductionofpendantgroup.InternationalJournalofPharmaceutics230:57-66
32 Hreczuk-Hirst,D.,German,L.&Duncan,R.(2001)Dextrinsascarriersfordrugtargeting:Reproduciblesuccinoylationasameanstointroducependantgroups.JournalofBioactiveandCompatiblePolymers16:353-364
7
Materials&Methods
Preparationofsynovialfluidsamples
Synovialfluidsampleswereharvestedfromthemetacarpo/metatarsophalangealjointsof18
montholdcowslegsusinga15gaugeneedle.
Preparationoflubricin
Followingeffusionofthesynovialfluidfromthejointsof18montholdcowslegsasdescribed
abovethejointswerelavagedusing1.6Msodiumchloridetoisolatethelubricincoatingthe
surfaceofthearticularcartilage33.
Preparationofaggrecanaggregates
Bovinearticularcartilageexplantswereestablishedusingpreviousmethodologies34.Following
a48hourprecultureexplantswerewashedintoserumfreeDMEM.Theexplantswerethen
culturedineither(i)serumfreeDMEMor(ii)serumfreeDMEM+IL-1a(10ng/ml).Cultures
wereincubatedforupto96hours;mediaandexplantswereharvestedandfinelydicedpriorto
additionofguanidineextractionbuffer(4MguanidineHCl,50mMsodiumacetatepH5.8-6.8,
0.1M6-amino-hexanoicacid,5mMbenzamidineHCl,10mMethylenediaminetetraaceticacid
(EDTA)(tetrasodiumsalt),1mMphenylmethylsulphonylfluoride(PMSF-10mlpergram
cartilagewetweight)andincubatedfor48hoursat4oCwithconstantagitation.Theextracted
cartilagedebriswasremovedbycentrifugationat15,000rpmfor10minutes,anddiscarded.
TheliquidsupernatantwasthendialysedexhaustivelyagainstMilliQ™water.Thedensityofthe
extractwasadjustedto1.5g/mlbyadditionofCaCl2andaggrecan-hyaluronanaggregate
purifiedbyultracentrifugationinaBeckmanL-60Ultracentrifugeat37,000rpmfor70hoursat
4oC.Theextractwasfractionatedinto4equalpoolsdesignatedA1-A4,thelowestfractionA1
containingthepurifiedaggrecan-hyaluronancomplexandhavingadensity>1.57g/ml.
33 Jones,A.R.C.,Gleghorn,J.P.,Hughes,C.E.,Fitz,L.J.,Zollner,R.,Wainwright,S.D.,Caterson,B.,Morris,E.A.,
Bonassar,L.J.andFlannery,C.R.(2007)Bindingandlocalizationofrecombinantlubricintoarticularcartilagesurfaces.JournalofOrthopaedicResearch25(3):283-92.
34 Hughes,C.E.,Caterson,B.,Fosang,A.J.,Roughley,P.J.andMort,J.S.(1995)Monoclonalantibodiesthatspecificallyrecogniseneoepitopesequencesgeneratedbyaggrecanasesandmatrixmetalloproteinasecleavageofaggrecan:applicationtocatabolisminsituandinvitro.TheBiochemicalJournal305:799-804
8
AnalysisofcellularuptakeofpolymerconjugatesbyFACSandfluorescencemicroscopy
Explantswereharvestedandpre-culturedusingpreviouslyestablishedmethodsError!Reference
sourcenotfound.priortoincubationinthepresenceorabsenceofIL-1a(10ng/ml)for96hours35.
CultureswerethenincubatedinDMEMwith50µg/mlgentamicinand10%(v/v)heat
inactivatedFBSinthepresenceorabsenceofOregonGreenlabelledpolymersatarangeof
concentrations(1-10µg/ml)foranumberoftimepoints(2-24hours).Followingincubationwith
polymersexplantswereeitherwashedinphosphatebufferedsalineandviewedusinga
confocalmicroscope,ordigestedtofreethecellsusingPronase(1%{w/v}inDMEMcontaining
50µg/mlgentamicinand10%{v/v}heatinactivatedFBS)for30minutesat37oC,followedby
collagenasetypeII(0.4%{w/v}inDMEMcontaining50µg/mlgentamicinand10%{v/v}heat
inactivatedFBS)for45minutesat37oC.Theisolatedcellswillbepelletedbycentrifugation
resuspendedinPBSandrunonaFACsCanto(BDBiosciences).
Pulsed-GradientSpin-EchoNuclearMagneticResonance
Measurementsonthepurifiedfreeze-driedaggrecan-hyaluronancomplexredispersedinD2O
wereconductedonaBrukerAMX360NMRspectrometerusingastimulatedecho-sequence36.
Thisconfigurationusedeithera5mm(CryomagnetSystems,Indianapolis)or10mm(Bruker)
diffusionprobeinconjunctionwithBrukerorWoodwardgradientspectroscopyaccessories.
Theself-diffusioncoefficientDswasextractedbyfittingtoequation1either(i)theintegralsfor
agivenpeak,or(ii)theindividualfrequencychannelspresentintheentirebandshape(CORE
analysis);
(1)
35 Arner,E.C.,Hughes,C.E.,Decicco,C.P.,Caterson,B.andTortorella,M.D(1998)Cytokineinducedcartilage
proteoglycandegradationismediatedbyaggrecanases.OsteoarthritisandCartilage.6:214-228
36 Davies,J.A.andGriffiths,P.C.(2003)APhenomenologicalApproachtoSeparatingtheEffectsofObstructionandBindingfortheDiffusionofSmallMoleculesinPolymerSolutions.Macromolecules:36,950
( ) [ ]so kDAGA −=Δ exp,,δ
9
whereAisthesignalamplitudeintheabsence(Ao)andpresenceofthefieldgradientpulses
( )Δ,,GA δ )and( ) ( )
⎟⎟
⎠
⎞
⎜⎜
⎝
⎛ +++−+Δ−=
301435301030 232232
22 σσδσδδσδγ Gk
giventhatgisthemagnetogyricratio,Dthediffusiontime,σthegradientramptime,dthe
gradientpulselengthandGthegradientfieldstrength.
Small-angleneutronscattering
SANSexperimentswereperformedontheLOQdiffractometerbasedatthespallationsourceat
theRutherfordAppletonLaboratory,U.K.,whereaQrangeof0.007Å-1to0.3Å-1isaccessible
using2<l<10Å,whereQ=(4π/λ)sin(θ/2)Q = #$%sin )
*.
Sampleswerecontainedin1mmpathlength,UV-spectrophotometergrade,quartzcuvettes
(Hellma)andmountedinaluminiumholdersontopofanenclosed,computer-controlled,
samplechamber.Temperaturecontrolwasachievedthroughtheuseofathermostatted
circulatingbathpumpingfluidthroughthebaseofthesamplechamber.Undertheseconditions
atemperaturestabilityofbetterthan±0.5°Ccanbeachieved.Experimentalmeasuringtimes
wereapproximately40-60min.
Allscatteringdatawerenormalisedforthesampletransmissionandtheincidentwavelength
distribution,correctedforinstrumentalandsamplebackgroundsusingaquartzcellfilledwith
eitherH2OorD2O(thisalsoremovestheincoherentinstrumentalbackgroundarisingfrom
vacuumwindows,etc.),andcorrectedforthelinearityandefficiencyofthedetectorresponse
usingtheinstrumentspecificsoftwarepackage.Thedatawereputontoanabsolutescaleusing
awell-characterizedpartiallydeuteratedpolystyreneblendstandardsample.
Theintensityofthescatteredradiation,I(Q),asafunctionofthewavevector,isgivenby:
𝐼 𝑄 = 𝑁𝑉* 𝛥𝜌 *𝑃 𝑄 𝑆 𝑄 +𝐵678 (2)
10
whereP(Q)describesthemorphologyofthescatteringspecies,S(Q)describesthespatial
arrangementofthespeciesinsolution,Nisthenumberofspeciesperunitvolume,Visthe
volumeofthespecies,Δρisthedifferenceintheneutronscatteringlengthdensity(SLD)ofthe
scattererandthesolventandBincistheincoherentbackgroundscattering.
11
ResultsandDiscussion
PGSE-NMRprovidesaconvenientandnon-invasivechemicallyselectivetechniquefor
measuringtranslationalmotion,andinparticulartheself-,ratherthanmutual-diffusion
coefficient.Therefore,PGSE-NMRcanbeusedbothtoquantifythemobilityofmoleculesand
toassesstheimpactofthepresenceofthemoleculesontheextracellularmatrixcomponents
themselves.Thediffusionofsmallsolutes(includingwaterandNa+)hasbeenshowntobe
impededbyupto40%bythepresenceofanextracellularmatrix,implyingthatthemovement
oflargermoleculessuchaspolymersmaybeverysignificantlyaffectedbythepresenceofa
matrix37.
Avitalcomponentintheselectionofpolymer-drugconjugatesforthetreatmentofarthritic
diseaseistheselectionofeitherpolymersabletotargetadrugwithintracellularactivityandits
abilitytodiffuserapidlythroughtheextracellularmatrixintothechondrocyte.Accordingly,the
rateofdiffusionofdextrinpolymers(asmodelconjugates)hasbeenquantifiedbothinfree
solutionandthroughcomponentsofthecartilaginousextracellularmatrix(anaggrecan-
hyaluronanaggregategelpurifiedbydensitygradientcentrifugationfrombovinearticular
cartilage),TableOne.FortheMw=10kg/mol-1dextrinsample,theself-diffusioncoefficientwas
slowedfromDs=2.7x10-10m2s-1infreesolution,correspondingtoahydrodynamicradiusofa
fewnanometres,toDs=2.6x10-11m2s-1intheaggrecan-hyaluronangel,(Table1).Thehigher
molecularweightdextrinshowsalargerreduction,thoughthefreesolutionretardationis
consistentwiththeincreaseinmolecularweightofarandomcoilconfiguration.Bydrawing
analogiesofthediffusionofsuchpolymerinrelated(mucin)gels,thissignificantretardationis
probablynotaconsequenceofdirectassociationofthedextrinwiththeaggrecan-hyaluronan
aggregate,butrathersterichindranceduetothepresenceofthehighlyentangledmatrixofthe
aggrecan-hyaluronanaggregate38.Thenon-linearityoftheattenuationfunctionclearly
demonstratesthepresenceofmorethanasinglediffusionrateandtheCOREanalysisidentifies
37 Burstein,D.,Gray,M.L.,Hartman,A.L.,Gipe,R.andFoy,B.D.(1993)Diffusionofsmallsolutesincartilage
asmeasuredbynuclearmagneticresonance(NMR)spectroscopyandimaging.JournalofOrthopaedicResearch.11:465-478
38 Griffiths,P.C.,Occhipinti,P.,Gumbleton,M.,Morris,C.J.,Heenan,R.K.andKing,S.M.(2010)PGSE-NMRandSANSStudiesoftheInteractionofModelPolymerTherapeuticswithMucinBiomacromolecules.11:120-125
12
thesetobedextrin(theinitialdecay)andtheunderlyingmuchslower(twoordersofmagnitude
slower)diffusionoftheaggrecan-hyaluronanaggregates.
Asanaside,wecanalsocommentontheeffectofsuccinoylation–thefirststepindextrin
functionalisation–ontheconformationofthepolymer,ascharacterisedbytheirself-diffusion
coefficients,figure2.Theself-diffusioncoefficientdropssmoothly(increasinghydrodynamic
size)withincreasingmolepercentofsuccinoylation,uptoavalueofaround~10mol%,above
whichtheself-diffusioncoefficientbecomeslargelyconstantat~1x10-10m2s-1,consistentwith
anhydrodynamicradiusofaround50Å.
The(gel)structureofcartilageextract,andvariousderivativematerialshavebeenexaminedby
small-angleneutronscattering(SANS)intheabsenceandpresenceofaddeddextrin,figures
3a&b(representativedataonlypresented).Inthecaseofthe18mdirectcartilageextract,
wherethescatteringfromthegelitselfissignificant(I(Q)>10cm-1atQ<0.01Å)and
dominatesthemixturescattering(fordextrin,I(Q)<0.5cm-1atQ<0.01Å),additionofthetwo
dextrinsamplesinducednonoticeableperturbationinthescattering-andhence,structureof
thedirectcartilageextractgel.InthecaseoftheIL-1systems,andvariousotherderivative
materials(datanotpresented),figure3b,thesameconclusionmaybedrawn,butnotso
directly.Itisobviousthatthescatteringdoesvaryacrossthedifferentmixedsystems,butitis
shownbelowthatthisisaconsequenceoftheweakerandcomparableintensitiesofthe
variouscomponentsratherthanonedominatingcontribution,asinthecaseofthe18mdirect
cartilageextract.
AnumberofstrategiesexistforinterpretingSANSdata.Thesimplestistoconsidertheslopeof
thedatawhenplottedonadoublelogarithmicrepresentation,extractingtheso-calledQ
dependency,I(Q) µQ-n,illustratingthemostprobableshapeofthescatterer;n=1indicatesa
rod,n=2aflatstructure,increasingallthewayton=4foralarge,solidobject.Forsystems
likegels,onemightanticipaten=5/3tothen=3,reflectingatransitionfromamasstovolume
fractalcharacterassociatedwiththedifferinglength-scalespresentinthegel.Thisisindeedthe
case.
Alternatively,onemaynumericallyanalysethedataintermsofspecificmodels,basedonsome
aprioriknowledgeofthelikelyconformationorarrangementofmoleculesinsolution.For
13
dextrin,asimplepolydisperseGaussiancoilmodeladequatelydescribesthedataforMw=51K
g/mol-1dextrinsample,withRG=80Å(consistentwiththetheoreticalpredictionfortheratioof
theradiusofgyrationandhydrodynamicradius,RG/RH=1.5).
Forthegels,anappropriatetreatmentistheShibayama-Geisslertwo-lengthscalemodel39,40
whichtreatsthescatteringastheadditionaloftwocomponents,withfractionf;
𝐼 𝑄 = 𝑓𝐼(0)==
=> ?@AB CDEAD
?/D + 1 − 𝑓 𝐼 0 *𝑒𝑥𝑝 −𝑄*𝑎** + 𝐵 (3)
whereDisthescalingexponentand𝑎** ≈NOD
P.TheparametersdescribingtheShibayama-
GeisslerfittothesedataarepresentedinTableTwo.Byandlarge,thefittingismostsensitive
totheLorentziancomponentembodiedinthescalingexponentD,withalengthscale(𝑎=*)of
around100Å,butthe18mdirectcartilageextractalsorequiresaGuinierterm,withlength
scaleslightlyshorter.Mostimportantly,asisevidentfromtherawdatawheresubtle
differencesareonlyobservedathigherQvalues,theparametersarelargelyinsensitivetothe
additionofthedextrini.e.itmaybeconsideredtobenon-perturbing.
Havingshownitispossiblefordextrintodiffusethroughthegelwhilsthavinglittleimpacton
itsstructure,theprogressionof(OregonGreenfluorophorelabelled)dextrinintochondrocytes
wasassessed.Eachofthecultureswasincubatedindextrin-OregonGreenat1,5and10µg/ml
for2-24hours.Cellswerereleasedfrommonolayerculturesbygentletrypsinisationandby
rapidpronaseandcollagenasedigestfromexplantandexvivotranswellgraftscultures.FACS
analysisofthesecellpopulationswith10µg/mldextrin-OregonGreenat2,4,8and24hours
areshowninFigure4.
Cellularuptakeofthedextrinconjugateachievedinthepresenceofacartilaginousextracellular
matrixinbothexplantculturesandinexvivotranswellgrafts(Figure4B&A,respectively).In
cartilageexplantscellularuptakewasachievedinover90%ofcellsfollowing8hoursexposure
(Figure4B).Uptakeofdextrin-OregonGreenwasslowerinexvivotranswellgraftsthanin
39 Shibayama,M.,Toyoichi,T.,andHan,C.C.(1992)Smallangleneutronscatteringstudyonpoly(N-
isopropylacrylamide)gelsneartheirvolume-phasetransitiontemperature.J.Chem.Phys.97(9),6829-6841
40 Mallam,S.,Horkay,F.,Hecht,A.M.,Rennie,A.R.andGeissler,E.,(1991)Microscopicandmacroscopicthermodynamicobservationsinswollenpoly(dimethylsiloxane)networks.Macromolecules24,543
14
explantscultureswithonly66%ofcellscontainingthefluorophorefollowing24hoursexposure
(Figure4A).Intheexvivotranswellgraftsthedextrin-OregonGreenwasonlyaddedtothe
insertmediumtomimicthesituationinvivowhereatherapeuticagentinjectedintothejoint
wouldonlybeabletopenetratethecartilageatthearticularsurface(Figure5).Thisrestricted
accesstoonesurfaceexplainstheapparentlyslowerrateofuptakebychondrocyteswithinthe
exvivotranswellgraftscomparedtochondrocyteswithincartilageexplants(Figures4A&B).
Inordertodeterminewhetherdextrin-OregonGreenwasabletopassrightthrougha
cartilaginousextracellularmatrixitwasonlyaddedtotheinsertmediumoftheexvivo
transwellgraftsandboththeinsertandoutermediumwereanalysedforitspresenceusing
fluorescencespectroscopyfollowinganumberofdifferentincubationtimes(Figure6).
Thedextrin-OregonGreenwasabletopassrightthroughtheextracellularmatrixoftheexvivo
transwellgraftsandwasdetectedintheoutermediumoftheculturesfollowingonly2hoursof
incubationwiththeconjugate(Figure6).Following24hoursincubationonthefilterinsert
culturesover13%ofthetotalfluorescencepresentinthecultureswasdetectedintheouter
medium(Figure6).
15
Conclusions
Combined,thedatapresentedheredemonstratethatdextrinisabletosuccessfullydiffuse
throughacartilaginousextracellularmatrixandintothechondrocyteswithin,inducinglittle
perturbationinthatmatrix,thusindicatingthefeasibilityofdrugdeliveryusingpolymer
conjugatesforthetreatmentofarthritis.
Acknowledgements
EPSRCarethankedfortheprovisionofanEPSRCPlatformGrant(EP/C013220/1)
”Bioresponsivepolymertherapeutics;synthesisandcharacterisationofnovelnanomedicines”,
STFCforaccesstoSANSfacilitiesandbothCardiffUniversityandUniversityofGreenwichfor
financialsupport.
16
Tables
Sample Freesolution Aggrecan-hyaluronan Ratio
Mw=10Kg/mol-1 2.7x10-10m2s-1 2.6x10-11m2s-1 10
Mw=51Kg/mol-1 1.0x10-10m2s-1 5.0x10-12m2s-1 20
Table1;Self-diffusioncoefficientsinfreesolution(concentration1wt%)andaggrecan-
hyaluronangelsmeasuredbyPGSE-NMR,andtheretardationratiofromfreesolutiontogel.
SampleGuinier
scale
Lorentzian
scale
Radiusof
gyration/
Å
Fractal
dimension
Correlation
length/Å
18m 0.2 18 85(+/-3) 2.2(+/-0.1) 235(+/-30)
18mplusdextrin
10Kgmol-1n/a 18 n/a 2.3 140
18mplusdextrin
51Kgmol-1n/a 14 n/a 2.3 135
IL-1 n/a 0.2 n/a 2.2 105
IL-1plusdextrin
51Kgmol-10.3 1.1 55 2.2 90
Table2:ParametersderivedfromananalysisofthescatteringdataintermsoftheShibayama-
Geisslertwo-lengthscalemodel.
17
18
Figures
Figure1.Experimentaltwo-dimensionalPGSENMRdataset(left)andanalysisofpeakintegrals
usedtoextracttheratesofdiffusion(right)forMw=10kg/mol-1dextrininfreesolutionandin
anaggrecan-hyluronangel,theopensymbolscorrespondtotheattenuationfunctionforthe
peakat~3ppminthespectrumfrom10mg/ml(1wt%)dextrininsolutioni.e.therawdata
presentedabove.Thefilledsymbolscorrespondtotwosuperimposeddatasets,necessaryto
spanthewidedynamicsrangepresentinthesesystems,againforthe3ppmpeak,arisingfrom
thespectrumof10mg/ml(1wt%)dextrininanaggrecan-hyaluronangel(20mg/mlGAG).
k /cm-2s
0.0 5.0e+61.0e+71.5e+72.0e+72.5e+73.0e+73.5e+7
Normalised signal
0.1
1
Ds = 2.7 x 10-10 m2s-1
Ds = 2.6 x 10-11 m2s-1
Ds = 3.0 x 10-12 m2s-1
0 5e+5 1e+6 2e+6 2e+6
0.1
1
19
degree of succinoylation / mol%
0 10 20 30
self-
diffu
sion
coe
ffici
ent /
m2 s-1
1e-10
2e-10
3e-10
4e-10
5e-10
6e-10
7e-10
FigureTwo;Self-diffusioncoefficientsinfreesolutionasafunctionofdegreeofsuccinoylation
measuredbyPGSE-NMRfordextrinMw=51Kg/mol-1at1wt%polymer.
20
Wavevector, Q / ≈ -1
0.01 0.1
Inte
nsity
I(Q
) / c
m-1
0.01
0.1
1
1018m cartilage extract18m cartilage extract and dextrin 10K g mol-1
18m cartilage extract and dextrin 51K g mol-1
dextrin 51K g mol-1
Figure3a.Small-angleneutronscatteringfrom1mmthick(H2O)aqueoussolutionsofdirect
cartilageextractfrom18montholdkneejointsintheabsenceofdextrin,andinthepresenceof
1wt%dextrin,Mw=10kg/mol-1andMw=51kg/mol-1.Thelinesofbestfithavebeenderived
fromtheanalysisusingtheBeaucagemodelasdescribedinthetext.Alsoshownforcomparison
isthescatteringfrom1wt%Mw=51kg/mol-1dextrin(inD2O).Thelinesofbestfitforthis
dextrinsamplehasbeenderivedfromasimpleGaussiancoilmodel,RG=80(±3)Å.
21
Wavevector, Q / ≈ -1
0.01 0.1
Inte
nsity
I(Q
) / c
m-1
0.01
0.1
1IL-1IL-1 and dextrin 51K g mol-1
dextrin 51K g mol-1
Figure3b.Small-angleneutronscatteringfrom2mmthick(D2O)reconstitutedaqueous
solutionsofIL-1intheabsenceofdextrinandinthepresenceof1wt%dextrinMw=51kg/mol-1.
Thelinesofbestfithavebeenderivedfromtheanalysisusingthegelpluscoilmodelas
describedinthetext.Alsoshownforcomparisonisthescatteringfromthedextrinsolution.
22
A.TranswellFilterGraftsB.CartilageExplants
Figure4;FACSanalysisofdextrin-OregonGreenuptakewithtimein:(A)chondrocytesisolated
fromexvivotranswellgraftsfollowingexposuretodextrin-OregonGreenand(B)chondrocytes
isolatedfromarticularcartilageexplantsculturesfollowingexposuretodextrin-OregonGreen.
23
Figure5:Pictureofexvivotranswellgraftsanddiagrammaticrepresentationofthestructureof
thecultures(insert)
TimeZero2Hours4Hours8Hours24Hours
Figure6:Analysisofthedistributionoffluorescenceintranswellfilterculturesbyfluorescence
spectroscopy.
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
1 2 3 4 5
Pro
pro
tio
n o
f To
tal Flu
orescen
ce (
%)
Cells / matrix / filter
Insert media
Outer media
Insert starting medium
Outer Medium
Cartilage matrix plug
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
1 2 3 4 5
Pro
pro
tio
n o
f To
tal Flu
orescen
ce (
%)
24