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Chapter
THERMALANALYSISANDCALORIMETRICMETHODSAPPLIEDTOPHARMACEUTICALSOLIDFORMS
DanièleGiron
Contents
8.1. INTRODUCTION......................................................................................................................................387
8.2. BASICPRINCIPLESOFTHERMALMETHODSANDTHEIRIMPORTANCEINPHARMACEUTICALANALYSIS.........................................................................................................388 8.2.1. Thermalanalysismethods...................................................................................................388 8.2.2. Microcalorimetry......................................................................................................................388 8.2.3. Overviewofapplications.......................................................................................................388
8.3. FACTORSTOBECONSIDEREDINTHEINSTRUMENTATION............................................391 8.3.1. Heatfluxdifferentialscanningcalorimetry(DSC)andpower
compensationDSC...................................................................................................................391 8.3.2. Thermogravimetry..................................................................................................................397
8.4. WHATARETHEAREASOFAPPLICATIONFORTHESTUDYOFSOLIDFORMS?......400 8.4.1. Thermodynamicdata..............................................................................................................400
Chapter8
386
8.4.1.1. Twopolymorphicsolidphases.........................................................................400 8.4.1.2. Thephasediagramsofsalts,solvatesandhydrates...............................404 8.4.1.3. Amorphousstate.....................................................................................................407
8.4.2. Puritydetermination..............................................................................................................408 8.4.3. Kineticaspects...........................................................................................................................410 8.4.4. Sorptionisothermsandhydrates.....................................................................................413 8.4.5. Combinedtechniques.............................................................................................................416
8.4.5.1. CombinationofDSCandXRD............................................................................416 8.4.5.2. Thermogravimetry‐massspectrometry(TG‐MS)and
thermogravimetry‐infraredspectroscopy(TG‐IR).................................416 8.4.6. Isothermalmicrocalorimetryandsolutioncalorimetry.........................................421
8.4.6.1.Microcalorimetry....................................................................................................422 8.4.6.2. Solutioncalorimetry..............................................................................................424
8.5. SOMEEXAMPLESOFAPPLICATIONS...........................................................................................424 8.5.1. Theselectionoftherightform...........................................................................................424 8.5.2. SensitivityofDSC.....................................................................................................................425 8.5.3. Disappearingsolvates............................................................................................................426 8.5.4. Selectionofthebestformconsideringthepharmaceuticalenvironment.....426
8.6. CONCLUSION...........................................................................................................................................428
REFERENCES......................................................................................................................................................428
387
8.1. INTRODUCTION
Thermal analysis techniques, in which a physical property is monitored asfunction of temperature or time while the analyte is heated or cooled undercontrolled conditions, are fundamental techniques for the characterisation ofdrug substances and products. They are fundamental as processing or agingconditions may be simulated, and because the methods give access tothermodynamicdata.Duetothedifferentinformationconveyed,thermalanalysismethodsarecomplementarytootheranalyticaltechniques,suchasspectroscopy,chromatography, melting point determination, loss on drying, assays foridentification, purity and quantitation. Thermal analysis techniques are basicmethods in the field of solid state analysis, in physical and chemicalcharacterisationof pure substances, aswell as formixtures.They find thebestapplication inpre‐formulation,processingandcontrolof thedrugproduct.Theintroduction of sophisticated, automated, robust and sensitive instrumentsconsiderably increased the advantages of these methods. New horizons havebeenopenedwiththeavailabilityofcombinedtechniquesandmicrocalorimetry,anemergingtechniquewhichisnowusedroutinely.
Sincechangesintemperatureandmoisturemightinducethechangesinthesolidstate,processingandstoragemayhaveaconsiderableeffectonactivity,toxicityandstabilityof compounds.Thepharmaceutical industry is facedwith thenewchallenges of quicker development and higher performance, in terms oftechnology, reliability and up‐scale in the international current GoodManufacturing Practise (cGMP) environment. Current requirements set by theInternationalConferenceofHarmonisation(ICH)forthecharacterisationandthequantitation of polymorphism in new entities [1], re‐enforce the position ofthermalanalysisandmicrocalorimetrictechniques,whichcandeliverthecorrectinformation concerning the thermodynamic relationships between phases, forthe proper selection of salt and crystal forms. The amorphous state is betterunderstood and determinable. Differential scanning calorimetry (DSC) purityanalysis isa fast,absolute,orthogonalpurity technique fororganiccompounds.Microcalorimetry, DSC and thermogravimetry (TG) are advantageous in theprocessofdesignofdrugproducts.
Chapter8
388
8.2. BASICPRINCIPLESOFTHERMALMETHODSANDTHEIRIMPORTANCEINPHARMACEUTICALANALYSIS
8.2.1. Thermalanalysismethods
Whenamaterialisheatedorcooled,thereisachangeinitsstructureorcompo‐sition.Thesetransformationsareconnectedwithaheatexchange.Thefirstappli‐cationofthermalanalysiswaspresentedbyLeChatelierin1887[2].Indiffere‐ntialthermalanalysis(DTA),thetemperatureinducedinthesampleismeasured.DSC,whichdetermines theheat flow intoandoutof the sample, aswellas thetemperatureofthethermalphenomenonduringacontrolledchangeoftempera‐ture,isthebasicthermaltechniqueusedforsolidforms.Thermalanalysistechni‐quesalsocoverallothertechniquesinwhichaphysicalpropertyismonitoredasa function of temperature or time,while the sample is heated or cooled undercontrolledconditions.Forthesolidstate,thephasediagramrulesforsinglecom‐pounds,aswellasformixturesofseveralcomponents,havetobeconsidered.Themostcommonmethodsusedinsolidstatecharacterisationare:DSCandTG,andtheyareoftencombinedwithmassspectrometry,X‐raydiffraction(XRD),IR,Raman spectroscopy and microscopy. Books and reviews dealing with theprinciples,instrumentationandapplicationsaregiveninreferences[3‐10].Specificapplications of thermal analysis and calorimetric methods for pharmaceuticalpolymorphismaregiveninreferences[11‐19].
8.2.2. Microcalorimetry
A calorimeter measures the heat flow into or out of a sample, whereas adifferentialcalorimetermeasurestheheatofasamplerelativetoareference.Adifferentialscanningcalorimetercombinesthesetwomethods,andadditionally,heatsthesamplewithalineartemperatureramp.
Microcalorimetry in isothermalmode is a growing technique, complementary toDSC for the characterisation ofpharmaceuticals [20]. Larger sample volume andhighersensitivitymeanthatphenomenaofverylowenergy,immeasurablebyDSC,may be studied. The output of the instrument is measured by the rate of heatchange(dq/dt),asafunctionoftime,withasensitivitybetterthan0.1W.Micro‐calorimetrycanbeappliedtoisolatedsystemsinspecificatmospheres,orforbatchmode,wherereactantsaremixed in thecalorimeter.Themostusefulapplicationcurrently, thanks to high throughput microcalorimeters [21], is the routinequantitationofundesirableamorphouscontentdownto0.1‐0.3%[22‐25].
Solutioncalorimetrycanbeusedinadiabaticorisoperibolmodesinmicrocalori‐meters at constant temperature. This method is used for polymorphic inter‐pretationandforquantitation[12].
8.2.3. Overviewofapplications
The processing of the drug substances and drug products involves solvent(s),temperatureandpressurechanges,aswellasmechanicalstressand,asaresult,
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
389
differentsolidphasesmaycoexistinthedrugproduct.Organicsubstancesshowsupersaturationbehaviourandunstablesolidphaseswhichshouldnotexistatadefined temperature,pressureandhumidity,butmaybehave likestable forms.Thesesolidmetastablephases,obtainedoutsideoftheirdomainsofstability,willconvert to their thermodynamically stable forms at given temperatures, pres‐suresandrelativehumidities, in response tochanges inenvironmental conditi‐ons,processing,orovertime.Theseconversions,drivenbythermodynamics,aregoverned by kinetics and are influenced by impurities, particle size, crystaldefectsandpresenceofseeds.
The market withdrawal of Ritonavir in 1998, one year after its launch, wascausedbyithavingarateofdissolutionthatwasfartooslow,duetoaninsolublestable polymorph not found during development [26]. The current focus ofresearch in the solid‐state area is tounderstand theoriginofpolymorphismatthemolecularlevel,andtopredictandpreparethemoststableformatthestartofdevelopment.Theselectionofametastable formshouldresult fromtargetedchoice,ratherthanfromchance.Theadvantageofthermalandmicrocalorimetrictechniquesisthattheirsensitivityallowsasamplesizeofconsiderablylessthan1mg.Table8.1summariestheanalysismethodsdetailed,includingcoupledandcombinedtechniques.
Table8.1.Mainthermalanalysistechniquesandcalorimetry
Technique Measurements Thermalevents
DifferentialScanningCalorimetry(DSC)
DerivativeDSC(DDSC)Micro‐DSCHyper‐DSC
Heatflowintoandoutofthesampleasa
functionoftemperature/time
Everythermaleventassociatedwithenergychangeduringheatingorcooling
melting,boiling,sublimationandcrystallisationglasstransition
polymorphicphasetransitiondesolvation,dehydrationandisomerisation
complexphasetransitionthermaldegradation
mixtures;phasediagramspuritydeterminationoxidation,catalysischemicalreactionkineticanalysis
couplingwithTG,microscopyorX‐ray
ModulatedDSC(MDSC) Totalheatflow,irreversibleand
reversibleheatflow
everytransitiondistinctionbetweenoverlappingthermalevents
studyofrelaxationofglasstransition
Thermogravimetry(TG)Derivative
thermogravimetry(DTG)
Changeinsamplemassasafunctionof
temperatureand/ortime
Everychangeofmassdesolvation,dehydration
sorption‐desorptionisothermsdegradation
compositionalanalysischemicalreactionkineticanalysis
dryingoptimisationcouplingwithDSC,GC,MS,IR,Raman
Chapter8
390
Technique Measurements Thermalevents
ThermomechanicalAnalysis(TMA),
Thermodilatometry
Dimensionalchangesduringcompression,penetration,tension,flexureortorsionversustemperature
Mechanicalproperties,dimensionsexpansion,dilatationglasstransition
gelification,swelling
Dynamicmechanicalanalysis(DMA)
Dimensionsversusfrequencyandtemperature
Youngmoduluspolymeranalysis
ThermallyStimulatedCurrent(TSC)
DielectricThermalAnalysis(DETA)
Depolarisationcurrentcurveversustemperature
Dielectricconstant
relaxationalphaandbetaofglassesquantificationofamorphous
ThermalConductivity(TC)
Thermalconductivity thermalconductivity,thermaldiffusivityonlineanalysisofprocesses
Thermomicroscopy Microscopicalobservationunder
differentmodesoflightilluminationduringheatingorcooling
melting,crystallisation,evaporation..eutecticformationsolubilitystudies
crystallinityusingpolarisedlightmorphologicalstudies
TG‐MS,TG‐Raman,TG‐IR CoupledspectroscopicanalysiswithTG
analysisofvolatilesinvestigationofdryingprocessesinvestigationofsolvates,hydratesinterpretationofthermalevents
Evolvedgasanalysis(EGA)
TGcoupledwithGCandpossiblyMS,IR
Identificationandquantificationofvolatilecomponents
Combinedspectroscopicmethods
Programmedheatingcellwithspectroscopicanalysis(IR,Raman,NMR,Terahertz))
spectroscopicdataofphasesobtainedinsituduringcombinedwithThermomicroscopyinterpretationofthermalevents
TemperatureresolvedXPRDor
coupledDSC/XRD
X‐raypowderdiffractionversustemperature
interpretationofthermaleventsidentificationofphasesinsitu
XPRDofunstableformscombinedwithmodelling
Microcalorimetry
HeatfluxoutofthesampleinIsothermal
mode
heatofsolutionheatoftransformation,heatofreaction
quantificationofamorphousstabilityprediction
kinetic
Nano‐DSC Heatfluxoutofthesample
Speciallydesignedforlifescience,foldingofproteins,siRNAusedforqualitycontrolinbiologicalscience
CalorimetryAcceleratedcalorimetryReactioncalorimetry
Heatmeasurement safetysimulationofprocessessimulationreactors
Titrationcalorimetry Heatmeasurementduringadditionof
reactant
bindingconstantstudyofmolecularbindingofproteins,nativecells
drug‐cellsinteractions
Micro‐thermalanalysis Heatfluxandatomicforcemicroscopy
Topography,withconductivityandthermaldiffusivityinterfacesstudies
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
391
8.3. FACTORSTOBECONSIDEREDINTHEINSTRUMENTATION
Moderninstrumentsusedforthermalanalysisusuallyconsistoffourparts:
‐ thesampleandsampleholder,‐ sensors to detect and measure a property of the sample, as well as thetemperature,
‐ asystemwithintheinstrumentthatallowstheexperimentalparameterstobecontrolled,
‐ acomputertocontroldatacollectionandprocessing.
8.3.1. Heatfluxdifferentialscanningcalorimetry(DSC)andpowercompensationDSC
DSCmeasures thetemperatureand theheat flowassociatedwithtransitions inmaterials,asafunctionoftimeandtemperature,inacontrolledatmosphereandrelativetoareference.Thesemeasurementsprovidequantitativeandqualitativeinformation about physical and chemical changes that involve endothermic orexothermicprocesses,orchangesinheatcapacity.
TheprincipleofDSCisasfollows:twoovensareheatedinalinearmanner.Oneovencontainsthesampleinapan;theothercontainsanemptypanasabalance,termedareferencepan.Ifnothingoccurstothesamplethenthesamplepanandreferencepanareat the same temperatureduringheating. If a change, suchasmelting occurs in the sample, then energy is used by the sample and thetemperature remains constant in the sample pan during melting. Therefore, adifferenceoftemperatureoccursbetweenthesamplepanandreferencepan.
Two methods of measurement are used by manufacturers. The first method istermed "heat flux DSC", in which the instrument measures the temperaturedifference(DTA).Throughcalibration,thistemperaturedifferenceistransformedintoheatflow(dq/dt).Theinstrumentcontainsafurnace,whichisablockforbothsample and reference cells. The sampleholder contains the samplepan, and thereferencepanisconnectedbyalowresistanceheatflowpath;thermocouplesareusedfordeterminingthetemperaturedifferencebetweensampleandreference.
Inthesecondmethod,whichistermed"powercompensationDSC",twoindividualheaters are used in order to monitor the individual heating rates of the twoindividual ovens. A system controls the temperature difference between sampleandreference.Ifanydifferenceisdetected,thespecificheaterwillbecorrectedsothatthetemperatureiskeptthesameinbothpans.Thatis,whenanendothermicor exothermic process occurs, the instrument delivers the compensation energywhichmustbegiveninordertomaintainequaltemperaturesinbothpans.
In the firstmethod (heat flux DSC), temperature is primarilymeasured, in thesecond case (power compensationDSC), energy isprimarilymeasured.Despitetheir different modes of operation, both instruments deliver the same infor‐mation:heatflowasafunctionoftemperature(ortime).
Chapter8
392
For first order transitions, such asmelting, crystallisation, sublimation, boilingetc.,integrationofthecurvegivestheenergyinvolvedinthetransition.Melting,boiling, sublimation and desolvation are endothermic, whichmeans they needenergy.Crystallisationisexothermic,whichmeansthatitsuppliesenergy.Solid‐solidphasetransitionanddecompositionmaybeendothermicorexothermic.Forsecondordertransitions,thesignalgivesthechangeinthespecificheat;forex‐ample,intheglasstransitionsofamorphousmaterials.Manufacturersrepresenttheheatflowdifferently:endothermshavethepositivevaluesinpowercompen‐sation DSC, and negative values for heat flux DSC. Figure 8.1 shows typicaltransitions for a single compound: with a power compensation DSC with anendotherm rising, or for heat flux DSC with an endotherm falling. Bothrepresentationsareacceptedifthesignsforendothermorexothermaregivenonthecurves.Generallythetemperatureisplottedonthexabscissa(usualgivenin°C)andtheheatflow(dQ/dt,dq/dtordH/dt)isplottedontheyordinateinJs‐1.Most recent curvesaregiven inmWatts (mW),which is equivalent, and in thischapterbothexpressionsareused.Melting,crystallisationandphasetransitionsarefirstordertransitions.Theintersectionbetweenthebaselineandtheslopeofthe peak is the extrapolated temperature onset of the transition (Te). Thecorrespondingenergy is theareaunderthepeak.Thepeaktemperature(Tm) isvery dependent on instrument andmeasurement parameters. The glass point,whichisasecondordertransition,isdeterminedasaninflexionpoint.
Figure8.1.ExamplesofapowercompensationandheatfluxDSCcurves
forasinglecompound
Temperature, oC
Glass Crystallization Melting Decompositiontransition
Hea
tflo
w,
dQ/d
t
Power compensation DSC
Heat flux DSC
Endo
Exo
Exo
Endo
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
393
Modern instruments permit the heating, cooling and isotherm curves betweensub‐ambienttemperatures,withuseofacoolingdevice,andhighertemperaturesintherangeof1200‐1500°C.Curvesmadeusingdifferentinstrumentscannotbe compared to one another; correctionsmust be calculated according to eachinstrument.Greatcaremustbegivento thetemperature,withthetemperatureplotted on the abscissa being the programmed temperature, not the realtemperature of the sample. The actual temperature depends on the thermalresistanceandheatingrateoftheinstrument,whichiscalledthe"thermallag"ofthe system. The correlation between apparent melting point and heating ratedependsonthemanufacturer.Generally,pureindium(>99.9999%)isusedwitheach series of measurements. Modern instruments, with data handling, enablethetruetemperatureofeachpointoftheDSCcurvetobecalculated.
Figure 8.2 exemplifies the effect of the heating rate on the DSC curves. Anexample of the DSC curves of indium using different heating rates on a DSC‐2Perkin‐ElmerinstrumentisgiveninFigure8.2a.Sinceenergyistheintegrationofthe signal as a function of the time, the DSC curves are not identical at everyheating rate. The “thermal lag” is instrument specific. Since the meltingtemperatureofindiumis156.6°C,theextrapolatedonsethastobecorrectedforeach heating rate. Figure 8.2b shows the plot of the extrapolated onset of thecurvesforindiumversusheatingrateat1.25,2.0,5.0,10.0and20°Cmin‐1.Thiseffecthastobetakenintoconsiderationwhencomparingcurvesobtainedusingdifferentheatingrates,andespeciallyifmeasuredwithdifferentinstruments.
Figure8.2.Effectofheatingrateonthemeltingpointofindium.
(a)DSCcurvesat1.25,2.0,5.0,10.0and20.0°Cmin‐1;(b)correspondinglinearrelationshipbetweenmeltingpointandheatingrate
Figure8.3showstheinfluenceofheatingrateontheresolutionofpolymorphsoftemazepam.Thebest resolution isobtainedwitha lowheating rate. Figure8.4exemplifies the influence of the sample mass on the resolution for the samecompound.Theheatingrate(sensitivityoftheinstrument),andthesamplemasshavetobechosencarefullytodetectthermaleffectswhichareveryclosetooneanother.
156,1
156,2
156,3
156,4
156,5
156,6
156,7
0 5 10 15 20 25156 157 158 159 Temperature, oC Heating rate, oC min-1
He
atf
low
E
nd
o
Te
mp
era
ture
on
se
t, o
C
a b
Chapter8
394
Figure8.3.DSCcurvesshowingtheeffectofheatingrateontheresolution
ofpolymorphsoftemazepam
Figure8.4.DSCcurvesshowingtheeffectofsamplemassontheresolution
ofpolymorphsoftemazepam.Heatingrate1.25°Cmin‐1
Figure8.5dealswiththemeasurementof theglasstransitionwithandwithoutthermal effect. The thermal effect appearing as a maximum on DSC curvedependsonthethermalhistoryofthesample,andiscommonlyusedinthestudyofamorphousmaterialsandpolymers.Athighheatingratesthesignalishigherbecause,fortheglasstransitionthechangeincpisdq/dtordH/dt,andiseasiertomeasure.
He
at
flo
w
En
do
Temperature, oC
20 oC min‐1
0.85 mg
10 oC min‐1
2.11 mg
5 oC min‐1
1.50 mg 1.25 oC min‐1
2.00 mg
He
at
flo
w
En
do
Temperature, oC
0.537 mg
10.096 mg
0.21 mJ s
‐1
2.1 mJ s‐1
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
395
Figure8.5.DSCcurvesfortheglasstransition(a)withoutthermaleffectand
(b)withthermaleffect
Great effortshavebeenmade in recent years to validatedifferent instruments,notonlyincomparingprinciplesandresults,butalsoindeterminingheatingandcoolingrates,particlesize,weight,resolution,atmosphereandtypeofpans.Thetypeand thesizeofpans isofgreat importance forcomparingresults; typesofpanmayincludeopenpan,crimpedpan,sealedpanorpinhole.Thesametypeofpansmustbeusedforbothsampleandreference.Ifpansarehermeticallyclosedthenthesolventcannotescape,andthecurvesarenotthesameasforpanswithapinhole.Figure8.6exemplifiestheproblemforamonohydrate.Inasealedpan,theDSCmeltingpeakof themonohydrate isobserved.Whereas, ifapinhole ismade in the cover of the pan, water can escape and the transition into theanhydrousformisobservedasendothermic/exothermicphenomenonbeforethemelting of the anhydrous form occurs. Unlike the curves formonohydrate, theanhydrousformisnotaffectedbythetypeofthepan.
Theuseof flowingpurgegas (nitrogenor argon) is requiredas thewastepro‐ductsfromsublimationordecompositionhavetoberemoved.Duetothelubri‐cantusedinthemanufactureofaluminiumpans,thesepansmustbepreheatedinordertoavoidartefacts.Thehomogeneityofthesample,thesampleprepara‐tion,anycontaminations,thetimebetweenthemanufactureofthesampleanditsmeasurement,thesamplemassandthermallagarethemainsourceoferrors.Inpharmaceutical development, instruments must be calibrated and routinelychecked. It shouldbeemphasised thatmeltingpointsofpolymorphsmaydifferbylessthan1°C,andthatdifferencesinmeltingenergyareoftenlessthan5%.Therefore,allvariablesofanautomateddevicehavetobecontrolled.
Table8.2dealswithexamplesofstandards,includingIUPACandWHOstandards,proposedfortemperaturecalibration.Thestandardsmustbeofcertifiedpurity.For heat calibration, the melting energies of certified substances with meltingpointsbetween60°Cand230°CareproposedinTable8.2.
a b
Chapter8
396
Figure8.6.EffectofthetypeofpanonDSCcurvesforamonohydrate(____)andforananhydrousform― – ―).Withthesealedpan,onemaymeasure
themeltingofthehydrate.Withpinhole,waterescapesandarecrystallisationintotheanhydrousformisobserved
Table8.2.CertifiedsubstancesforthecalibrationofDSCinstruments
CertifiedsubstanceMelting
temperature,°CStandardsubstance Meltingenergy,Jg‐1
Iodobenzene ‐31.3 Naphthalene 148.6
H2O 0.0 Benzil 112.0
4‐nitrotoluene 51.5 Benzoicacid 147.2
Biphenyl 69.3 Biphenyl 120.4
Naphthalene 80.2 Diphenylaceticacid 146.9
Benzil 94.7 Indium 28.7
Acetanilide 114.0 Tin 60.2
Benzoicacid 122.1
Diphenylaceticacid 146.5
Indium 156.6
Anisicacid 183.1
2‐chloro‐anthraquinone 210.0
Tin 231.9
Antraquinone 284.5
Lead 327.5
Zinc 418.9
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
397
InmodulatedDSC (MDSC), thenormally linearheating ramp is overlaidwith asinusoidal function, or an oscillating function defined by a frequency and anamplitude, to produce a sine wave shaped temperature versus time function.UsingFouriermathematics,theDSCsignalisthensplitintotwocomponents:onereflecting non‐reversible events (kinetic), and the other reversible events. Thismethod is generally not applied in the characterisationof solidpharmaceuticalforms.Fordetailsonthisapplication,see[3‐8].
8.3.2. Thermogravimetry
Inthermogravimetry(TG),thechangeinsamplemassisdeterminedasafunctionoftemperatureand/ortime.Theinstrumentusedisathermobalancethatallowsthecontinuousweighingofasampleasafunctionoftime.Thesampleholderanda reference holder are bonded to each side of amicrobalance, in a vertical orhorizontal design. The sample holder is situated in a furnace, without directcontactwiththesample,thetemperatureofwhichiscontrolledbyatemperatureprogrammer.Thebalanceportion ismaintainedat a constant temperatureandthe instrument is able to record the loss or gain in mass of the sample as afunctionoftemperatureandtime[m=f(T)].Frequently,themasschangeisgivenaspercentageof thesample.Most instrumentsalsorecordthederivativeof themasschange[dm/dt=f(T)].
ThederivativeTG(DTG)allowsabetterdistinctionofoverlappingsteps,andthedeterminationofthetemperatureatwhichtherateofmasschangeismaximalorminimal.TheareaundertheDTGcurveisproportionaltothismasschange,andtheheightoftheDTGpeakatanytemperaturegivestherateofmasschange.DSCandDTGperformedonhydratesshowthesameoutcome.
Balanceisadjustedwithcertifiedmassatambienttemperatureanditisrecomme‐nded to check themass at temperatures of use. Therefore, the author proposesthreestandards:calciumoxalatedihydrate(watercontent12.3%)(usedforTGinEuropean Pharmacopoeia), disodium tartrate dihydrate (water content15.7%)(used as standard for Karl Fischer analysis) and copper sulphate pentahydrate(watercontent36.1%).Figure8.7ashowssuchcalibrationcurvesat20°Cmin‐1heatingrate.Thedehydrationscoveratemperaturerangeof50to270°C.Inthisfigureweplotforcomparisonthecommonexcipientlactosemonohydrate.
Fortemperaturecalibration,thestandardsrecommendedbyICTAareferromag‐neticstandardsexhibitinglossofferromagnetismattheirCuriepointtemperatu‐re within a magnetic field: Nickel (354°C), Permanorm 3 (266°C), Numetal(386°C),Permanorm5(459°C)andTrafoperm(754°C).Athermobalancewithhorizontal plates is proposed by manufacturers as the melting of standards iseasierfortheuser.
Tables8.3a and8.3b showcalibrationsof a thermobalance at different heatingrates. In order to check the stability of the system, a baseline at the highestsensitivityhastobeperformedforallheatingratesinthetemperaturerangeofanalysis;thehighestdeviationwillbeobservedatthehighestheatingrate.
Chapter8
398
Figure8.7.Thermogravimetryofstandardorganicsubstancesat20°Cmin‐1.(a)TGcurves;(b)DTGcomparedtoTGofcopper(II)sulphatepentahydrate
Figure8.7bshowstheuseofDTGforcoppersulphatepentahydrate,atthesameheating rate as given in Figure 8.7a. The DTG determines precisely the end ofeach step at rapid heating rates, which is an advantagewhen desolvation anddecomposition overlap. Figure 8.8 exemplifies the effect of heating rate on TG
50 100 150 200 250 300
100
90
80
70
60
Ma
ss
, %
Temperature, oC
LactoseH2O
Calcium oxalate2H2O
Sodium tartrate2H2O
Copper sulphate5H2O
a
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
399
curves of disodium maleate dihydrate. The results obtained at the 5 °C min‐1heatingratecomplywiththetheoreticalvaluesofwatercontentofthedihydrate(18.45%).
Table8.3a.Examplesofthemasscalibrationofathermobalanceatdifferentheatingrates
SubstanceTheoreticalamount
ofwater,%Amountofwaterfound,%
5°Cmin‐1 10°Cmin‐1 20°Cmin‐1
Disodiumtartratedihydrate
15.65 15.73 15.60 15.73
Calciumoxalatemonohydrate
12.32 12.55 12.51 12.48
Coppersulphatepentahydrate
36.07 36.08 36.03 36.04
Table8.3b.Examplesofthetemperaturecalibrationofathermobalanceatdifferentheatingrates
SubstanceTheoretical
meltingpoint,°CDeterminedmeltingpoint,°C
5°Cmin‐1 10°Cmin‐1 20°Cmin‐1
4‐nitrotoluene 51.50 51.49 51.64 53.78
Indium 156.60 157.62 157.38 157.74
Tin 231.93 233.44 233.42 233.68
Figure8.8.TGcurvesofdisodiummaleatedihydrateattwodifferentheatingrates
50 100 150 200
Ma
ss
los
s,
%
Temperature, oC
40 oC min-1
5 oC min-1
17.3%18.2%
9.4%
8.6%
Chapter8
400
8.4. WHATARETHEAREASOFAPPLICATIONFORTHESTUDYOFSOLIDFORMS?
8.4.1. Thermodynamicdata
Oncesolidformisobtained,severalquestionsarise:
Istheformamixtureofpolymorphs? Whatisthechemicalpurity? Whatisthedegreeofcrystallinity? Isthesaltformpure? Whatarethethermodynamicwindows:
o fortruepolymorphs?o forsolvatedforms?o fordifferenthydratedforms?o fortheamorphousform?
Thesequestionsneedtobeansweredquickly inordertomeasurecorrectlythephysicochemicalparametersoftheisolatedform.
Polymorphismistheabilityofasubstancetocrystallise intodifferentcrystallinephasesthathavedifferentarrangements,and/orconformationsofthemolecules,inthecrystallattice.Thesecrystallineformsarecalledpolymorphs,orcrystallinemodifications. Polymorphs have the same liquid or gaseous state, but theybehave differently in the solid state. The amorphous state is characterised bysolidificationinadisorderedorrandommanner,structurallysimilartotheliquidstate. The expression pseudo‐polymorphism applies to hydrates and solvates.Hydratesorsolvatesdonothavethesamechemicalstructureastheanhydrousforms,thoughpolymorphismbetweenhydratesorsolvatesdoesoccur.
TherelationshipsbetweendifferentphasesaregovernedbytheGibbsphaserule:
V=C+2‐Ψ (8.1)
whereV=variance,C=numberofcomponents,Ψ=numberofphases.
8.4.1.1. Twopolymorphicsolidphases
Inthecaseoftwopolymorphicsolidphases,Cisequaltoone.Iftwosolidphasesarepresent,andifbothpressureandtemperaturevary, thevariance isunity. Ifpressureisfixed,thenvarianceiszero.Phasediagramsofpressureversustempe‐ratureillustratethedifferentequilibriumcurvesforpolymorphism(Figure8.9).
For each solid form, there is a solid‐liquid equilibrium curve and a solid‐vapourequilibriumcurve.Inthecaseofenantiotropy,thereisanequilibriumcurve(BFinFigure 8.9a), where both polymorphs are in equilibrium and undergo reversibletransitionataspecifictemperatureandatafixedpressure.Inthecaseofmonotropy(Figure8.9b),thereisnothermodynamictransitionbetweentwophases,sinceonlyone solid form is thermodynamically stable. The dashed lines correspond to themetastableequilibriumcurveswhichhavetobetakenintoconsideration.
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
401
Figure8.9.PhasediagramsP,Tforasinglecompoundshowing(a)enantiotropicand
(b)monotropicpolymorphism
Theabilityofasystemtoperformwork,andtoundergoaspontaneouschangeatconstantpressure ismeasuredbytheGibbsenergy,∆G.∆Ghasbeendefined intermsofenthalpyandentropychanges,∆Hand∆S,attemperatureTas:
∆G=∆H–T∆S (8.2)
Gibbsenergy(G),enthalpy(H)andentropy(S)arestatefunctionsandtheterm∆canbeomitted.
G=H–TS (8.3)
At 0 Kelvin, G = H. Since the entropy S is always positive, G decreases withincreasing temperature. The energy diagram,G versus temperature at a givenpressure, reflects the transition observed between both solid phases, andbetween solid and liquid phases. If a transition betweenphases occurs then atthistemperaturebothphaseshavethesameGibbsenergy,G.
Ingeneral,thethermodynamicrelationshipbetweentwopolymorphicphasesisrepresentedbyplottingGibbsenergyasafunctionoftemperatureforeachform(Figure 8.10). If the two curves intersect below the melting point of eachpolymorph, a reversible transition occurs at the temperature Tt of theintersection.AttemperaturesbelowTt,polymorphAhasthelowerGibbsenergyandisthereforethethermodynamicallystableform,whileattemperaturesaboveTt ,polymorphB isstable.Thetransitionpointcanbe low,evenbelowambienttemperature, or in other cases, very high (above 200 °C). In the case ofmonotropy, there is no intersection of theGibbs energyof both forms, and thehighermeltingformisalwaysthethermodynamicallystableform.
T T
P P
a b
Chapter8
402
Figure8.10.EnergydiagramsdepictingdependencesofHandGvs.temperaturefor
(a)enantiotropicand(b)monotropiccompound
The relativepositionof theG‐isobars (∆GA→B) of differentmodifications canbedeterminedbysolubilityexperimentsinagivensolvent:
∆GA→B=RTln(SA/SB) (8.4)
whereSAisthesaturationsolubilityofthemodificationAandSBisthesaturationsolubilityofthemodificationB.
Eachcrystalformhasitsownheatcapacity,whichisafunctionoftheenthalpyHandthetemperature.Theheatcapacityofsolidsatconstantvolumeandconstantpressureareaboutthesame.TheHisobarsofthetwomodificationsareparallelandtheirdistanceisthetransitionenthalpyHt.
Burger [27‐28], proposed to plot energy/temperature diagrams of the Gibbsenergy(G)andtheenthalpy(H),asfunctionsoftemperature.Thisproposalisthefundamentaltoolforthesolutionofcomplexpolymorphicsystems.AsshowninFigures 8.10a and 8.10b, a notable difference between enantiotropy andmonotropy is the melting enthalpy of the higher melting form. In the case ofenantiotropy,thehighermeltingformhasthelowermeltingenthalpy.Inthecaseofmonotropy,thehighermeltingformhasthehighermeltingenthalpy.
DSC,whichmeasureseveryheatflowchangeuponheatingorcooling,isthemostappropriate technique, since the method allows us to determine the meltingpoints and the melting enthalpies, as well as the transition points and thecorresponding energy. The influence of kinetics can be followed by usingdifferentheatingratesandtemperinginsitu[12].
TherelationshipbetweenmeltingenthalpiesoftwosolidphasesAandB,andtheheatoftransitionisapproximately:
Ht=HfA‐HfB (8.5)
L L
Energy (G
, H)
Energy (G
, H)
a b
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
403
The temperature of transition between two enantiotrops can be calculatedaccordingtoEquation8.6byneglectingthedifferencesinspecificheat.
Tt=TATB(HfAHfB)/(HfATB‐HfBTA) (8.6)
In the case of enantiotropy, the lowmelting form is the thermodynamic stableformbelowthetransitionpoint,andabovethispointthehighmeltingformisthethermodynamicstableform.Thetransitionpointcanbelow;closeto40°Cinthecaseoftolbutamide,closeto100°Cinthecaseofpropyphenazoneorevenhigherthan200°C.Figure8.11illustratesthecaseofthereversibletransitionbetweenpolymorphsoftolbutamide,withreversibleDSCheatingandcoolingcurves.
Figure8.11.DSCcurveforthereversibleenantiotropictransition;Inset:heatingand
coolingcurvesinthetemperaturerangeofthetransition
In thecaseofmonotropy, there isonly thehighmelting formpresent,which isthe thermodynamic stable form within the entire range of temperatures.Sometimes ametastable form can behave as a stable form, and the DSC curveshowsanexothermictransitionbeforethemeltingofthestableform,helpingtodefinethethermodynamicallystableanhydrousform(seeFigure8.12).
Duetokinetics,metastableformscanappearandbecausedifferentcaseshavetobe taken into account, it is mandatory to use different heating rates for DSCexperiments(seeSection8.4.3).Forsolidformselectionitisabsolutelynecessarytoknowthetemperatureofthetransitionofenantiotropicsystems,sinceit isathermodynamicvalue.Doesthetransitiontakeplaceat20°C,30°C,70°Corat120°C?Whatare the consequences fordrugdevelopment?The temperatureofthe process, the temperature of storage and transport are important factors inproduction.
Temperature, oC
He
at
flo
w,
mW
En
do
Chapter8
404
Figure8.12.DSCcurveofametastableformwhichtransformsinthestableform
withexothermictransition(monotropy)
Duetokineticbehaviour,thetemperatureoftransitionobservedinDSCishigherthan the temperature observed by solubility measurements or slurryexperimentsinthepresenceofsolvents.Table8.4showssomedataobtainedbycalculation,accordingtoEquation8.6,comparedtoexperimentaldata.
Table8.4.Determinationofenantiotropictransitiontemperaturesforexamplesubstancesbycalculationandexperiment
Substance Transitiontemperature,°C Method
Carbamazepine7173
CalculationSolubility
Nimodipine8288
CalculationSlurryexperiment
Substanceindevelopment3925
CalculationSlurryexperiment
8.4.1.2. Thephasediagramsofsalts,solvatesandhydrates
The phase diagrams of salts, solvates and hydrates aremore complex becausebinary mixtures are often of different compositions. The new compound mayundergo congruent melting (Figure 8.13a), or non‐congruent melting (Figure8.13b).Throughheating,themeltingofthesolvatemaybeobserved,followedbytransformation to an anhydrous form, or the solvent may be involved in anendothermic transition into the anhydrous form.A series of suchbinaryphasediagramshastobeconsideredifseveralcompoundsareformed.Thesediagramsarefundamentaltotheunderstandingofcrystallisationanddryingsteps.Analyti‐cal investigations of solvates are not possible without thermogravimetry.ExamplesofDSCandTGcurvescorrespondingat thesebehavioursaregiveninFigures8.14and8.15.
He
at
flo
w
E
nd
o
Temperature, oC
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
405
a b
Figure8.13.Binaryphasediagrams(solvates,salts);(a)stablecompoundCand2eutectics;(b)non‐congruentmelting,peritecticbehaviour,thecompounddissociates
Figure8.14.DSCandTGcurvesforcongruentmeltingofthehydratefollowed
bylossofwaterandcrystallisationintotheanhydrousform
The effect of pressure on dehydration steps is exemplified by Figure 8.16 forcoppersulphatepentahydrate.Dependingonthepressure,dehydrationcangivetheanhydrousform,themonohydrateorthetrihydrate.Thisexplainsthecoexi‐stenceofdifferentstepsofhydrationduringdrying,millingortableting.
Ex
oH
ea
tfl
ow
E
nd
o
TG
DSC
Temperature, oC
Ma
ss
,%
3.6% H2O
50 100 150 200
Chapter8
406
Figure8.15.DSCandTGcurvesforaperitecticbehaviourofasolvate:endothermic
transitionbetweentheethanolsolvateandtheanhydrousform
Figure8.16.Effectofthepressureonthedehydrationstepsofcoppersulphate
pentahydrate:intotrihydrate,monohydrateandanhydrous.Adaptedfromreference[29]
55 75 95 115 135 155 175 195 215 235Temperature, oC
He
at
flo
w
E
nd
o
TG
DSC
0.8%
2.9%
Ethanol
H2OMa
ss
,%
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
407
8.4.1.3. Amorphousstate
Ifaphysicalpropertyofacrystallinesubstanceisplottedagainsttemperature,asharpdiscontinuityoccursatthemeltingpoint.Foramorphoussubstancesthereisnomeltingpoint,andachangeofthebaselineoftheDSCcurveoccursattheso‐called glass transition temperatureTg. Below this temperature, the amorphousphasehascertainpropertiesofacrystallinesolid(e.g.plasticdeformation)andistermed “glassy”. At temperatures above Tg, the substance retains some of thepropertiesofaliquid,e.g.molecularmobility,andistermed“rubbery”.AboveTg,theincreaseinmolecularmobilityfacilitatesspontaneouscrystallisation,withanexothermicenthalpychangeaftertheglasstransition(seeFigure8.17).Theglasstransition temperature is decreased bywater, or other solvents and additives,facilitatingcrystallisation.Theamorphousstateisunstable,andthestudyoftheglasstransitionwithexcipientsunderhumidity, isapartofthepre‐formulationprocess[30].Amorphoussolidphasesareobtainedeitherbymeltquenching, ifno degradation occurs during themelting, or by lyophilisation. They are easilydetected by DSC, since the glass transition can be followed by the exothermiccrystallisation into thecrystallinestate,or canbedetectedbyXRD.Figure8.18shows a casewhere a very small amount of amorphous formwas detected byDSCalone.
Figure8.17.DSCcurvesofacrystallineandanamorphoushydrochloridesaltofa
substance.Inset:temperaturerangeoftheglasstransitionoftheamorphouscompound
Chapter8
408
Figure8.18.Detectionofanamorphouspartdownto1%inadrugsubstance
withpolymorphicbehaviour.
8.4.2. Puritydetermination
Asalreadydescribed, themethodforpuritydeterminationpreviouslyproposed[31] is particularly attractive as it does not require a reference standard. Thismethoddeliversabsolutepurityorassayvalueand resultsareobtained in lessthan 30minutes. The determination of purity bymeans of DSC is based on theassumptionthatimpuritiesdepressthemeltingpointofapurematerialaccordingtoeutecticphasediagrambehaviour.Figure8.19ashowsthephasediagramforthetwo componentmixturewith a eutectic point. At the eutectic point, for example40%A,60%B, thecrystalsAandBmelt togetherat the temperatureTE (Figure8.19b),belowthemeltingtemperatureofthepurecompounds.IfamixtureofAandB(containinge.g.90%A) isheated, themeltingof theeutecticmixture(which is40% A) is observed initially, until all of B is melted. During the melting of theeutectic mixture (40%A, 60%B) a part of A is melted with B, with thecorresponding amount of A (2/3 x 10%, i.e. 6.66 % of A). As the temperatureincreases,pureAmeltsbetweenTEandTm(Tmbeingtheendofthemelting).ForthecorrespondingDSCcurve,ifanendothermicheatflowattheeutectictemperatureisobserved,thenthemeltingofcrystalsofAoccurs.
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
409
Figure8.19.PuritydeterminationbyDSC
(a)phasediagramofthemixtureoftwocompoundsformingeutecticmixture,(b)DSCcurveoftheeutecticmixture,
(c)broadeningofDSCcurveduringthemeltingofasubstanceaftereutecticpoint,(d)aplotofobservedanalytetemperaturevs.reciprocalvalueofthefractionmelted.
TheeffectofimpurityontheDSCcurveisameltingdepressionandabroadeningofthemelting curve. The amount of impurities is calculated from themelting pointdepression∆T=To‐Tm.Thevan'tHoff'slawfordilutedsolutionsis:
f2
0
- T Hx =
RT (8.7)
He
at
flo
w
En
do
T T
100% A0% A
A + B
B + Liq. A + Liq.
Tm Tm
TEx2
TE TE
T0
Liq.
Temperature, oCComposition
Heat flow Endo
a b
Chapter8
410
wherex is themole fractionof impurities,∆T themeltingpointdepression,∆Hfthemeltingpointofpurematerial,Tmthemeltingof theanalyte,To themeltingpointofthepurecompoundandRthegasconstant.
TheDSCproceduredoesnotdirectlymeasure∆T,butcanbeusedtocalculateitfromthemeltingcurve.AttheeutecticpointallofBisintheliquidphase.Duringthe melting of A, after the eutectic point, the concentration of B varies in theliquidphase.ThiscausesthebroadeningoftheDSCcurve(Figure8.19c).Withnosolidsolutionformation,theconcentrationofimpurityintheliquidphaseatanytemperatureduringthemelting is inverselyproportional to the fractionmeltedatthattemperature,andthemelting‐pointdepressionisdirectlyproportionaltothe mole fraction of impurity. A plot of the observed analyte temperature,Ti,versusthereciprocalofthefractionmelted1/FiattemperatureTi,shouldyielda straight line with the slope equal to the melting‐point depression (To ‐ Tm)(Figure8.19d).The theoreticalmeltingpointof thepurecompound isobtainedbyextrapolationtol/Fi=0:
2o
ii 0
f
1
RTF
T T xH
(8.8)
Thecorrection,K,hastobemadecorrespondingtothepartalreadymeltedintheeutectic, and the detected beginning of themelting curve. Figure 8.19d depictssuch a determination. Software from manufacturers mostly uses iterativelinearisationwhichgivesthebestvalueofK.
Characteristicsofthepuritydeterminationareasfollows:
‐ impuritieswhichhave eutectic behaviour aremeasured (i.e. soluble in theliquidphaseandinsolubleinthesolidphase),
‐ thesumofimpuritiesshouldbe<2%,‐ theresultisexpressedinmole%withoutknowledgeofimpurities,‐ purematerialisnotneeded,‐ smallamounts(0.1‐2mg)ofmaterialareused,‐ ifdecompositionoccursduringmeltingitcangiveerroneousresults.
Thecalculationofpurityallowstheinterpretationofthecomplexcurvesgivenbyendotherms preceding the melting. It has been used successfully in stabilitystudies at the beginning of development. An example is given in Section 8.4.4,Table8.5.
8.4.3. Kineticaspects
EveryDSCstudyshouldincludescansatdifferentheatingratesduetoDSCbeingadynamicmethod,andsolid‐statetransformations,whilebeingthermodynami‐cally driven, are kinetically controlled. The DSC scans will differ if the sampleunderstudyisstableormetastableatambienttemperature.AtypicalsetofDSCscansillustratesthestudyofthepolymorphicrelationshipoftwoformsAandB.
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
411
Inthecaseofenantiotropy(Figure8.20a):
Scan1.ThesamplestudiedisthestableformA,whichgivestheendothermicso‐lidphasetransitionABfollowedbythemeltingendothermofformB.
Scan2.ThesamplestudiedisthestableformA,butforkineticreasonsthesolidtransformationABdoesnotoccur.InsteadformAmelts.
Scan3.ThesamplestudiedisthestableformAwhichmelts.FormBcrystallisesfrom the melt with an exothermic peak and form B melts at a highertemperature.
Scan4.ThesamplestudiedisthemetastableformB,whichbecomesstableatatemperature above the transition temperature. An exothermic peakcorresponds to the solid transformationB A, followed by successivetransformationAB,andmeltingofB.
Scan5.The sample studied is the metastable form B. The DSC scan shows itsmeltingendotherm.
Figure8.20.PossibleDSCscansfor2polymorphs.(a)enantiotropy;(b)monotropy
Inthecaseofmonotropy(Figure8.20b):
Scan1.The sample studied is the stable form A, and its melting endotherm isobserved.
Scan2.The sample studied is the metastable form B, which transformsexothermicallyinthesolidstateintothestableformA.FormAmeltsatahighertemperature.
Scan3.The sample studied is themetastable form B, which does not transformintoA,butmeltsendothermically.FromthemeltthestablecrystallineformAappears,withanexothermicpeak,thenAmeltsatahighertemperature.
a b
Heat flow dq/dt
Endo
Heat flow dq/dt
Endo
Temperature
Temperature
Chapter8
412
Similar interpretationsapply to allmethods that involveheating (e.g. hot stageopticalmicroscopy,hotstageinfraredorRamanmicroscopy,temperatureresolv‐edorvariabletemperatureXRD).ItisdifficulttodistinguishbetweenenantiotropyandmonotropyinthecasesofFigure8.20a,Scan5andFigure8.20b,Scan1,aswellasinFigure8.20a,Scan3andFigure 8.20b, Scan 3. The interpretation of theDSC curves is facilitatedbyBurger’senthalpyoffusionrule[27‐28]:ifthehighermeltingformhasthelowermeltingenthalpy,thenbothformsarerelatedenantiotropically.AsdemonstratedinFigure8.21,forabenzisoquinolinehydrochloride[12],themeltingenthalpyofthehighermeltingformBislowerthanthemeltingenthalpyofA.Therefore,thetwo forms are enantiotropically related, with form A being stable below thetransitionpoint.ModificationBishygroscopicandundergoesasolvent‐mediatedtransitiontoformAinalcoholsatambienttemperature.
Figure8.21.Polymorphicbehaviourofabenzisoquinolinehydrochloride.Eachformhasitsmeltingcurve.EnantiotropydemonstratedbytheBurgers’rule.FormAontheleftsidehasameltingpointof304°Candameltingenergyof50kJmol‐1.FormBhasamelting
pointof311°Candameltingenergyof46kJmol‐1[14]
Figure 8.22 shows DSC curves of propyphenazone. Samples from two manu‐facturerswere investigated in our laboratory since the second sample did notcomplywithmeltingrequirements.Anunexpectedlyhighmeltingpointwasnotdue to higher purity, but to the enantiotropic behaviour. The second samplecontainedtracesofahighmelting form.Aslowerheatingrateshowedforbothsamplestwoendotherms.DSCexperimentsallowedthemanufactureinsituofthe
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
413
high melting form, and to characterise it completely including solubility anddissolutionrate[12,13].Forexamplesofkineticeffectsduetopolymorphismandsalts, see references [32,33]. Kinetics also governs the steps of hydration anddehydration in the solid state, giving rise to complex conversion relationships[34‐36],(seeexampleinFigure8.25).
Figure8.22.EffectofheatingrateontheDSCofpropyphenazoneenantiotropicsystem.Batch1and2oftwomanufacturershavedifferentmeltingpoints.Athighheatingrates(20,10,5,or2.5°Cmin‐1)batch1showsonlyonepeak.Batch1isapureform,batch2containsverysmallamountsofhighmeltingformwhichactsasseed.Withslowheating
ratestransformationtothehighmeltingformoccursforbothbatches[12]
8.4.4. Sorptionisothermsandhydrates
Mostdrugsubstancescrystalliseintheformofsolvatesorhydrates.TheDSC/TGcurvesallowustofollowthedesolvationprocess.ItispossibletomeasurewatersorptionisothermsbyTGincontrolledatmospheres.Oftentheinstrumentusedisanautomaticmulti‐vapourgravimetricsorptionanalyser,aso‐called“dynamicvapour system” (DVS), e.g. those made by Surface Measurement Systems Ltd.Figure 8.23 shows such curves for an enantiotropic drug substance whichabsorbs water to form a trihydrate. The desorption occurs with hysteresis,allowingustodefinetherelativehumidityrangeforeachform.Accordingtothecurves, the trihydrate formwould be possible to develop.However, itwas notpossibletomanufactureitasapureformintheprocess.Theenantiotropicform,which was stable at room temperature, could be manufactured and stored intightcontainers[14].
98 100 102 104 106
Manufacturer 1
Manufacturer 2
Temperature, oC
Hea
tfl
ow
En
do
100 101 102 103 104 105
Temperature, oC
a) Heating rate 2.5 C min-1 b) Heating rate 1.2 C min-1
Chapter8
414
Figure8.23.Exampleofawatersorption‐desorptionisothermfortwoenantiotrops
(AandB)andatrihydrateoftheinvestigatedcompound
Figure8.24showstheuseofsorptionisothermmeasurementforasaltselection.Thehydrochloridefirstselectedwastoohygroscopicforeasydevelopment,andtherefore new saltswere studied. TheDSC puritywas determined for stabilitycomparison (Table 8.5). The hydrogen fumarate and hydrogen tartrate wereattractiveduetotheirgoodhygroscopicbehaviour,howeverthestabilityresultsclearly showed that hydrogen tartrate was chemically stable. This exampledemonstratestheadvantageoususeofthermaltechniquesforquickdecisionsinearlydevelopment.
Table8.5.DSCpurityresultsforthestabilitycomparisonofsaltsgiveninFigure8.24.
DSCtimeDSCpurity,%
Hydrogenfumarate
Hydrogenmaleate
Hydrogentartrate
Initial 99.8 99.8 99.9
1week 99.4 nopeak 99.9
Luminousexposure:1200kluxh 99.1 97.6 99.5
Relative humidity, %
Mass change, % of dry m
ass
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
415
Figure8.24. Saltselection.Thehygroscopichydrochlorideisreplacedbythehydrogen
tartrate[18].(a)Dynamicvapoursystem(DVS)curvesofhydrochloride,(b)DVScurvesforhydrogenmaleate,hydrogenfumarateandhydrogentartratesalts
Itisrecommendedthatseveralcyclesofsorptionanddesorptionareperformedwhenahydrate isproduced.Figure8.25shows thekineticeffectof seeds foradrug substance. The anhydrous form is converted to the monohydrate at arelativehumidityofRH>90%.Afterthedesorption,tracesofmonohydratearepresentandthesubstanceabsorbswaterveryfast.Thebehaviourwasalsofoundinstabilitystudiesofbatchesofthedrug[32].
Recentlyintroducedautomaticsystemsbringafasterunderstandingofcomplexhydration and dehydration behaviour, aswell as their kineticswithmonitoredrelativehumidity (RH%). Instruments for researchhave0.1µgsensitivity,andlessthan10mgofsamplecanbeused.Byusingsolventvapours,solvatedformscan be manufactured and studied. These studies are a prerequisite for themicrocalorimetricanalysisofamorphouscontent.
05
1015202530354045505560
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95 100
% Relative Humidity
% W
t. C
han
ge
Critical relarive humidity
a
Ma
ss
up
tak
e,
%
50
40
30
6
20
10
0
5
4
3
2
1
00 10 20 30 40 50 60 70 80 90 100
0 10 20 30 40 50 60 70 80 90 100Relative humidity (RH), %
Hydrochloride
HydrogenmaleateHydrogentartrateHydrogenfumarate
Ma
ss
up
tak
e,
%
Relative humidity (RH), %
b
a
Chapter8
416
Figure8.25.Watersorption‐desorptionisothermsandkinetics.InthefirstcyclethesubstancetakesupwateronlyatRH>90%.Afterthedesorptioncyclethethird
absorptioncycleshowsthetransformationintothemonohydratealreadyat30%RH
8.4.5. Combinedtechniques
8.4.5.1. CombinationofDSCandXRD
XRDinstrumentsareequippedwithheatingcellsandareroutinelyusedinmostresearchlaboratories.X‐raypatternsofpureformsobtained insitucanbeusedformodelling,andinfavourablecases,forcrystalstructuredetermination.Figure8.26exemplifies thecombinationofDSC/XRD foranenantiotropic systemwithheatingandcoolingcurves.Theadvantageofcoupledinstrumentsdevelopedinaresearch laboratory has been demonstrated [37]. The trehalose monohydratedehydration and hydration were studied in a humid atmosphere as anapplicationofanewcommercialinstrumentation[38].
8.4.5.2. Thermogravimetry‐massspectrometry(TG‐MS)andthermogravimetry‐infraredspectroscopy(TG‐IR)
AnexampleofTG‐MSisgivenforcalciumoxalateinFigure8.27,wherewater,COand CO2 are positively identified. Figure 8.28 is an example of the successfulinterpretation of a crystallisation into solvates followed by desolvation to ametastable form.TheDSCandTG‐MSinthis figurecorrespondtothemethanolsolvate. Similar pictures are obtained with other solvates e.g. acetone andethanol.TheDSC/TG/TG‐MSandtemperatureresolvedXRDexperiments,aswellas slurry experiments,were necessary to understand the crystallisation of thisdrugsubstanceandtochangethesolventofcrystallisation[32].
Figure8.29a shows theDSC/TG for aspartamehemihydrate andcorrespondingIR spectra (Figure 8.29b). The first endotherm at around 130 °C is the loss of
12
16
8
4
0
Ma
ss
ch
an
ge
, %
RHRH, %
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
417
water,andthesharpendothermisduetodecompositionandformationofmetha‐nol [14].Solvatescanbesuccessfullycharacterised[39],andquantitative infor‐mationofthespectroscopicsignalispossible[40].
An example is given in Figure 8.30 of the interpretation of the behaviour of amalonate using several combined technologies: DSC, TG, TG‐MS, temperatureresolved XRD and IR. Through drying, themalonic acid can sublimate and the
Figure8.26.UseofcombinedDSC‐XRDforthedetectionofareversibleenantiotropictransitionofapurinederivative;(a)successiveDSCheatingupto120°C(1)cooling(2)andheatingupto140°Cshowingthereversiblephasetransitionandthemelting
(3);(b)reversibletransitionbetween50and125°CfollowedbyXRD
2 / o
Intensity, Arb. units
Heat flow dq /dt Endo
Temperature, oC
1
2
3
a
b
Chapter8
418
base formed [14].Anotherexample, given inFigure8.31,dealswith the lossofwaterfromadrugsubstanceduringdrying.Thedecompositionproductformedwas at first believed to be a new form. DSC/TG/XRD and IR were thensuccessfully used for the identification of the substancewith two enantiotrops[15]. The DSC of the stable form shows an enantiotropic transition. After themeltingofthesecondform,adegradationintothelactamwiththelossofamolarquantityofwaterwasdetectedbyTG‐MSandtemperatureresolvedXRD.TheIR‐heatingcellallowedthestructureofthelactamtobeconfirmed.
Figure8.27.(a)TGcurveofcalciumoxalateand(b)MSsignalsofH2O,COandCO2
12.4%
19.3%
30.0%
100
80
60
5 10 15 20 25 30 35 40
Ma
ss
,%
Time, min.
5 10 15 20 25 30 35 40 Time, min.
Ion
cu
rre
nt,
10
-7A
0.16
0.00
0.08
H2OCO
CO2
40 100 200 300 400 500 600 700 800
a
b
Temperature, oC
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
419
Figure8.28.Identificationofamethanolsolvateinacomplexcrystallisationbehaviour
by TG-MS; (a) DSC curve and (b) TG curve and corresponding MS signal [14]
Figure8.29.UseofTG‐IRforthedetectionofmethanolinthedegradationofaspartame;
(a)TGandDSCcurves,(b)correspondingIRspectra
T G
T G -M S,m = 32
Solva te = > B ’ B ’ => A
40 60 80 100 120 140 160 180 200
40
30
20
Temperature (°C)
40 60 80 100 120 140 160 180 2000 2 4 6 8 10 12 14 16 18
TempTim
DSC
TG
TG-MS m=32 1
0 n
AMa
ss
%
4.8%
Solvate=>B’ B’=>A
Ma
ss
,%
0 2 4 6 8 10 12 14 16 18 Time, min.
TG
DSC
Hea
t Flo
w
E
nd
o
Solvate B’ B’ A
40 60 80 100 120 140 160 180 200 Temperature, oC
a
b
TG-MS m=32
10n
A40 60 80 100 120 140 160 180 200 Temperature, oC
a b
Temperature, oC Wavelenght, cm‐1
Heat flow, m
W
Weight, %
Intensity, A
rb. units
Chapter8
420
a
d e
Figure8.30.Useofcombinedtechniquesfortheinterpretationofthermaleventsofa
malonate.(a)DSCandTGcurves.ThreedifferentDSCpeaksareinterpretedasmelting(1)anddecomposition(2)ofthemalonatefollowedbymeltingofthebase(3);(b)temperatureresolvedXRDshowstheirreversibletransformationintothebase
accordingto(c);(c)XRDpatternsofthefreebaseandmalonate;(d)TG‐MSexperimentindicatestheevolutionofwaterandCO2duringheatingofmalonicacid;
(e)IRspectratakenatdifferenttemperaturesconfirmthepresenceofCO2andthechemicalstructureofthebase[14]
75 125 175 225 275
70
60
50
100
90
80
He
at
flo
w,
mW
En
do
Temperature, oC
Ma
ss
,%
TG
DSC
1
2 3
5 10 15
40 185
2 / o
180175
150 40
b
Base
Malonate at 220 C
5 10 15 20 25 30
Inte
ns
ity,
Arb
. u
nit
s
2 / o
c
2 6 10 14 18 22
40 60 80 100 120 140 160 180 200 220 240 260 280
18.3%
Mas
s,%
Time, min
Inte
nsi
ty,
Arb
. u
nit
sH2O
CO2
Temperature, oC
Tra
nsm
itta
nce
. %
3500 3000 2500 2000 1500 1000 Wavenumber, cm-1
130 oC
165 oC
210 oC
220 oC
250 oC
>250 oC
CO2
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
421
a
b
c d
Figure8.31.Combinedtechniqueselucidatingthedecompositionofanenantiotropicdrugintoalactam[15].(a)DSCcurve;(b)TG‐MSconfirmsthedegradationwithlossofwater;(c)thetemperatureresolvedXRDshowsthe3steps:formA,formBandlactam;(d)IRspectrainheatingcellconfirmtheenantiotropictransitionandshowthechemical
transformation.
Hea
tfl
ow
, mW
E
nd
o
40 60 80 100 120 140 160 180 200
65
55
45
35
25
Temperature, oC
DSC
B A
MeltingA
Lactam+ H20
0 2 4 6 8 10 12 14 16 Time, min. 40 60 80 100 120 140 160 180 Temperature, oC
5n
A
Mass,%
TG-MS m=18
TG- H20
95
90
100
5 8 11 14 17 20 23 26 29
Inte
nsi
ty, A
rb.
un
ist
B
A
lactam
120 oC
150 oC
185 oC
2 / o11001200130014001500160017001800
Wavenumber cm-1
050
100
150
200
Tra
nsm
ittan
ce [
%]
100 C
130
170 C
180 C
186 C
1800 1700 1600 1500 1400 1300 1200 1100Wavenumber, cm-1
100 oC
130 oC170 oC
180 oC
186 oC
Tra
nsm
itta
nce
, %
Chapter8
422
8.4.6. Isothermalmicrocalorimetryandsolutioncalorimetry
8.4.6.1. Microcalorimetry
Thedecreaseintheglasstransitiontemperature,Tg,bywaterandsolvents,istheprinciple behind the microcalorimetric method of amorphous contentdetermination. The substance is subjected to vapours ofwater, or organic sol‐vent, in an isothermal microcalorimeter (Figure 8.32). The heat flow ofcrystallisationwhichisproportionaltotheamorphouscontentismeasured.Thesorption‐desorption isothermpresented inFigure8.33 exemplifies theprocess.The un‐milled sample is not hygroscopic but after micronisation, the powderabsorbswater(cycle2),andanincreaseinmassisobserved.Anabruptdecreaseisobservedincycle3asthedrugcrystallisesandloseswater.Thecorrespondingexothermicenergyofcrystallisationcanthenbemeasured.
Figure8.32.Settingofisothermalcalorimeterforquantitation
ofamorphouscontent[17,21]
a b
Figure8.33.Sorption‐desorptionisotherms(a)beforeand(b)aftermicronisation.
Crystallisationoftheamorphouspartinhumidatmosphere
Figure8.34 showsan exampleof thedeterminationof amorphous content in abatch of micronised substance for inhalation, by using two different solventvapours, and themethodswere validated. The same result is obtained for this
Type: Thermal Activity Monitor,Thermometrics
Sample volume: 3 ml, glass ampoule
Temperature: 20 – 80 oCPrecision: 0.1 % (at 300 W)Baseline stability: 0.2 W (8 h)Humidity control: e.g. 57 % RH
(sat. NaCl‐solution)
Isothermal Microcalorimetry
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
423
batch: 12.9% compared to 12.7 % amorphous content. However, as demon‐stratedinFigure8.34,thetimeofcrystallisationisquitedifferent.Withvapoursfromamixtureofethanolandwater,thecrystallisationisrapid,butthestartofcrystallisation cannot be measured for low amounts of amorphous form. Thismethod can be used in the range 7 ‐ 15% of amorphous content. In order toanalyse lower contents, dimethylformamide (DMF) used as vapour, can actslowly, and themethod has been validated in the range 2 – 30% amorphouscontent.Anautomatic instrumentwith48channels(TAinstruments),allowsustoperformroutineanalysiswithalimitofdetectionatthe1%level.
Figure8.34.Exampleofquantitativevalidatedmethodsforthedeterminationof
amorphouscontentbyisothermalmicrocalorimetry;(a)and(b)microcalorimetriccurvesforabatchwithtwodifferentmethods,(c)automaticisothermalmicrocalorimetric
instrument(TAanalysis),(d)comparisonofcurveswithverylowamorphousformcontent
0.0 0.5 1.0 1.5 2.0 2.5 3.0
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
Hea
t F
low
(m
W)
TIME (hours) 0 1 2 3 4 5 6 7 8
0.0
0.5
1.0
1.5
2.0
2.5
He
at f
low
(m
W)
Time (hours)
Start
(b)Method 1: 12.9%Method 2: 12.7%
0
30
60
90
Time,hou5 100
P,µW Pin[1](t)Pin[2](t)Pin[3](t)Pin[4](t)
2%
1.5%
0.7%
Time, hours
Time, hours Time, hours
Heat flow, mW
Heat flow, mW
Start
DMF, longer analysisrange 2‐30 %
ethanol/water, quick resultsrange 7‐15 %
a b
c d
Chapter8
424
8.4.6.2. Solutioncalorimetry
SolutioncalorimetryhasbeendescribedinUnitedStatesPharmacopeia(USP)forthe determination of the amorphous form, but has also been used forquantitationofpolymorphs[14].Thismethodsupposesthatnoothercrystallineformmayinterfere.Inthecaseofenantiotropy:
Ht=HSA‐HSB (8.9)
whereHSAistheheatofsolutionofformA,andHSBtheheatofsolutionofformB.
Thismethodcanbeusedforpolymorphs,asdemonstratedinFigure8.35foranenantiotropicdrug.ThesameresultsfortheheatoftransitionarefoundbyDSCandsolutioncalorimetry[12,16,18].Solutioncalorimetryisveryhelpfulwhenthesubstancedecomposes onmelting. This approach allowsus to choosebetweenformsandselectthemoststable[14,18].
Figure8.35. Solutioncalorimetry.Determinationoftheheatoftransitionbetween
2enantiotrops[16.]BeforeandafterthebreakoftheampoulecontainingthesubstanceinwatertheinstrumentiscalibratedbyJouleeffect.HeatoftransitionfoundbyDSC:10.4kJmol‐1;Heatoftransitionfoundbysolutionmicrocalorimetry:9.7kJmol‐1
8.5. SOMEEXAMPLESOFAPPLICATIONS
8.5.1. Theselectionoftherightform
The following example, given in Figure8.36, is a situation often found in earlydevelopment.Wereceivedasample,obtainedbyprecipitation,forwhichtheDSCscan exhibits dual melting. By using different heating rates it was possible to
Calibration 1
Calibration 2
Calibration 1
Calibration 2Break
Break
Form A: 8.2 kJ mol-1
Form B: 17.9 kJ mol-1
Time, minutes
Temperature, oC
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
425
calculate the melting enthalpies and it was concluded that the sample is anenantiotropicsystem.Thepolymorphismstudyofslurriesindifferentsolventsofa purer sample gave a third form. According to Burger’s rule, and theequilibrationstudy,Cisthestableform,AandBareenantiotrops,andbotharemonotropstoC.Consequently,formCwasselectedforfurtherstudy[32].
In solid state A B but A and B monotrops to C
Figure8.36. Caseofadrugcandidatewithtwoenantiotropicmetastableformsobtainedinresearchlaboratory.Athirdformwasthermodynamicallystable[32].
Summaryoftheirrelationships.
8.5.2. SensitivityofDSC
Figure8.37dealswithadrugsubstanceforwhichtracesofastableform(formB)actedasacatalystforquicktransformationifthesampleswerenotkeptatverylowtemperatures.DSCprovedmoresensitiveandallowedmonitoring[15,18].
Figure8.37.Exampleofquantitativedeterminationofundesirableformbythemelting
DSCcurve.SensitivityofDSC:tracesofastableformactingasseedsbyagingaredeterminable[15,17]
Form A Melting : 112°C
Enthalpy : 98J/g
Heat
Solvent mediated Solvent mediated
Form B Melting : 117°C
Enthalpy : 90J/g
Form C Melting : 125°C
Enthalpy : 120J/g
Giron, Amer. Pharm. Rev. 8 (2005), 32, 72.
Chapter8
426
8.5.3. Disappearingsolvates
Solvatesareveryoftenformedinthepresenceofvolatilesolvents.Byisolationinthe air they easily transform into anhydrous forms, stable or unstable, inamorphouspowder,orinhydratedforms.Thebestwaytodetectthemwouldbedirectmeasurementinthecrystallisationvessel.Figure8.38showstheresultsofalargenumberofexperimentstounderstandthecomplexsituationfoundwithadrugsubstance.
Figure8.38.Disappearingsolvates.Exampleofexperimentsconducted
toselecttherightform[18]
8.5.4. Selectionofthebestformconsideringthepharmaceuticalenvironment
Water is present in the air and in excipients, and is oftenused inmixtures forcrystallisation purposes. The TG curves of hydrates can be consideredfingerprints. Figure 8.39 is an example of the coexistence ofmonohydrate andtrihydrate in the solvent mixture of a process. The TG curve permitted theevaluation of thepresenceof the trihydrate, since trihydrate andmonohydratehadseparatedstepsforthelossofwater[16,18].Figure8.40isanexampleoftherelationshipsneededtoselectthermodynamicwindowsforhydrates[12].
Crystallisation in ethanol <40 oC form A, >50 oC form BWhich form to be selected?
Burger’s rule? A: one DSC peak B: two DSC peaks with decompositionX‐ray heating cell: B A before melting and decomposition
Slurry experiments form A, form B and mixture A + B at 10, 25, 40, 50 and 60 oC at different times and solvents. Analysis of solids
unstable solvate
ethanol, <40oC
solvate 1:1B A
isopropanol, acetone, <40oC
Thermalanalysisandcalorimetricmethodsappliedtopharmaceuticalsolidforms
427
a b
Figure8.39.DetectionofimpurehydratesbyTG.
(a)TGcurvesofthemonohydrate,thetrihydrateandofanimpuresamplecontainingboth;(b)solubilitybehaviourofthemonohydrateandofthetrihydrate[18]
Figure8.40.Exampleofrelationshipsinacomplexproblemofhydratesandsolvates.
(a)AsdemonstratedontheDSCcurvesthedehydrationoftwopolymorphsofthehydrateoccurdifferently.
A:DSCofanhydrousformIwithtransformationintoanhydrousIII.B:polymorphichydrateAlooseswaterandgivestheanhydrousformI.C:polymorphichydrateBlooseswaterintotheanhydrousformII;
(b)Aschemeoftherelationshipsbetweensolvates,hydratesandanhydrousform
0
5
10
15
20
25
30
35
0 10 20 30 40 50 60
anhydrous
monohydrate
trihydrate
Mas
s, %
Co
nce
ntr
atio
n,m
gm
l-1
Temperature, oC Temperature, oC30 40 50 60 70 80 90
Temperature, oC70 80 90 100 110 120 130 140 150 160
En
do
ther
mic
Solvates
Anhydrous I
Anhydrous III
Solvents
Hydrate A
Hydrate B
Anhydrous II
Moisture
‐H2O
Moisture
a b
Chapter8
428
8.6. CONCLUSION
Inconclusion,thermalanalysisandcalorimetrictechniquesarenecessaryfortheselection and the characterisation of solid forms. They are versatile and offerquickresults.Asexemplified inFigure8.41,characterisationof therelationshipbetweenallformsistheobjectiveofdevelopment.Forthischallengingpurposearange of methods is necessary, and when this is achieved, process analyticaltechnologywillbethefutureforupscaleandmanufacture.
Figure8.41.Relationshipsbetweenthesolidphasesoftetracainehydrochlorideaccordingto[41].Forthestudy,DSC,TGandtemperatureresolvedXRDaswellas
solubilityandslurriesexperimentswereperformed.6cristallineanhydrousformswereidentified,anamorphousform,atetrahydrate,amonohydrateandahemi‐hydrate.Atroomtemperatureonlyanhydrousforms1and5couldbeobtainedforalongperiodof
time.Form1isthestableformandcorrespondstothecommercialquality
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