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Optimizacija tabletiranja na osnovi študija plastično-elastičnih lastnosti delcev : doktorska disertacija
ID Zupančič-Božič, Damjana (Avtor), ID Vrečer, Franc (Mentor) Več o mentorju... Povezava se odpre v novem oknu

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Izvleček
Direktno tabletiranje formulacij z visokim deležem učinkovine pogosto spremljajo težave, povezane s slabimi kompaktibilnimi lastnostmi in posledično z nizko trdnostjo tablet. V študiji smo preučevali realno formulacijo z visokim deležem učinkovine (75 %) iz skupine makrolidnih antibiotikov ter mikrokristalno celulozo (15 %) kot suhim vezalcem. Preučevali smo obnašanje treh sistemov: sistema z direktnim tabletiranjem in tabletiranjem predhodno granulirane zmesi prahov z dvema metodama suhega granuliranja (kompaktiranje z valjastim kompaktorjem in briketiranje na tabletirki). Direktno tabletiranje te formulacije je bilo namreč povezano z veliko tendenco nastajanja kapic (CC). Pri tabletiranju obeh suho granuliranih sistemov je prišlo do povečanja velikosti delcev, izboljšanja kompaktibilnosti, povečanja trdnosti tablet in signifikantnega zmanjšanja nastajanja kapic v primerjavi z direktnim tabletiranjem. Z vidika lastnosti zmesi in končnih tablet ni bilo bistvenih razlik med kompaktiranjem in briketiranjem. Metoda suhe granulacije ni ključna za proces tabletiranja, pomembni pa so vplivi pogojev pri kompaktiranju na lastnosti tablet, zlasti tlak kompaktiranja. Prevladujoči mehanizem zmanjševanja volumna makrolidnega antibiotika med stiskanjem je fragmentacija delcev, kar smo potrdili s Hecklovo analizo, testom občutljivosti na drsljivec in elektronsko mikroskopijo. Poleg fragmenatcije je v manjši meri izražena tudi plastična deformacija, ki se pojavlja vzporedno oz. takoj za fragmentacijo delcev. Ker je v formulaciji tudi 15% mikrokristalne celuloze, ki se tipično plastično deformira, lahko del plastične deformacije pripišemo tudi učinku MCC. Hecklova analiza je pokazala intenzivno prerazporejanje delcev v začetni fazi stiskanja zlasti pri zmesi za direktno tabletiranje, medtem ko je pri obeh suho granuliranih sistemih to nekoliko manjše, saj so delci v granulah v precejšnji meri že urejeni in fiksirani. Kritični tlak tabletiranja (Py) direktno tabletiranega sistema je nižji kot Py obeh suho granuliranih sistemov, kar pomeni nižjo plastičnost suho granuliranih sistemov. S to ugotovijo nismo mogli razložiti bistveno nižje tendence nastajanja kapic po suhem granuliranju v primerjavi z direktnim tabletiranjem, kar pomeni, da poglavitni vzrok ni v spremenjenih plastično–elastičnih lastnostih delcev oz. v mehanizmu deformacije. Hecklova analiza torej ni zaznala vseh elementov, ki lahko prispevajo k trdnosti tablet in CC, zato je njene rezultate potrebno pazljivo interpretirati zlasti takrat, kadar med stiskanjem pride do strukturnih sprememb snovi.Prevladujoči tip vezi, ki se vzpostavijo med delci preučevane formulacije v času stiskanja, so medmolekularne privlačne sile med delci (van der Waalsove vezi). Poglavitni element, ki prispeva k signifikantnemu zmanjšanju tendence nastajanja kapic in povečanju trdnosti tablet pri obeh suho granuliranih sistemih, pripisujemo strukturni spremembi (amorfizaciji) makrolidnega antibiotika, do katere pride zaradi fizične obremenitve med suhim granuliranjem, ki ima za posledico povišanje površinske proste energije in signifikantno povečanje jakosti vezi med delci, ki se lahko zoperstavijo elastični relaksaciji. Amorfizacija makrolidnega antibiotika je večja v primeru večje fizične obremenitve snovi. Višji tlak glavnega stiskanja pri tabletiranju najbolj vpliva na nižjo tendenco nastajanja kapic in na višjo trdnost tablet pri vseh treh sistemih (direktno tabletiranje, kompaktiranje, briketiranje), precej manjši vpliv pa ima hitrost tabletiranja. Vpliva predtlaka na trdnost tablet nismo dokazali, vpliva pa na zmanjšanje tendence nastajanja kapic. Koeficient nastajanja kapic pri suho granuliranih sistemih ni tako odvisen od sile stiskanja kot pri direktnem tabletiranju. Na podlagi rezultatov energije plastično–elastične deformacije delcev smo ugotovili, da je neto energija med stiskanjem (NETW) največja pri sistemu za direktno tabletiranje, sledita ji kompaktirana ter nato briketirana zmes. Delež elastične deformacije je pri direktnem tabletiranju manjši kot pri obeh suho granuliranih sistemih. Ti rezultati niso v skladu s pričakovanji, da bo višji CC povezan z višjo stopnjo elastične deformacije. S tem potrjujemo pomanjkljivost te metode, za katero v literaturi tudi drugi avtorji opozarjajo, da upošteva le deformacijske spremembe, zanemarja pa interakcije med delci, ki prav tako lahko vplivajo na energijske spremembe. Na razlike v NETW torej ne vplivajo samo deformacijske razlike med sistemi, ampak tudi razlike v interakcijah zaradi različne stopnje amorfizacije, kar je prišlo do izraza tudi v našem primeru. NIR je ustrezna metoda za določanje trdnosti tablet. Model, ki je upošteval rezultate vseh treh sistemov, ima zadovoljivo napovedno moč in predstavlja uspešno alternativo klasični diametralni metodi določanja trdnosti tablet ter pomeni korak naprej pri implementaciji sodobnega pristopa PAT (Process Analytical Technology) v praksi na področju farmacevtske industrije. Metode umetne inteligence – mehko modeliranje in umetne nevronske mreže so se izkazale kot zelo primerne za študij in optimizacijo tabletiranja v industrijskem merilu. Obe metodi sta pri vplivu na CC izpostavili pomen velikosti delcev oz. tip zmesi (direktno tabletiranje oz. suho granuliranje) ter Glavni tlak tabletiranja. Z obema metodama smo dobili zelo primerljive rezultate tako v prepoznavanju vplivov procesnih parametrov tabletiranja in lastnosti zmesi na kakovost tablet kot tudi pri predlogih optimizacije nastavitve tabletiranja tako, da imajo tablete ob maksimalni hitrosti tabletiranja minimalni CC in minimalno variiranje mase in trdnosti tablet.

Jezik:Slovenski jezik
Ključne besede:tabletiranje, farmacevtski prahi, Hecklova analiza, nevronske mreže
Vrsta gradiva:Doktorska disertacija
Tipologija:2.08 - Doktorska disertacija
Organizacija:FFA - Fakulteta za farmacijo
Kraj izida:Ljubljana
Založnik:[D. Zupančič Božič]
Leto izida:2008
Št. strani:183 f.
PID:20.500.12556/RUL-127024 Povezava se odpre v novem oknu
UDK:66.06
COBISS.SI-ID:2274673 Povezava se odpre v novem oknu
Datum objave v RUL:13.05.2021
Število ogledov:1601
Število prenosov:92
Metapodatki:XML DC-XML DC-RDF
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Sekundarni jezik

Jezik:Angleški jezik
Naslov:Optimization of tableting based on studying plasto-elastic particle deformation
Izvleček:
Direct tableting of formulations containing high percent of active ingredient is often accompanied with poor compactibility properties and consequently low tablet strength. The real formulation containing high percent of active ingredient (75%) from the macrolide antibiotic group and microcrystalline cellulose (15%) as dry binder was studied. The aim of this study was to investigate the three systems: direct tableting system and two dry granulated systems (roller compaction and slugging). Direct tableting of this formulation revealed a poor powder flowability properties and pronounced capping tendency. Both dry granulated systems caused increasing of particle size, better compactibility, higher tablet strength and significant reduction in capping tendency compared to direct tableting. There were no significant differences in tablet properties between roller compaction and slugging. This can indicate that the type of dry granulation is not crucial for tableting, however the parameters during dry granulation, such as compaction pressure, influence on tablet properties. The main volume reduction mechanism for macrolide antibiotic is fragmentation which was confirmed by Heckel analysis, the lubricant sensitivity test, and SEM images. Some plastic deformation also takes place beside fragmentation parallel and after particle fragmentation. Part of plastic deformation can be attributed also to the microcrystalline cellulose which is the typical plastic deforming material. The results of Heckel analysis indicates intensive particle rearrangement at low compaction pressures which was the most expressed at direct tableting system. Lower particle rearrangement at both dry granulated systems can be attributed to already better settlement and partial fixation of particles in the granules. The yield pressure (Py) of the direct tableting system is lower than the Py of dry granulated systems, which exhibit the lower plasticity of dry granulated systems. These findings do not explain the lower capping tendency of dry granulated systems compared to direct tableting which indicate that change of deformation mechanism or plastic-elastic particle properties is not the main mechanism responsible for lower capping at dry granulated systems. It is obvious that Heckel analysis does not perceive all elements which can attribute to tablet hardness and capping (CC), so it's results must be interpreted with caution, especially when structural changes of material can occur during compression. The main bonding mechanism between particles is attributed to the long distance intermolecular bonds (van der Waals) due to the intensive amorphisation of macrolide antibiotic that occurs due to the physical load during dry granulation. Amorphization leads to a significant increase in surface free energy and consequently stronger long-distance bonding between particles, which is able to withstand the elastic relaxation during decompression and therefore reduce the capping problem. This is considered as a crucial factor which is responsible for reducing capping incidence at dry granulated systems. The level of macrolide antibiotic amorphisation increases with increasing physical load during the process. The biggest influence on lower CC and higher tablet strength at all three systems (direct tableting, roller compaction, slugging) in the group of process parameters at tableting has higher main tableting pressure, while tableting speed has minor effect. The influence of precompression on tablet strength was not evidenced, but it can lead to lower CC. Capping incidence is not so much influenced of main tableting pressure at dry granulated systems as it is at direct tableting system.Based on studying energy differences for plastic-elastic particle deformation, it can be concluded that net energy (NETW) is the highest at direct tableting, followed by roller-compacted and then slugged system. The energy fraction for elastic deformation is lower at direct tableting system compared to both dry granulated systems. These findings are not in accordance to expectations, while higher CC is normally in a correlation to higher elastic deformation energy. This statement confirms the deficiencyof this method, which was pointed out also by other authors, which is that this method considers only deformation differences and neglects the possibility of particle interactions which can significantly influence on energy consumption. The differences in NETW in studied formulation are caused by deformation differences and also by particle interactions which are in our system very significant due to different level of amorphisation. NIR was found as an appropriate method for tablet strength determination. The reference model, which considered the results of all three systems, express satisfying level of certainty of anticipating and represent effective alternative to a classical diametral method for tablet strength determination and step forward in the implementation of contemporary approach, such us PAT (Process Analytical Technology) is, into pharmaceutical industry practice. Artificial intelligence methods - fuzzy logic and artificial neural network are very suitable and successful methods for studying and optimization of tableting process in industrial scale. Both methods stressed the impact of particle size and powder type (direct tableting or dry granulation) and main tableting pressure as crucial factors affecting capping incidence. Both methods have suitable and very comparable results such us identification of significant process parameters of tableting and powder properties, which have an impact to tablet quality and in optimization of process parameters setting in order to get the optimal outcome - no capping incidence, minimal deviation of tablet mass and hardness values at maximal tableting speed.


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