Desorptioilmanpainefotoionisaatio- ja desorptiosähkösumutusionisaatio-massaspektrometria lipidien analytiikassa

Lipidit ovat rasvaliukoisia kudoksesta peräisin olevia yhdisteitä, joilla on monia eri fysiologisia tehtäviä. Lipidien analyysimenetelmien kehittämien on tärkeää, sillä niiden esiintymistä elimistössä voidaan käyttää biomarkkerina sairauksien diagnostiikassa ja apuna sairauksien kehittymismekanismien tutkimisessa. Lipideihin kuuluu polaarisuudeltaan ja rakenteeltaan hyvin erilaisia yhdisteitä. Niiden massaspektrometria-analytiikassa on aikaisemmin käytetty useita erilaisia ionisaatiomenetelmiä, jotka vaativat näytteen esikäsittelyn ennen analyysia. Desorptiosähkösumutusionisaatio-massaspektrometria (DESI-MS) ja desorptio-ilmanpainefotoionisaatio-massaspektrometria (DAPPI-MS) ovat uusia ionisaatio-menetelmiä, jotka mahdollistavat yhdisteiden analysoinnin suoraan eri matriiseista, kuten kudosnäytteistä, usein ilman esikäsittelyä. DESI-MS soveltuu parhaiten suhteellisen polaaristen yhdisteiden analytiikkaan, kun taas DAPPI:lla voidaan ionisoida myös poolittomia yhdisteitä. DESI-MS:lla on jo aikaisemmin analysoitu erilaisia lipidejä, kun taas DAPPI-MS:lla on aikaisemmin analysoitu vain steroideja. DAPPI- ja DESI-MS:lla tutkittiin erilaisten lipidien (fosfolipidit, triglyseridit, rasvahapot, rasvaliukoiset vitamiinit ja steroidit) ionisoitumista. Molemmilla menetelmillä optimoitiin standardiyhdisteille mittausolosuhteet. Lipidejä analysoitiin myös suoraan farmaseuttisista valmisteista. DAPPI:n ja DESI:n soveltuvuudessa erilaisten lipidien ionisoimiseen oli jonkin verran eroja. DAPPI toimi hyvin varsinkin poolittomampien lipidien, eli triglyseridien, steroidien, vitamiinien ja rasvahappojen ionisaatiossa, mutta huonosti hieman polaarisempien ja herkästi hajoavien fosfolipidien ionisaatiossa. Fosfolipidit fragmentoituivat DAPPI-ionisaatiossa, eikä moolimassatiedon sisältävää ionia saatu näkyviin. DESI puolestaan toimii hyvin fosfolipidien ionisoimisessa ja melko hyvin myös muiden tutkittavien lipidien ionisoimisessa, lukuunottamatta kaikkein poolittomimpia lipidejä. Uutta tietoa tutkimuksessa saatiin varsinkin DAPPI:n soveltuvuudesta erilaisten lipidien analytiikkaan. Tulosten perusteella voidaan sanoa, että DAPPI toimii yhtä hyvin tai jopa DESI:a paremmin useiden eri lipidien analytiikkassa. Menetelmää tulisi kuitenkin kehittää edelleen, jotta fosfolipidien, jotka ovat elimistön tärkeä lipidiryhmä, analysointi onnistuisi DAPPI:lla. Työssä ei analysoitu lipidejä suoraan kudosnäytteestä, joten DAPPI:n soveltuvuudesta lipidien analysointiin suoraan kudosnäytteistä ei voida tehdä johtopäätöksiä tämän työn perusteella.

Biocompatibility and biofunctionalization of mesoporous silicon particles

Several of the newly developed drug molecules experience poor biopharmaceutical behavior, which hinders their effective delivery at the proper site of action. Among the several strategies employed in order to overcome this obstacle, mesoporous silicon-based materials have emerged as promising drug carriers due to their ability to improve the dissolution behavior of several poorly water-soluble drugs compounds confined within their pores. In addition to improve the dissolution behavior of the drugs, we report that porous silicon (PSi) nanoparticles have a higher degree of biocompatibility than PSi microparticles in several cell lines studied. In addition, the degradation of the nanoparticles showed its potential to fast clearance in the body. After oral delivery, the PSi particles were also found to transit the intestines without being absorbed. These results constituted the first quantitative analysis of the behavior of orally administered PSi nanoparticles compared with other delivery routes in rats. The self-assemble of a hydrophobin class II (HFBII) protein at the surface of hydrophobic PSi particles endowed the particles with greater biocompatibility in different cell lines, was found to reverse their hydrophobicity and also protected a drug loaded within its pores against premature release at low pH while enabling subsequent drug release as the pH increased. These results highlight the potential of HFBII-coating for PSi-based drug carriers in improving their hydrophilicity, biocompatibility and pH responsiveness in drug delivery applications. In conclusion, mesoporous silicon particles have been shown to be a versatile platform for improving the dissolution behavior of poorly water-soluble drugs with high biocompatibility and easy surface modification. The results of this study also provide information regarding the biofunctionalization of the THCPSi particles with a fungal protein, leading to an improvement in their biocompatibility and endowing them with pH responsive and mucoadhesive properties.

Importance of COMT in the regulation of prefrontal dopamine

The prefrontal cortex (PFC), located in the anterior region of the frontal lobe, is considered to have several key roles in higher cognitive and executive functions. In general, the PFC can be seen as a coordinator of thought and action allowing subjects to behave in a goal-directed manner. Due to its anatomical connections with a variety of cortical and subcortical structures, several neurotransmitters, including dopamine, are involved in the regulation of PFC activity. In general, the majority of released dopamine is cleared by the dopamine transporter (DAT). In the PFC however, the number of presynaptic DAT is diminished, emphasizing the relative importance of catechol-O-methyltransferase (COMT) in dopamine metabolism. As a result, the role of COMT in the etiology of psychotic disorders is under constant debate. The present study investigated the role of COMT in prefrontal cortical dopamine metabolism by different neurochemical methods in COMT knockout (COMT-KO) mice. Pharmacological tools to inhibit other dopamine clearing mechanisms were also used for a more comprehensive and collective picture. In addition, this study investigated how a lack of the soluble (S-) COMT isoform affects the total COMT activity as well as the pharmacokinetics of orally administered L-dopa using mutant mice expressing only the membrane-bound (MB-) COMT isoform. Also the role of COMT in striatal and accumbal dopamine turnover during Δ9-tetrahydrocannabinol (THC) challenge was studied. We found markedly increased basal dopamine concentrations in the PFC, but not the striatum or nucleus accumbens (NAcc), of mice lacking COMT. Pharmacological inhibition of the noradrenaline transporter (NET) and monoamine oxidase (MAO) elevated prefrontal cortical dopamine levels several-fold, whereas inhibition of DAT did not. The lack of COMT doubled the dopamine raising effects of NET and MAO inhibition. No compensatory expression of either DAT or NET was found in the COMT-KO mice. The lack of S-COMT decreased the total COMT activity by 50-70 % and modified dopamine transmission and the pharmacokinetics of exogenous Ldopa in a sex and tissue specific manner. Finally, we found that subsequent tolcapone and THC increased dopamine levels in the NAcc, but not in the striatum. Conclusively, this study presents neurochemical evidence for the important role of COMT in the PFC and shows that COMT is responsible for about half of prefrontal cortical dopamine metabolism. This study also highlights the previously underestimated proportional role of MB-COMT and supports the clinical evidence of a gene x environment interaction between COMT and cannabis.