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Elektrokemijski encimski biosenzor v mikrofluidnem sistemu
ID Lokar, Nina (Avtor), ID Vrtačnik, Danilo (Mentor) Več o mentorju... Povezava se odpre v novem oknu

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Izvleček
V disertaciji je predstavljen razvoj elektrokemijskega encimskega biosenzorja na čipu za merjenje glukoze ali eserina kot inhibitorja acetilholinesteraze (AChE). Za izdelavo in karakterizacijo tovrstnega senzorja potrebujemo interdisciplinaren pristop. Združiti je treba znanja elektrokemije, encimske kinetike in mikrofluidike. Glavne prednosti biosenzorjev so merjenje na izbrani lokaciji in ob izbranem času. Uporaba in postopki analize so poenostavljeni, zato se ne potrebuje posebej izučenega osebja. Biosenzorje lahko uporabimo tudi za preliminarne analize, pred izvedbo zahtevnejših in dragih analiz. Kot nova eksperimentalna tehnika pa se v zadnjem obdobju uporablja mikrofluidika, ki omogoča nadgradnjo biosenzorskih sistemov. Dodana vrednost je v uporabi izrazito majhnih količin vzorca in reagentov, možnost izvedbe več različnih eksperimentov hkrati in v kratkem času, možnost avtomatizacije eksperimentov in možnost hitrega prilagajanja števila procesnih enot. Delovanje biosenzorja temelji na biokemijskih in fizikalnih procesih, ki jih lahko opišemo s transportom analita v mikrokanalu, encimsko kinetiko in kronoamperometrijo. Fenomene sem združila v osnovnem modelu na primeru biosenzorja, ki je osnovan na encimu pirolokinolinski kinon-glukoza dehidrogenaza B (PQQ-GdhB). Sistem je rešen numerično z uporabo diferenčne metode za aproksimativno reševanje parcialnih diferencialnih enačb. Rešitev je odziv senzorja na različne koncentracije glukoze. V svojem delu poročam o dveh izvedbah eksperimentov – biosenzor v rezervoarju in biosenzor v mikrofluidnem sistemu. Poleg tega je senzor elektrokemijski. Kot pretvorniški del biosenzorja smo imeli tri-elektrodni sistem. V primeru biosenzorja v rezervoarju je bila delovna elektroda (WE) zlata tankoplastna, pomožna elektroda (CE) platinasta žička, ki je bila ovita okoli referenčne elektrode (RE) – miniaturne Ag/AgCl v KCl. V primeru biosenzorja v mikrofluidnem sistemu, pa so bile vse tri elektrode tankoplastne. Preklop med pristopoma se lahko izvede v nekaj minutah, saj je osnovni čip z WE na stekleni podlagi enak. Za prvi način so značilne statične meritve, za drugi pa poleg statičnih tudi dinamične. Biosenzor v rezervoarju sem uporabila za optimizacijo ključnih korakov pri razvoju biosenzorja, kot je ocena čistosti tankoplastnih zlatih elektrod, določitev ustrezne metode nanašanja mešanega enosloja samoorganiziranih molekul (SAM), pa tudi za določanje stabilnosti in shranjevanja biosenzorja. Poleg različnih eksperimentalnih načinov sem uporabila tudi t.i. velike in majhne elektrode. Pri velikih elektrodah je premer WE enak 3,0 mm, pri majhnih pa 0,8 mm. V primeru mikrofluidnega biosenzorja sem uporabila tudi mikrokanale, katerih oblike so bile prilagojene glede na oblike elektrod. Dolžina in višina sta bili 19,5 mm in 100 m za obe elektrodi. Za večje elektrode so bili kanali široki 6,7 mm, za manjše pa 1,2 mm. Tankoplastne elektrode so bile izdelane po standardnih postopkih naprševanja tankih plasti, fotolitografskih postopkih in postopkih jedkanja. Poleg zlate WE in CE, smo izdelali tudi RE Ag/AgCl, ki smo jo izdelali po kemijskem in elektrokemijskem postopku. Najbolj primeren način za nadaljni razvoj biosenzorja se je izkazala metoda s kapljičnim nanosom FeCl3, pri kateri se zgornje plasti srebrne elektrode pretvorijo v AgCl plast. Začetni korak pri izdelavi zanesljivega elektrokemijskega biosenzorja pa je poleg izdelave elektrod efektivno čiščenje le teh. Preizkusili smo kemijsko čiščenje z raztopino »piranhe«, elektrokemijsko čiščenje z žvepleno kislino in čiščenje elektrod s kisikovo plazmo. S prilagojenimi parametri se je slednje izkazalo kot najprimernejše za naš biosenzor, saj omogoča čisto površino z najmanjšo degradacijo nanesene plasti Ag/AgCl. Indikatorji čistosti so bili: potencialna razlika med katodnim in anodnim vrhom cikličnega voltamograma po čiščenju je bila 90 mV, vrhovi redukcije in oksidacije cikličnih voltamogramov so linearno sledili kvadratnemu korenu hitrosti preleta, količnik vrhov anodnega in katodnega toka pa je bil v povprečju enak 0,98. Poleg tega smo pri tankoplastnih elektrodah preizkušali tudi možnosti nanostrukturiranja WE, z namenom večje efektivne površine, s tem pa visoke občutljivosti. Za nanostrukturiranje smo uporabili HAuCl4 in NH4Cl in pulzne amperometrične tehnike. Izdelane nanostrukture smo opazovali z vrstično elektronsko mikroskopijo. Opazili smo igličaste skupke v velikosti 10 mm, z velikostjo posameznih iglic 500 nm. Efektivno površino elektrode, določeno s pomočjo ciklične voltametrije in Randles-Ševčik-ove enačbe, smo z nanostrukturiranjem uspeli povečati za 41%. Vsi nadaljni koraki izdelave biosenzorja so bili izvedeni samo na planarnih elektrodah. Prepoznavni del biosenzorja je v primeru detekcije glukoze PQQ-GdhB in v primeru detekcije eserina AChE. PQQ-GdhB je na zlato elektrodo imobiliziran s pomočjo 6-merkapto-1-heksanol (6-MCH) in 11-merkaptundekanojska kislina (11-MUA), ter 1-etil-3-karbodiimid hidroklorid (EDC) in sulfo-N-hidroksisulfosucinimid (S-NHS). AChE je na zlato elektrodo imobiliziran s pomočjo cisteamina in glutaraldehida. Za imobilizacijo encima na elektrodo sem uporabila dva načina. Enostavnejši način je potapljanje celotnega elektrodnega čipa v raztopine. Postopek je nezahteven in ne potrebuje dodatnih komponent, vendar ni selektiven in je počasen. Razvit način je mikrokontaktno tiskanje, ki se izvede s t.i. štampiljko iz polidimetilsiloksan-a (PDMS). Pri tem je depozicija molekul lokalna, samo na WE. Poleg tega se čas depozicije skrajša na nekaj minut. Prednost je tudi, da v kasnejših korakih izdelave mikrofluidnega biosenzorja omogoča in situ imobilizacijo, t.j. imobilizacija encima znotraj mikrokanala, kjer je biosenzor pozicioniran. Ta korak se izvede tik pred uporabo biosenzorja. Na ta način tudi ohranimo biološko aktivnost encima v največji možni meri. Učinkovitost izboljšane metode smo preverili elektrokemijsko in opazili zelo dobro pokritost WE z minimalno kontaminacijo RE in CE. Mikrofluidni del biosenzorja je izdelan po standardnih fotolitografskih postopkih, postopkih jedkanja in postopkih t.i. mehke litografije z uporabo elastomera PDMS. Mehanizem delovanja PQQ-GdhB biosenzorja temelji na oksidaciji glukoze, pri čemer se glukoza ob GdhB spremeni v glukonolakton, ob tem pa se odcepita dva elektrona, ki nato preideta na kofaktor PQQ, od tam pa na mediator. Le ta ponese elektrona do elektrode, kjer jih kronoamperometrično detektiramo. Pomagamo si lahko tudi s ciklično voltametrijo. Mehanizem delovanja AChE biosenzorja pa temelji na hidrolizi acetiltioholin klorid (ATCl). Produkt reakcije je tioholin klorid (TChCl), ki odda elektron mediatorju, le ta ga prenese do elektrode. Ker pa nas zanima koncentracija inhibitorja, ki inhibira encim, določimo inhibicijo z izmerjenim signalom v odsotnosti in prisotnosti eserina. Eksperimenti kažejo, da ima izdelan mikrofluidni elektrokemijski PQQ-GdhB biosenzor merilno območje do 10 mM koncentracije glukoze, linearno območje je do 200 M. Spodnja meja detekcije je pri tem 30 M. Biosenzorski odziv sledi Michaelis-Menten-ovi kinetiki. Michaelisova konstanta je določena kot 3,0 mM in 1,5 mM v primeru velikih in majhnih elektrod. Občutljivost biosenzorja v linearnem delu je 0,79 nA/M/mm2 v primeru pretoka 20 L/min. Ocenili smo tudi stabilnost razvitega biosenzorja – po 11 dneh se je signal zmanjšal za približno 45%. Preliminarne meritve AChE biosenzorja, ki smo jih izvedli samo v rezervoarju, kažejo, da kronoamperometrični signal kot odziv na različne koncentracije glukoze sledi Michaelis-Mentenovi kinetiki, z Michaelisovo konstanto 2,6 mM. Pri tem je merilno območje prav tako zgoraj omejeno na 10 mM koncentracijo ATCl. Po izpostavitvi biosenzorja 25 M eserinu za 10 min je bila ugotovljena 70% inhibicija encima. Reaktivacija inihbiranega AChE je bila določena kot 0,016 min-1. Izmerjeni parametri so primerljivi z literaturo. Razvit pristop in situ imobilizacije encima se lahko skupaj s celotnim razvojem mikrofluidnega biosenzorja, ki je predstavljen v disertaciji, široko uporabi, npr. z drugimi biološkimi prepoznavnimi elementi. V osnovi je glukozni biosenzor zasnovan predvsem za spremljanje glukoze v farmacevtskih procesih, zato tudi nadaljna nadgradnja ponuja pot do neprekinjenega in časovno neodvisnega zaznavanja. Na drugi strani, je AChE biosenzor razvit z mislijo uporabe v biomedicini. Ob zamenjavi ali dodajanju še drugih gradnikov pa se lahko mikrofluidni sistem prilagodi še za druge aplikacije in področja. Sistem bi lahko uporabili tudi na področjih medicinske diagnostike, farmacije, prehrambene industrije, ekologije, varnosti in tudi še širše.

Jezik:Slovenski jezik
Ključne besede:biosenzor na čipu, elektrokemijski biosenzor, encimska in situ imobilizacija, tankoplastna referenčna elektroda, nanostrukturiranje elektrode, fizikalni model biosenzorja, AChE biosenzor, glukozni biosenzor
Vrsta gradiva:Doktorsko delo/naloga
Organizacija:FE - Fakulteta za elektrotehniko
Leto izida:2023
PID:20.500.12556/RUL-151623 Povezava se odpre v novem oknu
COBISS.SI-ID:169718019 Povezava se odpre v novem oknu
Datum objave v RUL:13.10.2023
Število ogledov:928
Število prenosov:78
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Sekundarni jezik

Jezik:Angleški jezik
Naslov:Electrochemical enzyme biosensor in microfluidic system
Izvleček:
This thesis presents the development of an electrochemical enzyme biosensor-on-a-chip for the measurement of glucose or eserine as an acetylcholinesterase (AChE) inhibitor. The design and characterisation of such a sensor requires an interdisciplinary approach. It is necessary to combine knowledge of electrochemistry, enzyme kinetics and microfluidics. The main advantages of biosensors are that we can measure at the location and time of our choice. Device use and analysis procedures are simplified, so no specially trained personnel are required. Biosensors can also be used for preliminary analyses, prior to more complex and expensive analyses. Microfluidics has been added as an experimental technique that allows the upgrading of biosensor systems. The added value lies in the use of extremely small sample and reagent volumes, the possibility to perform several different experiments simultaneously and in a short time, the possibility to automate experiments and the possibility to quickly adjust the number of process units. Biosensor operation can be described by biochemical and physical processes such as analyte transport in the microchannel, enzyme kinetics and chronoamperometry. I have combined these phenomena in a basic simulation model using the pyrroloquinoline quinone-glucose dehydrogenase B (PQQ-GdhB) biosensor as an example. The system of equations is solved numerically using the differential method for the approximative solving of partial differential equations. Model output is the response of the sensor to different glucose concentrations. In my work, I report on two experimental designs of biosensors – a biosensor in a reservoir and a biosensor in a microfluidic system. In both cases the sensor is electrochemical. A typical three-electrode system was used. In the case of the biosensor in the reservoir, the working electrode (WE) was a thin-film gold electrode, the counter electrode (CE) was a platinum wire wrapped around a reference electrode (RE) which was a miniature Ag/AgCl in KCl. In the case of the biosensor in the microfluidic system, all three electrodes were thin film - gold WE and CE with Ag/AgCl RE. Switching between the two approaches can be done in a few minutes, as the fabricated chip is identical in both cases. Measurements with the biosensor in a reservoir are static, while the biosensor in a microfluidic system also allows for dynamic measurements in addition to static ones. The biosensor in the reservoir was used to optimise key steps in the biosensor development, such as assessing the purity of the thin-film gold electrodes, determining the appropriate deposition method for the mixed monolayer of self-assembled molecules (SAM), as well as determining the stability and shelf life of the biosensor. In addition to the two configurations, I have also used so-called large and small electrodes. The large electrodes have a WE diameter of 3.0 mm and the small electrodes have a diameter of 0.8 mm. CE and RE are also shrunk by a similar amount. Additionally, in the case of the microfluidic biosensor, microchannels' shapes have been adapted to the electrode shapes. The length and height of the channel were 19.5 mm and 100 m, respectively, for both electrode sizes. For the larger electrodes the channels were 6.7 mm wide while the smaller ones had 1.2 mm wide channels. The thin-film electrodes were fabricated using standard sputtering, photolithography and etching processes. In addition to the gold WE and CE, an Ag/AgCl RE was also produced by chemical and electrochemical processes. The most suitable method for further development of the biosensor turned out to be the FeCl3 drop-casting method, where the top layers of the silver electrode are converted into an AgCl layer. Afterfabrication of the electrodes, efficient cleaning of the electrodes is required for a reliable and a sensitive biosensor. We have cleaned the electrodes in three different ways: chemical cleaning with a solution of »piranha«, electrochemical cleaning with sulphuric acid in presence of current and cleaning with oxygen plasma. The latter method proved to be the most suitable for our biosensor, offering clean surface with the least degradation of the deposited Ag/AgCl layer. Indicators of electrode cleanliness and reversibility of the reaction were: the potential difference between the cathode and anode peak of the cyclic voltammogram after cleaning was 90 mV, the reduction and oxidation peaks of the cyclic voltammograms followed linearly the square root of the scan rate, and the ratio of the anode and cathode peak currents was on average equal to 0.98. In addition to planar electrode construction, we have also tested the potential of nanostructuring the thin film WE to increase the effective surface area and thus the sensitivity. HAuCl4 and NH4Cl and pulsed amperometric techniques were used for nanostructuring. The fabricated nanostructures were observed by in-line electron microscopy. Needle-like aggregates of 10 mm size were observed, with individual needles of 500 nm. The effective surface area of the electrode, determined by cyclic voltammetry and the Randles-Ševčik equation, was increased by 41% by nanostructuring. However, all the further steps of biosensor construction were performed only on the planar electrodes. The recognition element of the biosensor is PQQ-GdhB in the case of glucose detection and AChE in the case of eserine detection. PQQ-GdhB is immobilised on the gold electrode by 6-mercapto-1-hexanol acid (6-MCH) and 11-mercaptoundecanoic acid (11-MUA), and 1-ethyl-3-carbodiimide (EDC) and sulfo-N-hydroxysulphosuccinimide (S-NHS). AChE is immobilised on the gold electrode by cysteamine and glutaraldehyde. I compared two methods to immobilise the enzyme on the electrode. The simpler way is to immerse the whole electrode chip in the solutions. The process is simple and does not require additional components, but it does not offer selective deposition and it is slow. A more advanced method is micro-contact printing, which is performed with a polydimethylsiloxane (PDMS) stamp. Here, the deposition of the molecules is local, only on the WE. In addition, the deposition time is reduced to few minutes. Local deposition also has the advantage of allowing in situ immobilisation, i.e. immobilisation of the enzyme within the microchannel where the biosensor is positioned, in the later steps of the microfluidic biosensor fabrication. Enzyme can be immobilized immediately before the biosensor is used. In this way, the biological activity of the enzyme is also preserved as much as possible. The performance of the improved selective deposition method was verified electrochemically, very high coverage of the WE with minimal RE and CE contamination was observed. The microfluidic part of the biosensor is fabricated by the standard photolithography, etching and soft lithography processes using PDMS elastomer for the channel walls. PQQ-GdhB biosensor is based on the oxidation of glucose, whereby the glucose is converted to gluconolactone in the presence of GdhB. Reaction generates two electrons that are observable products, which are then transferred to the PQQ cofactor and from there to the mediator. The latter carries the electrons to the electrode where they are detected chronoamperometrically or by cyclic voltammetry. Meanwhile, the mechanism of the AChE biosensor is based on the hydrolysis of acetylthiocholine chloride (ATCl). The product of the reaction is thiocholine chloride (TChCl), which gives an electron to the mediator. Electrons are then transfered to the electrode. However, since we are interested in the concentration of the inhibitor that inhibits the enzyme, we determine the inhibition by the measured signal in the absence and presence of eserine. Experiments show that the microfluidic electrochemical PQQ-GdhB biosensor has a measurement range of up to 10 mM glucose concentration, with a linear range of up to 200 M. The lower limit of detection is 30 M. The biosensor response follows Michaelis-Menten kinetics. The Michaelis constant is defined as 3.0 mM and 1.5 mM in the case of large and small electrodes. The biosensor sensitivity in the linear part is up to 0.79 nA/M/mm2 in the case of flow of 20 L/min. The stability of the developed biosensor was also evaluated – after 11 days the signal decreased about 45%. Preliminary measurements of the AChE biosensor, performed in the reservoir only, show that the chronoamperometric signal in response to different glucose concentrations follows Michaelis-Menten kinetics, with a Michaelis constant of 2.6 mM. Here, the measurement range is also limited to a 10 mM ATCl concentration. After exposing the biosensor to 25 M of eserine for 10 min, 70% inhibition of the enzyme was observed. The reactivation of the inihibited AChE was determined as 0.016 min-1. The measured parameters of both biosensors are comparable to the literature. The developed approach of in situ immobilisation of the enzyme, together with the overall development of the microfluidic biosensor presented in this thesis, can be widely applied, e.g. with other biological recognition elements. Additionally, asthe glucose biosensor was primarily designed for glucose monitoring in pharmaceutical processes, further development offers a possibility of continuous and time-independent sensing. On the other hand, the AChE biosensor is developed with biomedical applications in mind. By replacing or adding other biosensing recognition elements the microfluidic system can be customised for other applications and fields. The device could be also used in the fields of medical diagnostics, pharmaceuticals, food industry, ecology, security and beyond.

Ključne besede:biosensor-on-a-chip, electrochemical biosensor, enzyme in situ immobilization, thin-film reference electrode, electrode nanostructuring, physical model of biosensor, AChE biosensor, glucose biosensor

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