The detection of drugs of abuse in biological matrices using enzyme-linked immunosorbent assay and liquid chromatography-tandem mass spectrometry

The aim of this study was to investigate the potential use of ELISA and LC-MS-MS in combination and as individual techniques, for the detection of drugs of abuse in biological matrices. Overall the LC-MS-MS method showed good correlation results for opiates compared to the GC-MS method. 6-MAM was however detected in more root segments and segments excluding roots by LC-MS-MS. Morphine was detected in a greater number of root segments by LC-MS-MS compared to GC-MS. However, morphine was detected in a greater number of segments excluding roots by GC-MS. Codeine and dihydrocodeine were also detected in a greater number of root segments and segments excluding roots by GC-MS. The cocaine results showed excellent qualitative correlation between the LC-MS-MS and GC-MS methods for cocaine and benzoylecgonine. The GC-MS method did not however extract greater concentrations of cocaine and its metabolites compared to LC-MS-MS due to the higher recovery of the drug group specific GC-MS method. Cocaethylene and EME were detected in some samples by LC-MS-MS method for opiates and cocaine and its metabolites compared to the GC-MS method; there may be some cases where the GC-MS method would detect the analytes where the LC-MS-MS method would not. This has been demonstrated in 3 samples for morphine and in 6 samples for codeine. The LC-MS-MS method analysed for and detected amphetamines in samples that were not tested for amphetamines by GC-MS. In one sample that was tested by both methods, amphetamine was detected in the root sample by LC-MS-MS where GC-MS failed to detect it. Also a greater concentration of amphetamine was extracted using the LC-MS-MS method in the segment without roots. The LC-MS-MS method was useful for the analysis of 17 drugs of abuse in post-mortem hair samples in forensic toxicology cases. Using this method, it is possible to obtain maximum information from one hair sample which is extremely useful when the sample weight is limited. The ability of the LC-MS-MS method to extract and analyse a greater number of drug groups from one hair sample highlights the advantages of using this method over GC-MS which targets individual drug groups and requires splitting of the sample. This method is particularly applicable for implementation in the forensic toxicology laboratory at the University of Glasgow where currently GC-MS methods that target individual drug groups are used for routine hair screening and confirmation.EThOS - Electronic Theses Online ServiceGBUnited Kingdo

Phospholipid film in electrolyte-gated organic field-effect transistors

A totally innovative electrolyte-gated field effect transistor, embedding a phospholipid film at the interface between the organic semiconductor and the gating solution, is described. The electronic properties of OFETs including a phospholipid film are studied in both pure water and in an electrolyte solution and compared to those of an OFET with the organic semiconductor directly in contact with the gating solution. In addition, to investigate the role of the lipid layers in the charge polarization process and quantify the field-effect mobility, impedance spectroscopy was employed. The results indicate that the integration of the biological film minimizes the penetration of ions into the organic semiconductor thus leading to a capacitive operational mode as opposed to an electrochemical one. The OFETs operate at low voltages with a field-effect mobility in the 10−3 cm2 V−1 s−1 range and an on/off current ratio of 103. This achievement opens perspectives to the development of FET biosensors potentially capable to operate in direct contact with physiological fluids.funding agencies|European Union|248728

Phospholipid film in electrolyte-gated organic field-effect transistors

A totally innovative electrolyte-gated field effect transistor, embedding a phospholipid film at the interface between the organic semiconductor and the gating solution, is described. The electronic properties of OFETs including a phospholipid film are studied in both pure water and in an electrolyte solution and compared to those of an OFET with the organic semiconductor directly in contact with the gating solution. In addition, to investigate the role of the lipid layers in the charge polarization process and quantify the field-effect mobility, impedance spectroscopy was employed. The results indicate that the integration of the biological film minimizes the penetration of ions into the organic semiconductor thus leading to a capacitive operational mode as opposed to an electrochemical one. The OFETs operate at low voltages with a field-effect mobility in the 10−3 cm2 V−1 s−1 range and an on/off current ratio of 103. This achievement opens perspectives to the development of FET biosensors potentially capable to operate in direct contact with physiological fluids.funding agencies|European Union|248728

http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-68228 ELECTROSYNTHESIS AND CHARACTERIZATION OF GOLD NANOPARTICLES FOR ELECTRONIC CAPACITANCE SENSING OF POLLUTANTS

Electrosynthesis and characterization of gold nanoparticles for electronic capacitance sensing of pollutant

Electronic transduction of proton translocations in nanoassembled lamellae of bacteriorhodopsin

An organic field-effect transistor (OFET) integrating bacteriorhodopsin (bR) nanoassembled lamellae is proposed for an in-depth study of the proton translocation processes occurring as the bioelectronic device is exposed either to light or to low concentrations of general anesthetic vapors. The study involves the morphological, structural, electrical, and spectroscopic characterizations necessary to assess the functional properties of the device as well as the bR biological activity once integrated into the functional biointerlayer (FBI)-OFET structure. The electronic transduction of the protons phototranslocation is shown as a current increase in the p-type channel only when the device is irradiated with photons known to trigger the bR photocycle, while Raman spectroscopy reveals an associated C=C isomer switch. Notably, higher energy photons bring the cis isomer back to its trans form, switching the proton pumping process off. The investigation is extended also to the study of a PM FBI-OFET exposed to volatile general anesthetics such as halothane. In this case an electronic current increase is seen upon exposure to low, clinically relevant, concentrations of anesthetics, while no evidence of isomer-switching is observed. The study of the direct electronic detection of the two different externally triggered proton translocation effects allows gathering insights into the underpinning of different bR molecular switching processes. © 2014 American Chemical Society