Ari Lehmusvuori

An Ion-Sensitive Floating Gate FET Model: Operating Principles and Electrofluidic Gating

We present a model that can be used to compute the charging and potential at any point of the electrochemical system comprising the ion-sensitive floating gate FET (ISFGFET) exposed to an electrolyte solution. In contrast to ion-sensitive FETs, the sensor has an additional control input gate. The model predicts the possibility for electrofluidic gating when the control gate (CG) is used in conjunction with a reference electrode (RE). Electrofluidic gating is the field-effect control over the electric double layer. We consider the applicability of electrofluidic gating in realizable devices and simulate the relationships between oxide properties and electrolyte solution to varying potentials of the CG and the RE. The oxide/electrolyte solution model is merged to the SPICE model of the transistor to create a unified model that can be used to simulate the transfer characteristics of the sensor in absolute terms to change input and electrolyte solution conditions. We simulate the sensor transfer characteristics with common Al2O3 surface to change the pH of the electrolyte solution and compare them to measurements. The results clarify the operation of ISFGFET and its applicability in electrofluidic gating.

High-performance closed-tube PCR based on switchable luminescence probes

We introduce a switchable lanthanide luminescence reporter technology based closed-tube PCR for the detection of specific target DNA sequence. In the switchable lanthanide chelate complementation based reporter technology hybridization of two nonfluorescent oligonucleotide probes to the adjacent positions of the complementary strand leads to the formation of a highly fluorescent lanthanide chelate complex. The complex is self-assembled from a nonfluorescent lanthanide chelate and a light-harvesting antenna ligand when the reporter molecules are brought into close proximity by the oligonucleotide probes. Outstanding signal-to-background discrimination in real-time PCR assay was achieved due to the very low background fluorescence level and high specific signal generation. High sensitivity of the reporter technology allows the detection of a lower concentration of amplified DNA in the real-time PCR, resulting in detection of the target at the earlier amplification cycle compared to commonly used methods.

Rapid homogeneous PCR assay for the detection of Chlamydia trachomatis in urine samples

Chlamydia trachomatis infection is the most common bacterial sexually transmitted disease and a major public health problem worldwide. Fast and sensitive point-of-care diagnostics including non-invasive sample collection would be of value for the prevention of C. trachomatis transmission. The aim of this study was to develop a fast, reliable, non-invasive and easy-to-use homogenous PCR assay for the detection of C. trachomatis. Bacteria were concentrated from urine by a simple and fast centrifugation-based urine pretreatment method. Novel automated GenomEra technology was utilized for the rapid closed-tube PCR including time-resolved fluorometric detection of the target using lanthanide chelate labeled probes. We have developed a rapid C. trachomatis assay which provides qualitative results in 1 h with diagnostic sensitivity and specificity of 98.7% and 97.3%, respectively. The novel assay can be performed with minimal laboratory expertise and without sophisticated DNA-extraction devices and has performance comparable to current gold standard assays.

Homogeneous duplex polymerase chain reaction assay using switchable lanthanide fluorescence probes.

We have developed a duplex polymerase chain reaction (PCR) assay based on switchable lanthanide chelate complementation probes. In the complementation probe technology, two nonfluorescent oligonucleotide probes, one labeled with a lanthanide ion carrier chelate and another with a light absorbing antenna ligand, form a fluorescent complex by self-assembly of the reporter molecules when the two probes are hybridized in adjacent positions to the target DNA. Here we report the synthesis of a new terbium(III) (Tb(III)) ion carrier chelate and a new light-absorbing antenna ligand for Tb(III) and the development of a duplex Chlamydia trachomatis (Ct) PCR assay. For the detection of Ct in urine samples, a specific sequence in Ct cryptic plasmid was amplified and detected using europium(III) (Eu(III)) complementation probes. An internal amplification control was amplified in each reaction and detected using Tb(III) complementation probes to verify the Ct negative results. Ct bacteria were concentrated from urine samples with a rapid and simple centrifugation-based sample preparation method. Good diagnostic accuracy (99-100%) was achieved, and also Ct positive reactions yielded a very high Eu(III) signal-to-background ratio (maximum of 244). High performance of the complementation probes is advantageous when sample may contain impurities after a simple sample preparation.

Homogenous M13 bacteriophage quantification assay using switchable lanthanide fluorescence probes

We have developed a rapid and reliable bacteriophage quantification method based on measurement of phage single-stranded DNA (ssDNA) using switchable lanthanide chelate complementation probes. One oligonucleotide probe contains a non-fluorescent lanthanide ion carrier chelate and another probe is labeled with a light absorbing antenna ligand. Hybridization of the non-fluorescent complementation probes in adjacent positions on the released bacteriophage ssDNA leads to high local concentrations of the lanthanide ion carrier chelate and the antenna ligand, inducing formation of a fluorescent lanthanide chelate complex. This method enables monitoring of bacteriophage titers in a 20 min assay with a dynamic range of 10(9)-10(12) cfu/mL in a microtiter well format. While designed for titering filamentous bacteriophage used in phage display, our method also could be implemented in virological research as a tool to analyze ssDNA virus reproduction.

Lanthanide chelate complementation and hydrolysis enhanced luminescent chelate in real-time reverse transcription polymerase chain reaction assays for KLK3 transcripts

The requirement for high-performance reporter probes in real-time detection of polymerase chain reaction (PCR) has led to the use of time-resolved fluorometry of lanthanide chelates. The aim of this study was to investigate the applicability of the principle of lanthanide chelate complementation (LCC) in comparison with a method based on hydrolysis enhancement and quenching of intact probes. A real-time reverse transcription (RT) PCR assay for kallikrein-related peptidase 3 (KLK3, model analyte) was developed by using the LCC detection method. Both detection methods were tested with a standard series of purified PCR products, 20 prostatic tissues, 20 healthy and prostate cancer patient blood samples, and female blood samples spiked with LNCaP cells. The same limit of detection was obtained with both methods, and two cycles earlier detection with the LCC method was observed. KLK3 messenger RNA (mRNA) was detected in all tissue samples and in 1 of 20 blood samples identically with both methods. The background was 30 times lower, and the signal-to-background (S/B) ratio was 3 times higher, when compared with the reference method. Use of the new reporter method provided similar sensitivity and specificity as the reference method. The lower background, the improved S/B ratio, and the possibility of melting curve analysis and single nucleotide polymorphism (SNP) detection could be advantages for this new reporter probe.

Ready to use dry-reagent PCR assays for the four common bacterial pathogens using switchable lanthanide luminescence probe system

Ready to use dry-reagent PCR assays for Escherichia coli, Staphylococcus aureus, Streptococcus pneumoniae, Pseudomonas spp. and for broad-range bacteria detection were developed. The assays were based on novel switchable lanthanide probes that provide sensitive target DNA detection with exceptionally high signal-to-background ratio, thus enabling clear discrimination between positive and negative results. For example, sensitivity of three S. aureus and two S. pneumonia bacteria (colony forming units) per PCR assay was measured with fluorescence signal more than 30 times over the background signal level. The rapid and easy-to-use assays are suitable for routine clinical diagnostics without molecular biology expertise and facilities.

Closed-tube human leukocyte antigen DQA1∗05 genotyping assay based on switchable lanthanide luminescence probes.

Genotyping in closed tube is commonly performed using polymerase chain reaction (PCR) amplification and allele-specific oligonucleotide probes using fluorescence resonance energy transfer (FRET). Here we introduce a homogeneous human leukocyte antigen (HLA)-DQA1∗05 end-point PCR assay based on switchable lanthanide luminescence probe technology and a simple dried blood sample preparation. The switchable probe technology is based on two non-luminescent oligonucleotide probes: one carrying a non-luminescent lanthanide chelate and the other carrying a light-absorbing antenna ligand. Hybridization of the probes in adjacent positions to the target DNA leads to the formation of a highly luminescent lanthanide chelate complex by self-assembly of the reporter molecules. Performance of the HLA-DQA1∗05 assay was evaluated by testing blood samples collected on sample collection cards and was prepared by lysing the punched samples (3-mm discs) using alkaline reaction conditions and high temperature. Testing of 147 blood samples yielded 100% correlation to the heterogeneous DELFIA technology-based reference assay. Genotyping requires carefully designed probe sequences able to discriminate matched and mismatched target sequences by hybridization. Furthermore, definite genotype discrimination was achieved because inherently non-luminescent switchable probes together with time-resolved measurement mode led to very low background signal level and, therefore, very high signal differences averaging 54-fold between DQA1∗05 and other alleles.