Simple, Reagentless Quantification of Total Bilirubin in Blood Via Microfluidic Phototreatment and Image Analysis.

Total bilirubin (T-Bil) is an important clinical diagnostic marker that is measured frequently by physicians to assist in the diagnosis, treatment, and monitoring of multiple medical conditions. The work demonstrated here utilizes the 48-year-old mechanism of phototherapy that is commonly implemented in the treatment of infants with exaggerated physiologic and pathologic jaundice but adapts it to the microfluidic level for the ultimate purpose of total bilirubin quantitation. After acquisition of a small volume of blood (<10 µL) and through subsequent separation (plasma + red blood cells), a 3 µL plasma sample was imaged by a portable scanner and analyzed through a custom algorithm for color intensity. After blue light irradiation for 10 min at 470 nm, the sample was reimaged and analyzed. The resulting intensities obtained pre- and postimaging (clearly observed through a color change from yellow to clear) were then utilized to calculate the total bilirubin concentration. A total of 34 blood samples were analyzed with microfluidic photo treatment-image analysis (µPIA) and were found to have a Deming-regression slope of 0.97 (R2 = 0.960) when compared to the total bilirubin values determined in the clinical laboratory. We demonstrate the implementation of a centrifugal microdevice fabricated through the Print, Cut, and Laminate (PCL) method that accepts eight whole blood samples and provides the capabilities to not only quantitate total bilirubin (Deming-regression slope of 0.95, R2 = 0.990) but allow future integration with excess plasma sufficient for additional downstream clinical assays. This work will highlight the inexpensive nature of the analysis (absence of caustic, viscous, or additional reagents), the simplicity (does not require any chemical reactions), speed (sample-to-answer in <15 min), insusceptibility to biofouling (no protein matrix effects, hemoglobin interferences, and minimized turbidity), low volume plasma requirement (3 µL), and the ability for future downstream integration.

Rotation-Driven Microfluidic Disc for White Blood Cell Enumeration Using Magnetic Bead Aggregation.

We recently defined a magnetic bead-based assay that exploited an agglutination-like response for DNA and applied it to DNA-containing cell enumeration using inexpensive benchtop hardware [ J. Am. Chem. Soc. 2012 , 134 ( 12 ), 5689 - 96 ]. Although cost-efficient, the open-well format assay required numerous manual steps, and the magnetic field actuation scheme was not readily adaptable for integration. Here, we demonstrate a low-cost (<$2 in-lab), higher-throughput "pinwheel assay" platform that relies on a combination of a disposable rotation-driven microdisc (RDM), and a simple bidirectional rotating magnetic field (bi-RMF). The assay was transformed into an integrated microfluidic system using a multilayered polyester microfluidic disc created through laser print, cut and laminate fabrication, with fluid flow controlled by rotation speed without any mechanical valves. The RDM accepts four samples that undergo on-chip dilution to five different concentrations that cover the effective concentration range needed for downstream cell counting by pinwheel assay. We show that a bi-RMF is effective for the simultaneous actuation of pinwheel assays in 20 detection chambers. The optimization of the bi-RMF frequencies allows the RDM-based pinwheel assay detect human genomic DNA down to a mass of human genomic DNA (5.5 picograms) that is roughly equal to the mass in a single cell. For proof of principle, enumeration of the white blood cells in human blood samples on the RDM provided data correlating well (C.V. of 10%) with those obtained in a clinical lab. Fusing the cost-effective RDM with a simple bi-RMF provides a promising strategy for automation and multiplexing of magnetic particle-based agglutination assays.

Evaluation of the initiation of urine drug screens intended for use in transfer patients.

OBJECTIVE: The objective of this study was to determine if signs of clinical intoxication were present in patients who had transfer urine drug screens (UDS) performed and to determine the proportion of patients with UDS orders who were actually transferred to another facility. METHODS: Of all emergency department (ED) patient visits who had a transfer UDS ordered from November 19, 2011, to December 31, 2012, 54% of the population was randomly selected for review by 1 of 3 study investigators. For quality assurance, a random sample of 100 patient charts was independently reviewed by all 3 investigators to assure consistency in interpreting data. Demographics, clinical characteristics and history, disposition, and laboratory results were recorded. RESULTS: Of the 639 patients included in this study, only 18% were transferred to another psychiatric facility. Pediatric patients and those with presenting with suicidal ideation were more likely to be transferred to an outside facility. Thirty-six percent of the UDS were positive for at least one substance. Marijuana was the most common substance (23%), followed by cocaine (7%) and opiates (7%). There was no evidence that the UDS changed acute management decisions. CONCLUSIONS: Few (<6%) patients demonstrated any clinical characteristics that were consistent with an acute intoxication. Less than 20% of patients who had a transfer UDS were actually transferred to an outside facility corresponding with more than 80% not ordered appropriately according to the ED established guidelines. This number of inappropriate tests represented more than $152 000 of avoidable UDS cost during the study period.

UBA1-CDK16 : A Sex-Specific Chimeric RNA and Its Role in Immune Sexual Dimorphism.

RNA processing mechanisms, such as alternative splicing and RNA editing, have been recognized as critical means to expand the transcriptome. Chimeric RNAs formed by intergenic splicing provide another potential layer of RNA diversification. By analyzing a large set of RNA-Seq data and validating results in over 1,200 blood samples, we identified UBA1-CDK16 , a female-specific chimeric transcript. Intriguingly, both parental genes, are expressed in males and females. Mechanistically, UBA1-CDK16 is produced by cis-splicing between the two adjacent X-linked genes, originating from the inactive X chromosome. A female-specific chromatin loop, formed between the junction sites, facilitates the alternative splicing of its readthrough precursor. This unique chimeric transcript exhibits evolutionary conservation, evolving to be female-specific from non-human primates to humans. Furthermore, our investigation reveals that UBA1-CDK16 is enriched in the myeloid lineage and plays a regulatory role in myeloid differentiation. Notably, female COVID-19 patients who tested negative for this chimeric transcript displayed higher counts of neutrophils, highlighting its potential role in disease pathogenesis. These findings support the notion that chimeric RNAs represent a new repertoire of transcripts that can be regulated independently from the parental genes, and a new class of RNA variance with potential implications in sexual dimorphism and immune responses.

Label-free method for cell counting in crude biological samples via paramagnetic bead aggregation.

Under chaotropic conditions, DNA released from lysed cells causes the aggregation of paramagnetic beads in a rotating magnetic field in a manner that is independent of the presence of other cellular components. The extent of aggregation correlates with the mass of DNA in a quantitative manner (Leslie, D. C. et al., J. Am. Chem. Soc. 2012, 134, 5689-96), and from this, the number of DNA-containing cells in the sample can be enumerated. Microbial growth testing is demonstrated by monitoring bead aggregation with E. coli in the presence of ampicillin. Without the need for fluorescent labeling or Coulter counting, the white blood cell count can be defined directly from a microliter of crude whole blood. Specificity is brought to the process by coupling bead-based immunocapture with DNA-bead aggregation allowing for the enumeration of CD4+ T cells from human blood samples. The results of DNA-induced bead aggregation had a 95% correlation with those generated by flow cytometry. With the process requiring only inexpensive, widely available benchtop laboratory hardware, a digital camera, and a simple algorithm, this provided a highly accessible alternative to more expensive cell-counting techniques.

A laboratory-developed TaqMan Array Card for simultaneous detection of 19 enteropathogens.

The TaqMan Array Card (TAC) system is a 384-well singleplex real-time PCR format that has been used to detect multiple infection targets. Here we developed an enteric TaqMan Array Card to detect 19 enteropathogens, including viruses (adenovirus, astrovirus, norovirus GII, rotavirus, and sapovirus), bacteria (Campylobacter jejuni/C. coli, Clostridium difficile, Salmonella, Vibrio cholerae, diarrheagenic Escherichia coli strains including enteroaggregative E. coli [EAEC], enterotoxigenic E. coli [ETEC], enteropathogenic E. coli [EPEC], and Shiga-toxigenic E. coli [STEC]), Shigella/enteroinvasive E. coli (EIEC), protozoa (Cryptosporidium, Giardia lamblia, and Entamoeba histolytica), and helminths (Ascaris lumbricoides and Trichuris trichiura), as well as two extrinsic controls to monitor extraction and amplification efficiency (the bacteriophage MS2 and phocine herpesvirus). Primers and probes were newly designed or adapted from published sources and spotted onto microfluidic cards. Fecal samples were spiked with extrinsic controls, and DNA and RNA were extracted using the QiaAmp Stool DNA minikit and the QuickGene RNA Tissue kit, respectively, and then mixed with Ag-Path-ID One Step real-time reverse transcription-PCR (RT-PCR) reagents and loaded into cards. PCR efficiencies were between 90% and 105%, with linearities of 0.988 to 1. The limit of detection of the assays in the TAC was within a 10-fold difference from the cognate assays performed on plates. Precision testing demonstrated a coefficient of variation of below 5% within a run and 14% between runs. Accuracy was evaluated for 109 selected clinical specimens and revealed an average sensitivity and specificity of 85% and 77%, respectively, compared with conventional methods (including microscopy, culture, and immunoassay) and 98% and 96%, respectively, compared with our laboratory-developed PCR-Luminex assays. This TAC allows fast, accurate, and quantitative detection of a broad spectrum of enteropathogens and is well suited for surveillance or clinical purposes.

New detection modality for label-free quantification of DNA in biological samples via superparamagnetic bead aggregation.

Combining DNA and superparamagnetic beads in a rotating magnetic field produces multiparticle aggregates that are visually striking, enabling label-free optical detection and quantification of DNA at levels in the picogram per microliter range. DNA in biological samples can be quantified directly by simple analysis of optical images of microfluidic wells placed on a magnetic stirrer without prior DNA purification. Aggregation results from DNA/bead interactions driven either by the presence of a chaotrope (a nonspecific trigger for aggregation) or by hybridization with oligonucleotides on functionalized beads (sequence-specific). This paper demonstrates quantification of DNA with sensitivity comparable to that of the best currently available fluorometric assays. The robustness and sensitivity of the method enable a wide range of applications, illustrated here by counting eukaryotic cells. Using widely available and inexpensive benchtop hardware, the approach provides a highly accessible low-tech microscale alternative to more expensive DNA detection and cell counting techniques.

Simultaneous detection of six diarrhea-causing bacterial pathogens with an in-house PCR-luminex assay.

Diarrhea can be caused by a range of pathogens, including several bacteria. Conventional diagnostic methods, such as culture, biochemical tests, and enzyme-linked immunosorbent assay (ELISA), are laborious. We developed a 7-plex PCR-Luminex assay to simultaneously screen for several of the major diarrhea-causing bacteria directly in fecal specimens, including pathogenic Aeromonas, Campylobacter jejuni, Campylobacter coli, Salmonella, Shigella, enteroinvasive Escherichia coli (EIEC), Vibrio, and Yersinia. We included an extrinsic control to verify extraction and amplification. The assay was first validated with reference strains or isolates and exhibited a limit of detection of 10(3) to 10(5) CFU/g of stool for each pathogen as well as quantitative detection up to 10(9) CFU/g. A total of 205 clinical fecal specimens from individuals with diarrhea, previously cultured for enteric pathogens and tested for Campylobacter by ELISA, were evaluated. Using these predicate methods as standards, sensitivities and specificities of the PCR-Luminex assay were 89% and 94% for Aeromonas, 89% and 93% for Campylobacter, 96% and 95% for Salmonella, 94% and 94% for Shigella, 92% and 97% for Vibrio, and 100% and 100% for Yersinia, respectively. All discrepant results were further examined by singleplex real-time PCR assays targeting different gene regions, which revealed 89% (55/62 results) concordance with the PCR-Luminex assay. The fluorescent signals obtained with this approach exhibited a statistically significant correlation with the cycle threshold (C(T)) values from the cognate real-time PCR assays (P < 0.05). This multiplex PCR-Luminex assay enables sensitive, specific, and quantitative detection of the major bacterial causes of gastroenteritis.

Warfarin genotyping in a single PCR reaction for microchip electrophoresis.

BACKGROUND: Warfarin is the most commonly prescribed oral anticoagulant medication but also is the second leading cause of emergency room visits for adverse drug reactions. Genetic testing for warfarin sensitivity may reduce hospitalization rates, but prospective genotyping is impeded in part by the turnaround time and costs of genotyping. Microfluidics-based assays can reduce reagent consumption and analysis time; however, no current assay has integrated multiplexed allele-specific PCR for warfarin genotyping with electrophoretic microfluidics hardware. Ideally, such an assay would use a single PCR reaction and, without further processing, a single microchip electrophoresis (ME) run to determine the 3 single-nucleotide polymorphisms (SNPs) affecting warfarin sensitivity [i.e., CYP2C9 (cytochrome P450, family 2, subfamily C, polypeptide 9) *2, CYP2C9 *3, and the VKORC1 (vitamin K epoxide reductase complex 1) A/B haplotype]. METHODS: We designed and optimized primers for a fully multiplexed assay to examine 3 biallelic SNPs with the tetraprimer amplification refractory mutation system (T-ARMS). The assay was developed with conventional PCR equipment and demonstrated for microfluidic infrared-mediated PCR. Genotypes were determined by ME on the basis of the pattern of PCR products. RESULTS: Thirty-five samples of human genomic DNA were analyzed with this multiplex T-ARMS assay, and 100% of the genotype determinations agreed with the results obtained by other validated methods. The sample population included several genotypes conferring warfarin sensitivity, with both homozygous and heterozygous genotypes for each SNP. Total analysis times for the PCR and ME were approximately 75 min (1-sample run) and 90 min (12-sample run). CONCLUSIONS: This multiplexed T-ARMS assay coupled with microfluidics hardware constitutes a promising avenue for an inexpensive and rapid platform for warfarin genotyping.

Intraprocedural cortisol levels in the evaluation of proper catheter placement in adrenal venous sampling.

PURPOSE: Adrenal venous sampling (AVS) is limited by technical failures that result from incorrect catheter placement or failure to catheterize the right adrenal vein. The existence of an inadequate sample may not be recognized at the time of the procedure, which can lead to nondiagnostic results. Rapid assay of serum cortisol levels allows for intraprocedural evaluation of the ratio of adrenal and peripheral cortisol concentrations and confirmation of adequate sampling. MATERIALS AND METHODS: Retrospective review was performed of 64 AVS procedures, 36 performed with digital subtraction venography (DSV) guidance alone and 28 performed with DSV guidance plus intraprocedural quantitative determinations of plasma cortisol levels. RESULTS: Technical success was achieved in 26 of 28 procedures (93%) that included intraprocedural cortisol measurements in addition to DSV. Analysis of cortisol ratios (adrenal vein cortisol level divided by inferior vena cava cortisol level) revealed technical success in 29 of 36 procedures (81%) that used DSV alone (P = .16). Procedure note indication of successful/unsuccessful sampling coincided with cortisol ratios in 28 of 28 cases (100%) that included cortisol measurement and 29 of 36 cases (81%) that did not (P = .01).The feedback provided by the measurement of cortisol levels allowed the operator to salvage three of five inadequate AVS procedures (60%), increasing the overall technical success rate from 82% to 93%. CONCLUSIONS: Intraprocedural measurement of cortisol with rapid results allows for prediction of successful adrenal vein catheterization, which may increase the technical success rate of AVS.

Optimization of novel loop-mediated isothermal amplification with colorimetric image analysis for forensic body fluid identification.

Accurate presumptive and confirmatory test use for forensic body fluid identification is essential for gaining contextual information for crime scene investigators. Loop-mediated isothermal amplification (LAMP) is an ideal method for forensic body fluid identification because it is highly specific and generates multi-sized amplicon DNA, and successful amplification results can be read out colorimetrically. Here, we show preliminary data on a LAMP method that rapidly identifies body fluids including venous blood, semen, and saliva, based on colorimetric response and image analysis. The method is designed for easy implementation into forensic casework protocols with minimal disruption to DNA analysis. LAMP naturally increases target specificity due to the use of multiple primers for one target and mRNA targets were used for tissue and human specificity. With colorimetric detection as an inherent part of LAMP, samples that are positive or negative for any of the body fluids are readily identified by image capture and analysis, thus eliminating subjectivity. Results show by using the 3D-printed imaging system specific color ranges can be set for easy determination of body fluids. The resulting color change can be seen in <30 min using a universal temperature and primer concentration for all body fluids. This simple method and imaging system allow for minimal hands-on time with objective image analysis and presents a pathway for creating a new potential method for forensic body fluid identification.

Characterization of dynamic solid phase DNA extraction from blood with magnetically controlled silica beads.

A novel solid phase extraction technique is described where DNA is bound and eluted from magnetic silica beads in a manner where efficiency is dependent on the magnetic manipulation of the beads and not on the flow of solution through a packed bed. The utility of this technique in the isolation of reasonably pure, PCR-amplifiable DNA from complex samples is shown by isolating DNA from whole human blood, and subsequently amplifying a fragment of the beta-globin gene. By effectively controlling the movement of the solid phase in the presence of a static sample, the issues associated with reproducibly packing a solid phase in a microchannel and maintaining consistent flow rates are eliminated. The technique described here is rapid, simple, and efficient, allowing for recovery of more than 60% of DNA from 0.6 microL of blood at a concentration which is suitable for PCR amplification. In addition, the technique presented here requires inexpensive, common laboratory equipment, making it easily adopted for both clinical point-of-care applications and on-site forensic sample analysis.

A novel loop-mediated isothermal amplification method for identification of four body fluids with smartphone detection.

Messenger RNA profiling for body fluid identification (bfID) is a useful approach to collect contextual information associated with a crime. Current methods require costly fluorescent probes, lengthy amplification protocols and/or time-consuming sample preparation. To simplify this process, we developed a bfID method that has the potential to be rapid in analysis time, inexpensive and fluorescence-free, combining a universal operating procedure with a high-throughout (microwell plate) platform for simultaneous detection of mRNA markers from whole blood, semen, saliva, and vaginal fluid. Full bfID sample preparation and analysis of 23 samples was completed in under 3 h using smart phone optical detection and analysis and show efficacy of the method in a validated blind study. The results provide an efficient, sensitive and specific approach to supplement the current biochemical tests in a forensic laboratory.

Use of Dual-Force Aggregation as a Multiplexed, Rapid Point-of-Care Screening Method for White Blood Cell Counting from Whole Blood Samples.

BACKGROUND: Enumeration of blood cells is an integral metric for evaluating patient health and can be used to screen for a wide range of diseases and conditions. Conventional methods rely on large, expensive, and complicated instrumentation that requires trained technicians and is not amenable to point-of-care analysis. This work demonstrates the use of a multiplexed, bead-based assay for both rapid white blood cell (WBC) count screening and accurate, multiplexed WBC counts for point-of-care analysis. METHODS: Blood samples were lysed and diluted before being incubated with silica-coated magnetic particles under chaotropic conditions, a rotating magnetic field, and a source of agitation. The resulting bead aggregation was imaged and correlated to a known WBC count. After establishing standard curves, the WBC count for 18 whole blood samples were determined by this method and compared to values obtained conventionally. RESULTS: When the optimal dilution factor for lysis of whole blood samples was established, 17 of 18 samples (94.4%) were correctly screened and categorized as having high, typical, or low WBC count, while 14 of 18 samples were within 16% of the reported clinical values. The developed system provides analysis of 13 samples in <3 min with a total analysis time of approximately 10 min (including incubation and dilution) and represents comparable throughput to conventional instrumentation, while providing point-of-care capability with reduced size (14 × 21 × 14 cm) and simplicity. CONCLUSIONS: This work demonstrates the potential for a multiplexed, bead-based assay to be used as a rapid, point-of-care screening method for WBC counting from whole blood samples.

Multilevel fluidic flow control in a rotationally-driven polyester film microdevice created using laser print, cut and laminate.

This paper presents a simple and cost-effective polyester toner microchip fabricated with laser print and cut lithography (PCL) to use with a battery-powered centrifugal platform for fluid handling. The combination of the PCL microfluidic disc and centrifugal platform: (1) allows parallel aliquoting of two different reagents of four different volumes ranging from nL to µL with an accuracy comparable to a piston-driven air pipette; (2) incorporates a reciprocating mixing unit driven by a surface-tension pump for further dilution of reagents, and (3) is amenable to larger scale integration of assay multiplexing (including all valves and mixers) without substantially increasing fabrication cost and time. For a proof of principle, a 10 min colorimetric assay for the quantitation of the protein level in the human blood plasma samples is demonstrated on chip with a limit of detection of ∼5 mg mL(-1) and coefficient of variance of ∼7%.

The ARTµS: a novel microfluidic CD4+ T-cell enumeration system for monitoring antiretroviral therapy in HIV patients.

We report on a novel and cost-effective microfluidic platform that integrates immunomagnetic separation and cell enumeration via DNA-induced bead aggregation. Using a two-stage immunocapture microdevice, 10 µL of whole blood was processed to isolate CD4+ T-cells. The first stage involved the immuno-subtraction of monocytes by anti-CD14 magnetic beads, followed by CD4+ T-cell capture with anti-CD4 magnetic beads. The super hydrophilic surface generated during polydimethylsiloxane (PDMS) plasma treatment allowed for accurate metering of the CD4+ T-cell lysate, which then interacted with silica-coated magnetic beads under chaotropic conditions to form aggregates. Images of the resulting aggregates were captured and processed to reveal the mass of DNA, which was used to back-calculate the CD4+ T-cell number. Studies with clinical samples revealed that the analysis of blood within 24 hours of phlebotomy yielded the best results. Under these conditions, an accurate cell count was achieved (R(2) = 0.98) when compared to cell enumeration via flow cytometry, and over a functional dynamic range from 106-2337 cells per µL.

Sonorheometry assessment of platelet function in cardiopulmonary bypass patients: Correlation of blood clot stiffness with platelet integrin αIIbß3 activity, aspirin usage, and transfusion risk.

BACKGROUND: Impaired platelet function may underlie bleeding associated with cardiopulmonary bypass (CPB) and at present is incompletely evaluated with existing diagnostic technologies. Sonorheometry (SR) is a recently developed ultrasound-based technology that quantifies hemostasis and platelet activity from a blood sample by measuring ex vivo clot stiffness (S). We hypothesized that impaired platelet-fibrin interactions as assessed by SR would correlate with transfusion during CPB and history of prior aspirin therapy. METHODS: Thirty-nine patients undergoing elective cardiopulmonary bypass (CPB) were enrolled following informed consent (University of Virginia IRB#14050) in a prospective observational pilot study to assess pre-operative platelet function and transfusion frequency. To assess platelet activity, abciximab was added to blood prior to SR and native S versus abciximab treated S created a differential test for platelet activity. Patient blood samples were activated with kaolin and SR was then used to measure clot stiffness. Patients were transfused with blood products as directed by clinical practice, with the surgical team blinded to SR results. RESULTS: Blood clot stiffness with and without abciximab, was compared in a ratio test (S/Sabciximab) named the Platelet Function Index (PFI). PFI was hypothesized to be positively correlated with platelet contributions through integrin αIIbß3 to clot stiffness. PFI for CPB subjects was lower for those receiving transfusions than those not receiving transfusions (p<0.006). A receiver-operator characteristics (ROC) analysis correlating the PFI with the blinded surgical team's decision on transfusions that included platelet concentrates generated an area under the curve (AUC) of 0.79 (p<0.001). Additionally, the mean value of PFI for subjects on aspirin therapy was lower than for those not on aspirin therapy (p<0.02) and correlated with a 1.73-fold enhanced risk of receiving a peri-operative transfusion. CONCLUSION: Evaluation of platelet function with SR may help in the specification of blood transfusion needs in cardiac surgery and in the assessment of aspirin effects on risk of surgical bleeding.

Hematocrit analysis through the use of an inexpensive centrifugal polyester-toner device with finger-to-chip blood loading capability.

Hematocrit (HCT) measurements are important clinical diagnostic variables that help physicians diagnose and treat various medical conditions, ailments, and diseases. In this work, we present the HCT Disc, a centrifugal microdevice fabricated by a Print, Cut and Laminate (PCL) method to generate a 12-sample HCT device from materials costing <0.5 USD (polyester and toner or PeT). Following introduction from a drop of blood (finger stick), whole blood metering and cell sedimentation are controlled by centrifugal force, only requiring a CD player motor as external hardware and, ultimately, a cell phone for detection. The sedimented volume from patient blood in the HCT Disc was analyzed using a conventional scanner/custom algorithm for analysis of the image to determine a hematocrit value, and these were compared to values generated in a clinical laboratory, which correlated well. To enhance portability and assure simplicity of the HCT measurement, values from image analysis by a cell phone using a custom application was compared to the scanner. Fifteen samples were analyzed with cell phone image analysis system and were found to be within 4% of the HCT values determined in the clinical lab. We demonstrate the feasibility of the PeT device for HCT measurement, and highlight its uniquely low cost (<0.5 USD), speed (sample-to-answer <8 min), multiplexability (12 samples), low volume whole blood requirement (<3 µL), rotation speeds (<4000 rpm) needed for effective measurement as well as the direct finger-to-chip sample loading capability.

Optimization of Quantitative PCR Methods for Enteropathogen Detection.

Detection and quantification of enteropathogens in stool specimens is useful for diagnosing the cause of diarrhea but is technically challenging. Here we evaluate several important determinants of quantification: specimen collection, nucleic acid extraction, and extraction and amplification efficiency. First, we evaluate the molecular detection and quantification of pathogens in rectal swabs versus stool, using paired flocked rectal swabs and whole stool collected from 129 children hospitalized with diarrhea in Tanzania. Swabs generally yielded a higher quantification cycle (Cq) (average 29.7, standard deviation 3.5 vs. 25.3 ± 2.9 from stool, P<0.001) but were still able to detect 80% of pathogens with a Cq < 30 in stool. Second, a simplified total nucleic acid (TNA) extraction procedure was compared to separate DNA and RNA extractions and showed 92% (318/344) sensitivity and 98% (951/968) specificity, with no difference in Cq value for the positive results (ΔCq(DNA+RNA-TNA) = -0.01 ± 1.17, P = 0.972, N = 318). Third, we devised a quantification scheme that adjusts pathogen quantity to the specimen's extraction and amplification efficiency, and show that this better estimates the quantity of spiked specimens than the raw target Cq. In sum, these methods for enteropathogen quantification, stool sample collection, and nucleic acid extraction will be useful for laboratories studying enteric disease.