Construction of a fiber-optically connected MEG hyperscanning system for recording brain activity during real-time communication.

Communication is one of the most important abilities in human society, which makes clarification of brain functions that underlie communication of great importance to cognitive neuroscience. To investigate the rapidly changing cortical-level brain activity underlying communication, a hyperscanning system with both high temporal and spatial resolution is extremely desirable. The modality of magnetoencephalography (MEG) would be ideal, but MEG hyperscanning systems suitable for communication studies remain rare. Here, we report the establishment of an MEG hyperscanning system that is optimized for natural, real-time, face-to-face communication between two adults in sitting positions. Two MEG systems, which are installed 500m away from each other, were directly connected with fiber optic cables. The number of intermediate devices was minimized, enabling transmission of trigger and auditory signals with almost no delay (1.95-3.90 µs and 3 ms, respectively). Additionally, video signals were transmitted at the lowest latency ever reported (60-100 ms). We furthermore verified the function of an auditory delay line to synchronize the audio with the video signals. This system is thus optimized for natural face-to-face communication, and additionally, music-based communication which requires higher temporal accuracy is also possible via audio-only transmission. Owing to the high temporal and spatial resolution of MEG, our system offers a unique advantage over existing hyperscanning modalities of EEG, fNIRS, or fMRI. It provides novel neuroscientific methodology to investigate communication and other forms of social interaction, and could potentially aid in the development of novel medications or interventions for communication disorders.

Analysis of Serotonin in Human Feces Using Solid Phase Extraction and Column-Switching LC-MS/MS.

Serotonin, an important neurotransmitter, is produced mainly in intestines, and serotonin levels in feces can be an indicator of the intestinal environment. Human feces, however, contain a large amount of contaminants, which vary widely owing to food contents and the intestinal environment, and these contaminants would be expected to interfere with the determination of serotonin levels in human feces. To remove these contaminants and determine serotonin levels, we developed a new method using solid phase extraction (SPE) and column-switching LC-MS/MS. Serotonin, labeled with a stable isotope, was added to human feces samples prior to SPE as an internal standard to correct for individual differences in matrix effects. The recovery rate for SPE was 55.9-81.0% (intraday) and 56.5-78.1% (interday) for feces from two subjects. We analyzed 220 fecal samples from 96 subjects including 76 pregnant and post-delivery women. The endogenous serotonin content per unit weight of dried feces was 0.09-14.13 ng/mg for pregnant and post-delivery women and 0.30-9.93 ng/mg for the remaining subjects.

Prism-based spectral imaging of four species of single-molecule fluorophores by using one excitation laser.

A prism-based imaging system for simultaneously detecting four species of single-molecule (SM) fluorophores was developed. As for the detection method, four spectrally distinct species of BigDye fluorophores were bound to 50-nm-diameter gold nanoparticles (AuNPs) to form AuNP/BigDye complexes. Four species of complexes were randomly immobilized on different fused-silica slides. BigDyes were excited by an argon-ion-laser (excitation wavelengths: 488 and 514.5 nm) beam through total internal reflection on the slide surface. SM fluorescence emitted from a complex was spectrally dispersed through a prism to form an SM spot elongated in the spectral direction on a charge-coupled device. A scattered light spot generated by the AuNP of the same complex under 594-nm laser illumination was used as a wavelength reference, and the SM fluorescence spectrum was obtained from the pixel-intensity pattern of the elongated SM spot. Peak locations of fluorescence spectra of all the observed SM spots were obtained, and their histograms were distinctly separated according to species. SM spots can thus be classified as one of four species according to their peak locations. By statistically analyzing the histograms, the classification accuracy was estimated to be above 93.8 %. The number of pixels in the spectral direction required for classifying four species of SM fluorophores was estimated to be 10. As for the conventional system (which uses two excitation lasers), 15 pixels are required. Using BigDyes as the four fluorophores (which consist of donors linked to acceptors and can be excited by just an argon-ion laser) is the reason that such a small number of pixels was achieved. The developed system can thus detect 1.5 times more SM fluorophores per field of view; that is, its throughput is 1.5 times higher. The approach taken in this study, namely, using BigDye with a prism-type system, is effective for increasing the throughput of DNA microarray-chip analysis and SM real-time DNA sequencing.

Dual-view imaging system using a wide-range dichroic mirror for simultaneous four-color single-molecule detection.

A dual-view imaging system for simultaneous four-color single-molecule (SM) detection was developed. As for the detection procedure, four species of SM fluorophores, namely, Alexa 488, 555, 647, and 680, are immobilized on different slides and excited by evanescent-wave illumination. Fluorescence emitted from an SM fluorophore is split by a wide-range dichroic mirror (WR DM) in a dual-view optics and imaged as two SM fluorescence spots (SM spots) on an electron-multiplying charge-coupled device (EM-CCD) at 100 Hz. The transmittance of the WR DM changes gradually over the wavelength range of 500 to 700 nm so that the signal ratios of the two SM spots for the four fluorophore species differ. A method for classifying SM fluorophores into four species in accordance with their signal ratios was developed. It was used to classify 597 SM fluorophores at an accuracy of above 98% for all the species. This accuracy is comparable to that of a conventional four-color SM detection system. To classify four species, the conventional system disperses SM fluorescence with a prism and provides an elongated SM spot that uses more pixels of an EM-CCD chip than that of the developed system. The developed system can thus detect 1.5-fold more SM spots with the same-size EM-CCD chip, so it can achieve 1.5-fold higher throughput. Moreover, the developed system is based on a simple and practical approach, namely, replacing an ordinary dichroic mirror in a commercially available dual-view optics with a WR DM. This replacement transforms a dual-view imaging system for two-color detection into a system for four-color detection. The developed system is suitable for detection systems of next-generation DNA sequencers and DNA microarray-chip analyzers.

Simultaneous four-color imaging of single molecule fluorophores using dichroic mirrors and four charge-coupled devices.

We developed a total-internal-reflection (TIR) fluorescence microscopy using three dichroic mirrors and four charge-coupled devices (CCDs) to detect simultaneously four colors of single-molecule (SM) fluorophores. Four spectrally distinct species of fluorophores (Alexa 488, Cy3, Cy5, or Cy5.5) were each immobilized on a different fused silica slide. A species of fluorophores on the slide was irradiated simultaneously, by two excitation beams from an Ar ion laser (488 and 514.5 nm) and a diode laser (642 nm) through TIR on the slide surface. Fluorescence emitted from the fluorophores was spectrally resolved into four components by the dichroic mirrors, and four images were generated from them simultaneously and continuously, with the four CCDs at a rate of 10 Hz. A series of images was thus obtained with each CCD. Fluorescence spots for a species were observed mainly in the series of images recorded by its respective-color CCD. In the first image in the series, we picked out the spots as continuous pixel regions that had the values greater than a threshold. Then we selected only those spots that exhibited single-step photobleaching and regarded them as SM fluorescence spots. Pixel values of SM fluorescence spots widely differed. Some SM fluorophores had pixel values smaller than the threshold, and were left unpicked. Assuming the pixel values of SM fluorescence spots differed with a Gaussian profile, we estimated the ratios of unpicked fluorophores to be less than 20% for all the species. Because of the spectral overlaps between species, we also observed cross-talk spots into CCDs other than the respective-color CCDs. These cross-talk SM fluorescence spots can be mistaken for correct species. We thus introduced the classification method and classified SM fluorescence spots into correct species in accordance with two kinds of four-dimensional signal vectors. The error rates of fluorophore classification were estimated to be less than 3.2% for all the species. Our system is suitable for the biological studies that desire to simultaneously monitor the four colors of SM fluorophores.

Prism-based spectral imaging of single-molecule fluorescence from gold-nanoparticle/fluorophore complex.

A wavelength-calibration method for prism-based spectral imaging of single-molecule (SM) fluorescence was developed. With this method, a wavelength reference is provided by photoluminescence from 50-nm-diameter gold nanoparticles (AuNPs) binding with fluorophores. The AuNPs each bound with a SM fluorophore, either Alexa488 or Cy3, to form AuNP/fluorophore complexes in tris-HCl buffer. Each complex was immobilized on a silica slide and then excited by total-internal-reflection illumination to make it emit SM fluorescence and AuNP photoluminescence. The portion of the AuNP photoluminescence transmitted by a band-pass filter gives the wavelength reference. A spectral-imaging system composed of a prism-based spectroscope (with a reciprocal dispersion of about 4 nm/µm) and a charge-coupled device with 6.45-µm-square pixels was used to obtain an SM-fluorescence spectrum and a wavelength-reference spectrum. Through smoothed differentiation of these two spectra, the peak location of the former in relation to the latter was determined with subpixel precision. After that, the SM fluorophore was classified as either Alexa488 or Cy3 according to the peak location. The error rate of the classification was estimated to be only 0.3%.

Improvement of biomolecule quantification precision and use of a single-element aspheric objective lens in fluorescence correlation spectroscopy.

We found a way to increase the precision with which biomolecules present at concentrations below 10(-10) M can be quantified by fluorescence correlation spectroscopy (FCS). The effectiveness of the way was demonstrated experimentally by using a single-element aspheric objective lens, which was newly developed to reduce the cost of FCS instruments. In the first part of this paper, the relative standard deviation (RSD) of FCS-based concentration measurements is estimated theoretically by an analytical approximation assuming the detection volume profiles in FCS setups to be Gaussian and by molecular simulations in which more realistic profiles are calculated from physical parameters of the measurement setups. In a limit of infinitely bright molecules and zero background emission, the analytical approximation predicts that the RSD at a concentration is minimized when the mean number of molecules in a detection volume is approximately 0.5. A detection volume of the order of 10(-13) L thus gives smaller RSD values for concentrations from 10(-11) to 10(-10) M than does one of the order of 10(-15) L, which is widely used in FCS. This prediction is supported by the molecular simulations, taking into account the finite molecule brightness and background emission. In the second part of the paper, the RSD is evaluated experimentally with an FCS setup with a detection volume of 1.1 x 10(-13) L. The newly developed objective lens, serving as the bottom of the sample cell in this setup, has a large numerical aperture (0.9) without using immersion liquid. When a calibration line was made by 30-s FCS measurements of Cy3-labeled, 112-mer single-stranded DNA solutions, the RSD roughly agreed with the simulation result and was less than 0.1 for DNA concentrations from 2 x 10(-11) to 10(-10) M.

Ultra-slim laminated capillary array for high-speed DNA separation.

We developed a new kind of capillary array for electrophoresis by using the numerical-control (NC) wiring technique conventionally used to produce printed-circuit boards. Laminating two polyimide sheets after laying cylindrical capillaries between them according to designed geometries, we fabricated a 16-lane laminated capillary array (LCA) 9.9 cm long, 7.2 cm wide, and 0.5 mm thick in which the effective length of all capillaries was only 10.9 cm. This compact LCA thus had separation columns as short as those in capillary array electrophoresis chips fabricated by lithography techniques. Like conventional capillary arrays, it also enabled pipetting-less direct injection of analytes from sample preparation plates. Using the LCA with LIF detection and a replaceable fluid sieving matrix, we demonstrated high-speed ssDNA fragment separations. At an electric field strength of 316 V/cm, 15 fragments ranging from 50 to 500 bases were completely separated within 5.8 min in all lanes. The lane-to-lane CV of migration time was only 0.38%, and the fragment size for which the resolution per base was 0.59 was 258 +/- 15 bases (average +/-SD).

High resolution for single-strand conformation polymorphism analysis by capillary electrophoresis.

Since the successful completion of the Human Genome Project, increasing concern is being directed toward the polymorphic aspect of the genome and its clinical relevance. A form of single-strand DNA-conformation polymorphism analysis (SSCP) employing nondenaturing slab-gel electrophoresis (SGE) is applicable to the genetic diagnosis of bladder cancer from urine samples. To bring this technique into routine clinical practice, the use of capillary electrophoresis (CE) is naturally favorable in terms of speed and automation. However, the resolving power of SSCP, a prerequisite basis for reliability required in diagnostics, remains as a challenge for CE systems. We thus focused on this topic and conducted studies on CE instruments equipped with a single capillary or an array of multiple capillaries, using the resolution (Rs) as a quantitative scale for the resolving power. Polymer concentration and buffer are shown to be the decisive parameters. High Rs values of >2.5 are achieved for representative SNPs markers under the optimized conditions, without sacrificing such intrinsic advantages of CE over SGE as the 10-fold quicker migration time and operation that is reproducible, continuous, and automatic. The strategies presented broaden the limits of CE in both the current and related applications.

High-speed DNA sequencing by tube-based capillary electrophoresis.

We assessed the feasibility of high-speed DNA sequencing by tube-based capillary electrophoresis (TCE) with electrokinetic sample injections. We developed a water-circulated TCE system to control the capillary temperature precisely. Using this system and a ready-made sieving matrix at 50 degrees C, single-stranded DNA size marker fragments were separated at various pairs of the electric field strength, E, of 128-480 V/cm and the capillary effective length, L, of 100-360 mm. Assuming the read length (RL) is the fragment size at which the peak width equals the peak interval per base in obtained electropherograms, we estimated the values of RL (E, L), the RL at the pair (E, L). The points in ELz-space, (E, L, RL(E, L)), form a curved surface expressed by z = RL(E, L). Analyzing the contour lines of this curved surface, we determined the pairs of E and L providing target RLs of 300-500 bases within a minimum time. At a pair optimized for a 500-base RL (330 V/cm, 200 mm), one-color sequencing fragments were successfully separated up to 529 bases within 9.6 min. These results demonstrate that high-speed DNA sequencing comparable with that obtained by microfabricated chip-based capillary electrophoresis (MCE) can be achieved with TCE, which is more suitable in automation than MCE.

Fluorescence correlation spectroscopy excited with a stationary interference pattern for capillary electrophoresis.

Using a combination of capillary electrophoresis (CE) and patterned fluorescence correlation spectroscopy (patterned FCS), we have developed a new technique for performing electrophoretic analysis independently of the initial length of injected analyte plugs. In t histechnique, which is abbreviated as CE/patterned FCS, fluorescent analyte molecules dispersed continuously in a capillary migrate through a stationary interference pattern created by two intersecting excitation laser beams, and their fluorescence emission is monitored. We prove theoretically that the power spectrum of fluctuations in the fluorescence intensity gives a virtual electropherogram. The profile of the electropherogram and the number of theoretical plates are in general obtained by using analytical methods. Characterizing the capillary length within the excitation beams as the effective length, we compare CE/ patterned FCS with conventional CE. Numerical simulations on capillary gel electrophoresis of DNA predict that the optimized CE/patterned FCS is superior to conventional CE when the effective length is shorter than 1 cm. The experimental feasibility of this technique is demonstrated in the fluorometry of TOTO-1-stained DNA. For an effective length of 740 microm, a maximum number of plates of 7400, and a resolution of 1.0 were obtained with a one-component injection of pUC18 DNA and a two-component injection of pUC 18 DNA and lambda DNA, respectively.