JP2020085451A - Epilepsy biomarker of mouse - Google Patents

Abstract

To provide an epilepsy biomarker concerning mammals including a mouse.SOLUTION: An epilepsy biomarker of mammals contains at least one compound to be selected from a group consisting of: Methylamine, N,N-Diethyl; Methanethiol; 2-Butanone; 2-Pentanone; Disulfide, dimethyl; Methane, nitro-; 2-Heptanone; RI1227; 2-Acetyl-1-pyrroline; Dimethyl trisulfide; 7-Exo-ethyl-5-methyl-6, 8-dioxabicyclo[3.2.1]oct-3-ene; RI1449; Acetophenone; Disulfide, methyl (methylthio)methyl; and Ethanone, 1-(1H-pyrrol-2-yl)-.SELECTED DRAWING: Figure 3

Description

The present invention relates to a mouse epilepsy biomarker and the like.

Epilepsy is a frequent chronic neurological disease that affects 1% in humans and cats and an average of 2 to 3% in dogs. It is known that the cause is an idiopathic case due to a genetic predisposition or a symptomatic case due to a secondary predisposition including canceration, ischemia, hydrocephalus and the like. The underlying failure is due to an abnormal synchronous discharge of the neural network. Approximately 20 to 30% of patients and patients with epilepsy progress to refractory epilepsy that develops resistance to epilepsy drugs, and may require specialized epilepsy treatment such as adjustment of multiple antiepileptic drugs and surgical treatment. is there.
Epilepsy patients require ongoing support for a variety of life problems, such as development and schooling in children, working and driving in adults, and pregnancy and childbirth in women. A kit that can easily test the possibility of epileptic seizures will give a great deal of relief to the patient and help with welfare care support.

Epileptic seizures are the fourth leading cause of dog death. In animals where verbal communication is difficult, disease detection is often delayed, especially epileptic seizures are often found after becoming severe. In animals, invasive tests often require anesthesia, and general anesthesia is also needed when measuring EEG for epilepsy diagnosis. Therefore, a non-invasive urinalysis allows early diagnosis of epilepsy in companion animals such as dogs and cats.
In epileptic model mice, microelectrodes were inserted into the amygdala, where 50% of the onset of intractable epilepsy was the firing point, and when a minute current (450 μA, 60 Hz, 2 seconds) was applied once a day, epilepsy developed after about 3 weeks. It is an amygdala kindling model mouse. This model was developed in 1969 in rats. It is a model that induces similar epileptic seizures in all mammals such as dogs, cats, and monkeys, and was established by the present inventors in 2003 in mice (Non-patent document 20: prior art documents are collectively shown at the end. ). The symptoms of all model animals closely resemble human temporal lobe epilepsy.

However, in the above-mentioned research and development, metabolites (biomarkers) that can evaluate epileptic seizures have not been specified, leaving room for further research.
The present invention has been made in view of the above circumstances, and an object thereof is to provide a mouse epilepsy biomarker and the like.

The present inventor investigated whether the progression of epilepsy was correlated with changes in urinary volatile metabolites (VOCs). As a result of VOC profiling of epilepsy mice, we found a novel biomarker related to temporal lobe epilepsy.
Thus, the mammalian epilepsy biomarker according to the present invention includes methylamine, N,N-dimethyl-(Methylamine, N,N-dimethyl-); methanethiol; 2-butanone; -Pentanone (2-Pentanone); Disulfide, dimethyl; Methane, nitro-; 2-Heptanone; RI1227; 2-Acetyl-1-pyrroline (2-Acetyl) -1-pyrroline); Dimethyl trisulfide; 7-exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct-3-ene (7-Exo-ethyl-5) -methyl-6,8-dioxabicyclo[3.2.1]oct-3-ene); RI1449; Acetophenone; Disulfide, methyl (methylthio)methyl; Ethanone, 1-(1H -Pyrrol-2-yl)-(Ethanone, 1-(1H-pyrrol-2-yl)-), and at least one compound selected from the group consisting of:

In the above invention, 13 compounds excluding RI1227 and RI1449 are (a) ethanone, 1-(1H-pyrrol-2-yl)-; 2-acetyl-1-pyrroline; acetophenone; 2-heptanone; disulfide, methyl (Methylthio)methyl; methanethiol; (b) methylamine, N,N-dimethyl-; disulfide, dimethyl; methane, nitro-; dimethyl trisulfide; (c) 2-butanone; 2-pentanone; 7-exo- Ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct-3-ene (a) to (c) are classified into 3 groups, and at least one compound is selected from each group and included Preferably. Furthermore, it is preferable that the compound selected from (a) is methanethiol, the compound selected from (b) is disulfide, dimethyl, and the compound selected from (c) is 2-butanone.
The mammals are humans, monkeys, gorillas, orangutans, chimpanzees, horses, rhinos, tapirs, hippos, camels, giraffes, cows, pigs, goats, sheep, monkeys, antelopes, boars, bears, dogs, cats, rabbits. , Guinea pig, rat, mouse, squirrel, capybara, sloth, anteater, armadillo, bat, wolf, bear, panda, otter, sea otter, mongoose, hyena, puma, lion, tiger, jaguar, leopard, cheetah, kangaroo, koala, sea lion , Seals, elephants, whales, killer whales, dolphins and dugongs.

A method for examining epilepsy of a mammal according to another invention comprises (1) a collecting step of collecting urine derived from a mammal as a specimen, (2) concentrations of methanethiol, disulfide, dimethyl and 2-butanone from the specimen. And a measuring step for measuring.
At this time, the mammals are human, monkey, gorilla, orangutan, chimpanzee, horse, rhino, tapir, hippo, camel, giraffe, cow, pig, goat, sheep, monkey, antelope, boar, bear, dog, cat, Rabbit, guinea pig, rat, mouse, squirrel, capybara, sloth, anteater, armadillo, bat, wolf, bear, panda, otter, sea otter, mongoose, hyena, puma, lion, tiger, jaguar, leopard, cheetah, kangaroo, koala, It is preferably at least one selected from the group consisting of sea lion, seal, elephant, whale, killer whale, dolphin and dugong.

According to the present invention, a biomarker for epilepsy related to mammals is provided. These biomarkers are volatile organic compounds detected in the urine of amygdala kindling model mice, and are urinary volatile organic compounds linked to epileptic seizures that are common in mammals. It can also be applied to companion animals. The present invention can prevent accidents by applying it to a transportation company or a public facility as a primary screening at a clinical site. It can also be used for drug discovery screening using a mouse model.

It is a figure explaining preparation of epilepsy mouse and urine collection. (A) A graph showing a typical electroencephalogram of a mouse having an epileptic seizure, (B) a graph showing the number of spikes immediately after stimulation (the horizontal axis is the number of days after the start of the test (Day), the vertical axis is the number of spikes), ( C) Graph showing the duration of tonic-clonic seizures after stimulation (horizontal axis is the number of days after the start of the test (Day), vertical axis is the duration of seizures (seconds)), (D) is the duration of the frozen state Graph (horizontal axis is the number of days after the start of the test (Day), vertical axis is the duration (sec)), (E) Graph showing the stage of the mouse after the start of the test (the horizontal axis is the number of days after the start of the test (Day)) , The vertical axis is the stage. Here, the "freeze state" means a state in which the whole movement is stopped and facial cramps or partial cramps of limbs are caused. The results were as follows: Stage 1: freezing for 5 seconds or less, facial spasm, stage 2: symptom of stage 1, clonus of forelimbs and persistence of post-epileptic firing (electroencephalogram) for 5 seconds or more, stage 3 : In addition to stage 2 symptoms, freeze for 15 seconds or more, Stage 4: Stage 3 symptoms, tonic-clonic seizure and elevation due to tail tension, Stage 5: tonic-clonic seizure and falls (side) (Brain lobe epilepsy model) In graphs (B) to (E), data are shown by mean value ± SEM, and mice showing signs of stage 5 were epileptic mice. Shows the average number of days (18.9 days) that mice completely developed epileptic seizures, and shows that urine was collected from day 18.9 to day 60 in graph (E). It is a figure which shows the typical TIC chromatogram of VOC in urine of the unstimulated mouse (A) and epilepsy mouse (B) after operation. The method for acquiring the TIC chromatogram is as described in <Test method>. The numbers in the figure mean metabolites showing SI of 85% or more. The compound of each number is as follows. 1) Carbon dioxide/Carbamic acid, monoammonium salt/dl-Alanyl-l-alanine; 2) Methylamine, N,N-dimethyl-; 3) Methanethiol; 4) Acetone; 5) 2-Butanone; 6) Butanal, 2- methyl-; 7) Ethanol; 8) 2-Hexenal, 2-ethyl-; 9) 2-Pentanone; 10) 2-Pentenal, 2,4,4-trimethyl-; 11) Disulfide, dimethyl; 12) Butanenitrile, 2 -methyl-; 13) 3-Penten-2-one; 14) 1-Butanol; 15) RI1148; 16) Methane, nitro-; 17) 2-Heptanone; 18) 4-Hepten-2-one, (E) -; 19) 5-Oxohexanenitrile; 20) 2-Acetyl-1-pyrroline; 21) Dimethyl trisulfide; 22) 1-Nitro-2-methyl propene; 23) 7-Exo-ethyl-5-methyl-6,8- dioxabicyclo[3.2.1]oct-3-ene; 24) Benzaldehyde; 25) Butanoic acid, 3-methyl-; 26) Acetophenone; 27) Disulfide, methyl (methylthio)methyl; 28) Benzenamine, 3-methyl-; 29 ) Hexanoic acid, 2-ethyl-; 30) Ethanone, 1-(1H-pyrrol-2-yl)-; 31) Formamide, N-phenyl-. It is a figure which shows the result of having analyzed principal component analysis (PCA) and a dendrogram of VOC. (A) A graph showing the result of three-dimensional plotting of the principal component scores extracted from the correlation matrix using the absolute values of 15 VOCs, (B) Extracted from the correlation matrix using the absolute values of 13 VOCs A graph showing the result of three-dimensional plotting of the principal component scores, (C) Promax rotation (κ = 4) using Kaiser normalization in the principal component method using the absolute value of 13 VOCs , Converged after 5 rotations. A graph showing the results of plotting the first to third components of the pattern matrix of each VOC obtained as a result on the X, Y, and Z coordinates, (D) 13 VOCs extracted from the correlation matrix of each VOC It is a dendrogram which analyzed by the Ward method using the 1st principal component-the 6th principal component of the prepared ingredient matrix (the vertical line shows the number about the order of the absolute ingredient score sorted in descending order). The three-dimensional plots of the principal component score coefficient matrix of 13 VOCs in (B) converged between the epileptic mouse (red) and post-operative unstimulated mouse (blue) plots. In (C) and (D), it was possible to divide into 3 groups by using the pattern matrix or the component matrix obtained by the principal component method. Abbreviations for compound names shown in the figure are as follows. "2AP" is 2-Acetyl-1-pyrroline, "2B" is 2-Butanone, "2H" is 2-Heptanone, "2P" is 2-Pentanone, and "7E" is 7-Exo-ethyl-. 5-methyl-6,8-dioxabicyclo [3.2.1] oct-3-ene, "Ac" is Acetophenone, "DMT" is Dimethyl trisulfide, "DSD" is Disulfide, dimethyl, and "DSM" is Disulfide. , methyl (methylthio) methyl "Et" is Ethanone, 1-(1H-pyrrol-2-yl)-, "MeN" is Methane, nitro-, "MeT" is Methanethiol, "TMA" is Methylamine, N , N-dimethyl- (Trimethylamine) are shown respectively. The 6VOCs in (B) include 2AP, 2H, Ac, DSM, Et, and MeT, and the 8VOCs in (A) are the 6VOCs in (B) plus RI1227 and RI1449. By linear discriminant analysis stepwise method, 3 types of VOCs were extracted as biomarkers linked to epileptic seizures. The absolute value of 13 VOCs was used for the stepwise discriminant analysis using Wilks lambda. The maximum value of the significant probability of F for inputting was set to 0.05, and the minimum value of the significant probability of F for deleting was set to 0.10. Since the eigenvalue was 3.650 and the canonical correlation coefficient was 0.886, which was a high value, the epilepsy group and the post-operative unstimulated group can be discriminated well. The Wilks lambda had 0.215, the chi-square was 26.879, the degree of freedom was 3, and the significance probability was 0.000006, indicating that the epilepsy group and the post-operative unstimulated group are sufficiently separated. The standardized canonical discriminant function coefficient (contribution to separate epilepsy group from post-operative unstimulated group) was 0.772 for Methanethiol, -0.882 for 2-Butanone, and 0.677 for Disulfide, dimethyl. In addition, the original grouping was 100% discriminative, and the discriminant predictive value was 95.2% in the grouping with cross-confirmation.

Next, the embodiments of the present invention will be described with reference to the drawings, but the technical scope of the present invention is not limited to these embodiments, and various embodiments can be made without changing the gist of the invention. Can be implemented in.

<Test method>
1. Laboratory animal
(1) Animal ethics All animals were processed according to the "Proper behavior guidelines for animal experiments" (Japan Science Council, 2006). The experimental protocol was approved by the animal experiment ethics committee of Kyoto Sangyo University (approval numbers 2017-08, 2018-08).
(2) Preparation of epilepsy model mouse
8-week-old male C57BL/6J mice (CLEA Japan, Inc.) were acclimated for 1 week to relieve the stress of migration. As previously reported (Non-Patent Document 19), all surgical procedures were performed under anesthesia with isoflurane (Pfizer). A mouse under inhalation anesthesia was fixed on a brain fixation table, and the basolateral amygdala nucleus (cathode: 3 mm right from bregma, 2 mm posterior, 4.5 mm deep) with a tungsten wire electrode (Intermedical, 0.1φ × 200 mm coated) ) Was inserted underneath the dura (anode: 2.0 mm left from bregma, 1.5 mm forward), and a screw-type positive electrode (Biotex Co., Ltd.) with a width of 1.0 mm and a length of 3.0 mm was inserted. For EEG measurement, a φ1.0 mm stainless wire was inserted under the dura on both sides.

Biphasic square wave pulse (480 μA, 60 Hz) was used 10 days after surgery on unconscious mice (10 weeks old) using an electric stimulator (SEN-3301, Nihon Kohden) and an isolator (SS-202J). , 200 μs for 2 seconds) once a day. Electrical stimulation using pre-amplifier and brain amplifier (BEMCT-21 and BH-3, Low cut = 0.5, High cut = 30. Biotex Co., Ltd.) and data acquisition software SleepSign ver.2.0 (Kissei Comtec Co., Ltd.) Electroencephalographic recordings were performed before and after electrical stimulation. The number of EEG spikes and the duration of post-discharge were calculated manually based on the EEG data recorded using SleepSign ver.2.0. Epileptic seizures were basically monitored according to the modified Racine criteria (Non-Patent Document 19). Mice that received electrical stimulation daily acquired epileptic seizures (stage 5) on average 18.9 days. Urine was collected after daily stimulation from the 4th day to the 60th day (18.5 weeks old) after seizure acquisition. The collected urine was rapidly frozen under liquid nitrogen and stored in a nitrogen gas tank until just before use. As a control, unstimulated mice after surgery were used.
The creatinine concentration in urine was measured using a lab assay creatinine/colorimetric assay kit (Wako Pure Chemical Industries, Ltd.) based on the Jaffe method. The total cholesterol, alkaline phosphatase, and neutral fat (triglyceride) in plasma were measured using a lab assay colorimetric assay kit (Wako Pure Chemical Industries, Ltd.). The total protein amount was measured using a Pierce BCA protein assay kit (Thermo Fisher Scientific Co., Ltd.).

2. Reagents The following were used as standard products. Methylamine, N,N-dimethyl (25% purity ethanol solution, catalog number T2892 (Tokyo Kasei Kogyo Co., Ltd.)), 2-butanone (purity 99.0% or more (gas chromatography), catalog number E0140), 2-pentanone (purity 99.0% or more (gas chromatography), catalog number P0060), disulfide, dimethyl (purity 98.0% or more (gas chromatography), catalog number D0714), 2-heptanone (purity 98.0% or more, catalog number H0037), dimethyl-trisulfide ( Purity 98.0% or more, Catalog No. D3418), butanoic acid, 3-methyl-(Purity 99.0% or more (gas chromatography), Catalog No. M0182), Acetophenone (Purity 98.5% or more, Catalog No. A0061), Ethanone, 1-(1H -Pyrrol-2-yl)-(Purity 98.0% or more (gas chromatography), Catalog No. A0894), Formamide, N-phenyl-(Purity 99%, Catalog No. F0047, Tokyo Chemical Industry Co., Ltd.), 3-pentene, 2 -one (Purity 70%, Catalog No. 145017 (Sigma)), 1-Nitro-2-methylpropene (Purity 98.0% or more, Catalog No. sc-481890 (Santa Cruz)), n-alkane mixed solution (C9-C40: 50 μg) /mL; C10, 20, 30 and 40: 100 μg/mL, catalog number 102158321 (GL Sciences).

3. Solid-Phase Microextraction (SPME)
For the extraction of substances in urine, 50/30 μM divinylbenzene/carboxene/polydimethylsiloxane fiber ((SPME fiber) manufactured by US Supelco) was used. The SPME fiber was inserted into a vial containing 200 μL of urine and extracted at 45°C for 60 minutes. Then, the SPME fiber was inserted into the gas chromatography (GC) inlet and the SPME fiber was inserted into the gas chromatography (GC) inlet, and the volatile compound (VOC) was thermally desorbed by the splitless method at 240°C for 3 minutes. It was

4. Gas Chromatography/Mass Spectrometry (GC-MS) Analysis InertCap Pure-WAX (60m+10m) using Gas Chromatography/Mass Spectrometry (QP-2010 Ultra (Shimadzu)) with ProGuard and TL column Sample analysis was performed using a pro-guard line, a 2 m transfer line, an inner diameter of 0.25 mm, and a film thickness of 0.5 μm (manufactured by GL Sciences Inc.). The temperature of the oven depended on the following conditions. The sample was kept at 40°C for 10 minutes, heated to 240°C at a temperature increase of 5°C per minute, and then kept at 240°C for 10 minutes. Helium was used as the carrier gas, and the linear velocity was constant at a flow rate of 20 cm/sec.

The processing parameters of the mass spectrometer were as follows. The ion source temperature was 200°C, the ionization energy was 70 eV, and the scan frequency was 30 m/z to 300 m/z for 0.2 seconds per time, and the column length was 65 m. GCMSsolution ver.4.45 software (manufactured by Shimadzu Corporation) was used to convert the GC-MS raw data into mzXML format, and it was executed with version R version 3.2.3 (http://cran.r-project.org/). XCMS software package ver.1.3.2 (http://masspec.scripps.edu) was used to extract the differential ion peak (m/z) between epileptic mice and post-operative unstimulated mice. Twenty-four total ion currents (TIC) were extracted based on retention time (RT) for ion peaks identified with a hazard rate of less than 0.05 using GCMSsolution (Table 1). From the extracted TIC, the mass spectral library (NIST/EPA/NIH mass spectral library, NIST14) was searched and candidate metabolites with similar fragmentation patterns were selected. Then, the identification of each metabolite was performed by comparing the fragmentation pattern and the retention index (RI) with literature values concerning the chromatography of known compounds or similar compounds.
An automatic sampler system (Multifunctional autosampler system, manufactured by Shimadzu Corporation) was used to stably measure all samples. The concentration of metabolites was determined by calculating the ratio of the ionic peak areas of the volatiles and the peak areas of the limiting dilution external standards.

5. Statistical analysis Descriptive statistics showing the absolute area of each ion peak are shown as mean ± standard error (SEM). For the statistical processing, the Mann-Whitney U test was used, and a risk rate of 5% (p≦0.05) was statistically significant (Table 1). It is necessary to determine the accuracy of each VOC in order to know whether each VOC showing a significant difference is effective as a biomarker for separating unstimulated mice from mice with epileptic seizures after surgery. Therefore, a receiver operating characteristic curve (ROC curve) was created by plotting "sensitivity" on the vertical axis and "1-specificity" on the horizontal axis (GraphPad Prism 6). The area under the ROC curve (AUC) was determined in order to examine the difference between the unstimulated control group and the epilepsy group after surgery and to examine the accuracy of the biomarker candidate substance. In addition, exploratory data analysis using VOCs showing statistical differences was performed by principal component analysis (PCA) (IBM SPSS Statistics 25), and the prediction probabilities of belonging to the epilepsy group or post-operation unstimulated control group were investigated. Furthermore, the VOC biomarkers were divided into groups using the component factors of the extracted pattern matrix as a result of performing Promax rotation by Kaiser Normalization in the principal component method using VOCs. .. In addition, a dendrogram using the Ward method analyzed with the scores of the principal components 1 to 6 in the component matrix that does not rotate was created. Furthermore, since the F value of the Box M test (F (6, 2540) = 0.207, p = 0.975) showed homogeneity of the covariance matrix, linear discriminant analysis was performed stepwise, and biomarkers linked to epileptic seizures were performed. Was extracted (IBM SPSS Statistics 25).

<Test results and consideration>
In this study, 16 epileptic mice and 15 post-operative unstimulated mice (control group) were examined. Stimulation of the amygdala once a day increased the number of spikes during post-epileptic firing, prolongs the post-epileptic firing period, and finally induced epileptic seizures (Fig. 1). Urine samples were collected from 13.5 to 18.5 weeks after epileptic seizure.
1. Identification of VOC in urine of epileptic mice by SPME-GCMS Fig. 2 shows a typical chromatogram when urinary VOCs of epileptic mice and unstimulated mice after surgery were examined by SPME-GCMS TIC. The VOC profiles of both groups were very similar.
Analysis using GC-MS (Shimadzu QP-2010 Ultra, TQ-8040) identified 135 metabolites in the urine of both groups of mice. The chemical structures of metabolites included many types such as aldehydes, ketones, nitrogen compounds, terpenes, carboxylic acids, alcohols, benzene compounds, furans, and sulfur compounds. As shown in Table 1, 24 VOCs were identified from the fragment ion m/z values of different VOCs obtained from the samples of both groups by the analysis using XCMS. Next, the VOC fragment ion m/z value with the largest area within each of these 24 VOC fragmentation patterns was selected for comparison of the absolute values of the areas between the two groups (Table 1, column 3). , 15 potential biomarkers were obtained (p<0.05: 16th column of Table 1). Among the obtained compounds, unknown compounds for which no corresponding value was found in the literature value or known compound database were displayed using the retention index (RI) number.

2. Receiver Operating Characteristic curve (ROC curve)
ROC curves of 15 VOCs were prepared and the cutoff value was set. To assess the ability of the 15 biomarker candidates in epileptic seizures, the sensitivity, specificity, accuracy and area of the area under the ROC curve (AUC) at the cutoff point were calculated (Table 2). A statistical analysis of each compound that was statistically significant showed that the AUC of the ROC curve for disulfide dimethyl was accurate to 0.8571 (Sensitivity = 0.8182, Specificity = 0.9000). Showed good accuracy (0.9091 (95% CI, 0.7046 to 1.041)). The AUC for RI1227 was 0.9071 (95% CI, 0.7532 to 1.065) with an accuracy of 0.9048 (sensitivity = 0.9091, specificity = 0.9000).

On the other hand, for 2-butanone, no false negative was observed and the sensitivity was 1, and for disulfide and methyl(methylthio)methyl, false positive was not observed and the sensitivity was 0.9091. Of the 15 biomarker candidates, 14 VOCs except for 7-exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct-3-ene had an AUC of 0.8 or higher. ，It showed high potential as a biomarker for predicting epileptic seizures. Furthermore, for 11 compounds except nitromethane (Methane, nitro-), 7-exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct-3-ene, RI1227, RI1449, It has been identified for both mouse and human species (http://www.hmdb.ca).
Since 15 VOCs are a large biomarker group, we tried to classify them into several small groups. Therefore, we performed principal component analysis (PCA) to reduce the number of variables, classified VOCs using a dendrogram, and narrowed down the numbers using linear discriminant analysis.

3. Principal component analysis (PCA) and dendritic diagram 15 VOCs that were found to be different in the urine of epileptic mice and unstimulated mice after surgery, and 15 of these were excluded from unknown components, RI1227 and RI1449. PCA was performed on 13 VOCs. The 15 potential biomarkers tended to be separable by a 3D PCA score plot. The p variables of the eigenvalues of the correlation matrix at 15 VOCs and 13 VOCs were 58.85% and 55.35% for the first principal component (PC1). The second main component (PC2) had 16.03% and 17.20%, and the third main component (PC3) had 10.99% and 12.51%. Cumulatively, it was 85.87% and 85.06% with 15 VOCs and 13 VOCs, respectively. The standardized principal component (PC) scores of epileptic mice (red circles) were separated from the scores of unstimulated mice (blue circles) after surgery by the component scores (transparent circles) of the principal component score coefficient matrix for each VOC. At this time, the component scores of 15 and 13 VOCs on PC1 to PC3 were concentrated near zero (transparent circles) (Figs. 3A and 3B). These results indicate that urinary VOCs can be separated between epileptic mice and unstimulated mice after surgery.

Then, we applied the rotation method using Promax with Kaiser normalization by the principal component method using 13 VOCs, and as a result, converged in 5 iterations. In the factors of the pattern matrix of each VOC obtained as a result, ethanone, 1-(1H-pyrrol-2-yl)-(1.031), 2-acetyl-1-pyrroline (0.994), acetophenone (0.915), 2- Heptanone (0.904), disulfide, methyl (methylthio)methyl (0.846) and methanethiol (0.804) 6 showed high load in the first factor (low load in the second and third factors), methylamine, N ,N-Dimethyl-(0.990), disulfide, dimethyl (0.722), methane, nitro- (0.623) and dimethyl trisulfide (0.542) showed high load in the second factor (low in the first and third factors). Load), 2-butanone (0.929), 2-pentanone (0.863) showed a high load in the third factor, 7-exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct- 3-ene (0.306, -0.991, 0.177) showed low loading in the first and second factors. Based on these scores, 13 VOCs were classified into 3 groups (Fig. 3C). In addition to the promax method, a hierarchical clustering analysis was performed using the scores of 6-dimensional principal components extracted from the correlation matrix of 13 VOCs of PCA, and as a result, 3 groups of VOCs were obtained (Fig. 3D). .. Each VOC belonging to these three groups was similarly classified between the Promax method and the dendrogram.

4. Linear discriminant analysis Since the F value (F(6, 2540)=0.207) of the Box M test showed homogeneity of the covariance matrix, linear discriminant analysis was performed. For 13 known VOCs, a stepwise method using Wilks' lambda was performed while automatically selecting the best variables. As a variable selection condition, the maximum F value was 0.05 and the minimum value was 0.10. As a result, the eigenvalues of the canonical correlation were 0.886, the Chi-square value of Wilk's lambda was 26.897, f was 3, and p was 0.000006. The standardized discriminant function coefficients were 0.772 for methanethiol, -0.882 for 2-butanone, and 0.677 for disulfide and dimethyl. The obtained discriminant function was as follows when methanethiol was described as [MeT], 2-butanone as [2B], and disulfide and dimethyl as [DSM].

Equation 1: -0.53887155117 + 0.00004396261 * [MeT]-0.00000537535 * [2B] + 0.00004072790 * [DSM].
However, the value in parentheses in the formula indicates the absolute area of the ion peak m/z of each VOC.
By using the above formula, the discriminant score of the epilepsy mouse (black circle: Kindling) and the post-operative unstimulated mouse (white circle: Sham) was calculated (FIG. 4).
Using the three best biomarkers, methanethiol, 2-butanone and disulfide dimethyl, it was found that epileptic mice and control mice could be clearly separated to 100% discrimination. As a result of crossing confirmation, the discriminant predictive value was 95.2%. Each of these three VOCs was separated in the Promax method (Fig. 3C) and the dendrogram (Fig. 3D).

5. Based on the results of this test and the findings of the present inventor, the following conclusions were obtained.
(1) We obtained 15 compounds as biomarkers of urinary VOCs associated with epileptic seizures. These are methylamine, N,N-dimethyl-(Methylamine, N,N-dimethyl-); methanethiol; 2-butanone; 2-pentanone; disulfide, dimethyl. (Disulfide, dimethyl); Methane, nitro-; 2-Heptanone; RI1227; 2-Acetyl-1-pyrroline; Dimethyl trisulfide ( Dimethyl trisulfide); 7-exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct-3-ene (7-Exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2. 1]oct-3-ene); RI1449; Acetophenone; Disulfide, methyl (methylthio)methyl; Ethanone, 1-(1H-pyrrol-2-yl)-(Ethanone, There were 15 of 1-(1H-pyrrol-2-yl)-). Of these 15 compounds, RI1227 and RI1449 are undetermined compounds, so 13 compounds other than these 2 compounds may be used as biomarkers.

(2) Of the above 15 biomarker substances, 13 biomarkers except RI1227 and RI1449, which are undetermined substances, were roughly classified into the following 3 groups (a) to (c). .. That is, (a) ethanone, 1-(1H-pyrrol-2-yl)-, 2-acetyl-1-pyrroline, acetophenone, 2-heptanone, disulfide, methyl(methylthio)methyl, methanethiol; (b) methylamine ,N,N-Dimethyl-, disulfide, dimethyl, methane, nitro-, dimethyl trisulfide; (c) 2-butanone, 2-pentanone, 7-exo-ethyl-5-methyl-6,8-dioxabicyclo [3.2.1] It was octo-3-ene.

(3) Of the groups (a) to (c) above, by determining at least one biomarker (three or more in total) from each group and measuring the urinary concentration, the extent of progress of epilepsy, Evaluate the possibility of epileptic seizures.
(4) The best combination of the above three or more biomarkers was methanethiol, disulfide, dimethyl and 2-butanone. When these three are used as biomarkers, they can be clearly separated between patients (cattle) who have epileptic seizures and control groups.
(5) Since the biomarker can be extracted from urine that can be collected non-invasively, it is not necessary to injure humans and/or animals.

Thus, according to the present embodiment, a biomarker for epilepsy can be provided. These biomarkers are volatile organic compounds detected in the urine of amygdala kindling model mice, and are urinary volatile organic compounds linked to epileptic seizures that are common in mammals. It can also be applied to companion animals. The present invention can prevent accidents by applying it to a transportation company or a public facility as a primary screening at a clinical site. It can also be used for drug discovery screening using a mouse model.

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Claims (6)

Methylamine, N,N-Dimethyl-(Methylamine, N,N-dimethyl-); Methanethiol; 2-Butanone; 2-Pentanone; Disulfide, Disulfide dimethyl); Methane, nitro-; 2-Heptanone; RI1227; 2-Acetyl-1-pyrroline; Dimethyl trisulfide ; 7-Exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct-3-ene (7-Exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct -3-ene); RI1449; Acetophenone; Disulfide, methyl (methylthio)methyl); Ethanone, 1-(1H-pyrrol-2-yl)-(Ethanone, 1-( 1H-pyrrol-2-yl)-) comprising at least one compound selected from the group consisting of 1H-pyrrol-2-yl)-). The biomarker according to claim 1, wherein 13 compounds except for RI1227 and RI1449 are (a) ethanone, 1-(1H-pyrrol-2-yl); 2-acetyl-1-pyrroline; acetophenone; 2- Heptanone; disulfide, methyl(methylthio)methyl; methanethiol; (b) methylamine, N,N-dimethyl-; disulfide, dimethyl, methane, nitro-; dimethyl trisulfide; (c) 2-butanone; 2-pentanone ; 7-exo-ethyl-5-methyl-6,8-dioxabicyclo[3.2.1]oct-3-ene (a) to (c), classified into 3 groups, at least one compound from each group The mammalian epilepsy biomarker according to claim 1, which comprises: The biomarker according to claim 2, wherein the compound selected from (a) is methanethiol, the compound selected from (b) is disulfide, dimethyl, and the compound selected from (c) is 2-butanone. The mammal epilepsy biomarker according to Item 2. The mammal is a human, monkey, gorilla, orangutan, chimpanzee, horse, rhinoceros, tapir, hippo, camel, giraffe, cow, pig, goat, sheep, monkey, antelope, boar, bear, dog, cat, rabbit, guinea pig. , Rat, mouse, squirrel, capybara, sloth, anteater, armadillo, bat, wolf, bear, panda, otter, sea otter, mongoose, hyena, puma, lion, tiger, jaguar, leopard, cheetah, kangaroo, koala, sea lion, seal The epilepsy biomarker for mammals according to any one of claims 1 to 3, which is at least one selected from the group consisting of, elephants, whales, orcas, dolphins, and dugongs. An epilepsy test method for a mammal, comprising (1) a collecting step of collecting urine derived from a mammal as a sample, and (2) a measuring step of measuring the concentrations of methanethiol, disulfide, dimethyl and 2-butanone from the sample. The mammal is a human, monkey, gorilla, orangutan, chimpanzee, horse, rhinoceros, tapir, hippo, camel, giraffe, cow, pig, goat, sheep, monkey, antelope, boar, bear, dog, cat, rabbit, guinea pig. , Rat, mouse, squirrel, capybara, sloth, anteater, armadillo, bat, wolf, bear, panda, otter, sea otter, mongoose, hyena, puma, lion, tiger, jaguar, leopard, cheetah, kangaroo, koala, sea lion, seal The method for inspecting epilepsy of a mammal according to claim 5, wherein the method is at least one selected from the group consisting of, elephant, whale, killer whale, dolphin and dugong.