JP4090821B2 - Genetic diagnostic apparatus and genetic diagnostic method - Google Patents

Description

【図面の簡単な説明】
【図１】本発明の実施の形態１における遺伝子診断装置の外観図
【図２】本発明の実施の形態１における遺伝子診断装置の上蓋開放外観図
【図３】本発明の実施の形態１における遺伝子診断装置の装置構成図
【図４】本発明の実施の形態１における遺伝子診断装置の制御回路要部図
【図５】本発明の実施の形態１における遺伝子診断装置の分離用ＤＮＡ結合物質を用い試料ＤＮＡおよび正常ＤＮＡを電気泳動させる本発明における選択性分離フィルターを終点近傍にのみ付属した密閉流路の構造図
【図６】本発明の実施の形態２における実施の形態１で説明した選択性分離フィルターを密閉流路の両端に装着した図
【図７】本発明の実施の形態３における実施の形態１で説明した選択性分離フィルターを密閉流路の終点近傍に装着し、実施の形態１、２に記載の選択性分離フィルターよりも大量の高分子を捕捉することができる第２の選択性分離フィルター（プレフィルター）を最上流部装着した図
【図８】本発明の実施の形態４における実施の形態１で説明した選択性分離フィルターを密閉流路の両端に装着し、実施の形態３で説明したプレフィルターを密閉流路の始点近傍に装着した図
【図９】本発明の実施の形態５における実施の形態１で説明した選択性分離フィルターを密閉流路の両端に装着し、実施の形態３で説明したプレフィルターを密閉流路の両端に装着した選択性分離フィルターよりもさらに開始点および終点に近いところにそれぞれ装着した図
【図１０】本発明の実施の形態６における実施の形態１で説明した選択性分離フィルターを密閉流路の両端に装着し、密閉流路の両端に検出のための透明な検出窓を設けた図
【図１１】本発明の実施の形態１における遺伝子診断装置の密閉流路内の分離用ＤＮＡ結合物質と試料ＤＮＡとの関係概念図
【図１２】経過時間と吸光度の関係図
【符号の説明】
１ 電源スイッチ
２ 操作ボタン
３ 表示パネル
４ 上蓋
５ 筐体
６ 電気泳動部
７ 支持台
８ 制御演算部
９ 電源ボックス
９ａ 電源部
１０ 検出部
１０ａ Ｄ₂ランプ
１０ｂ スリット
１０ｃ フォトダイオード
１５ｄ プリアンプ
１０ｅ Ａ／Ｄコンバータ
１１ 温調器
１２，１３ 電極
１４，１４ｃ 緩衝液
１４ａ，１４ｂ 容器
１４ｄ リニアポリマー
１５ キャピラリー管
１６ 吸引ポンプ
１７ 選択性分離フィルター
１８ 選択性分離プレフィルター
１９ 検出窓
２０ 分離用ＤＮＡ結合物質
２１ 試料ＤＮＡ[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a genetic diagnostic apparatus and a genetic diagnostic method that can easily and accurately detect the presence / absence of a genetic abnormality, and in particular, it is possible to reuse a DNA-binding substance for separation that is necessary for determination without throwing it away. The present invention relates to a genetic diagnostic apparatus and a genetic diagnostic method.
[0002]
[Prior art]
All diseases involve genetic factors and environmental factors with various probabilities, but diseases such as congenital metabolic disorders, cancer, diabetes, hypertension, Alzheimer, autoimmune diseases, atopy, obesity, and alcoholism Hereditary factors account for a very large proportion. On the other hand, diseases that have a large contribution of environmental factors include diseases caused by infections and aftereffects of trauma.
[0003]
By the way, due to the rapid development of molecular biology in recent years, genetic elements, that is, gene involvement in various diseases have been elucidated fairly accurately, and attention has been focused on gene-targeted medicine. Yes. At present, what is attracting the most attention is SNPs (snips). This is an abbreviation for single nucleotide polymorphism, which is generally translated as “single nucleotide polymorphism”, and is a general term for differences in one code (one base) in genes between individuals.
[0004]
All life-form genes on earth, including humans (or the genome that means the entire collection of genes), are composed of four common bases, and various proteins are created by the sequence of these bases. Life activities are taking place. The four bases common to all organisms are adenine (denoted as A), guanine (denoted as G), thymine (denoted as T), and cytosine (denoted as C). Human genes are said to be composed of about 3 to 3.2 billion base sequences, but each individual has a base that is different from other people at a rate of about one in several hundred to 1000 bases. Exists. Usually, this single base change is present at a frequency of 1% or more in the total population of a certain human population, and is called SNPs.
[0005]
Therefore, it is said that there are 3 to 10 million SNPs in all genes (genome), and the search for SNPs is currently continued all over the world. The reason why SNPs are attracting attention is that it is considered that the morbidity rate for many diseases, which are said to be statistically related to the genes of each individual, can be estimated by the classification of SNPs. For example, taking breast cancer as an example, SNPs common to those who are likely to have breast cancer can be identified by comparing SNPs between a group of patients with breast cancer and a normal group. At the time of a health examination, it becomes possible to find a person who has investigated the gene and has the SNPs, that is, a person who is normal but is likely to have breast cancer in the future.
[0006]
With this diagnosis, a person with a constitution that is likely to have breast cancer can be treated very early, and the possibility of survival can be improved even if he / she suffers from cancer. The same can be said for lifestyle-related diseases such as diabetes and hypertension, and it is possible to accurately diet and guide living before the onset of diseases that many people around the world suffer.
[0007]
In addition, SNPs are expected to play an important role regarding drugs used for treatment of diseases. Drugs used during treatment are not equally effective for everyone. In general, it is well known that drugs are effective for a certain proportion of people but not for others at all, and may cause adverse results due to side effects. Incidentally, it is well known that drug side effects are at the top of the causes of death in the United States. The effect of the drug is deeply related to the constitution of the person, and the constitution is said to be distinguishable by the classification of SNPs. That is, the classification based on the analysis of SNPs makes it possible to predict the effect and sensitivity of a certain drug in advance and make an appropriate prescription, and the optimal drug administration and risk of side effects according to the individual patient's constitution. Avoidance is expected. Such medical care is called tailor-made medical care or tailor-made medical care, and future practical use is surely expected.
[0008]
In addition, it is known that cancer is caused by a mutation occurring at a specific site on a gene that plays an important role in normal cells, for example, by the action of ultraviolet rays or mutagenic substances. By reading a mutation on a specific gene, it becomes possible to diagnose from an early stage whether or not a cell is cancerous. SNPs are also effective in identifying criminals in criminal investigations, determining ambiguous parent-child relationships, and identifying whether or not they are individuals. As described above, there are 3 to 10 million SNPs in each individual, and since there are separate SNPs from parents, there are absolutely no humans on the planet who have the same SNPs even if they are parents and siblings. It is said not to. This is the reason why complete identification of individuals is possible.
[0009]
In this manner, observing a mutation that occurs at one base in a specific gene may greatly contribute to various matters including medical treatment. However, at present, the method of observing a mutation of a specific gene requires a very complicated operation or an expensive apparatus as described below, and the running cost is very high, so that it has not yet been widely used. is there.
[0010]
The most commonly used method for examining SNPs at present is a method called sequencing (determining the base sequence) in which the base sequence of DNA is directly read from the end. Since a gene is a unit of DNA having base sequence information for forming one kind of protein, SNPs can be elucidated by reading the base sequence from the end. There are several reports on the sequencing method, but the most commonly performed method is dideoxy sequencing (Sanger method) described below. All of these methods, including this method, are based on a technique that can separate and identify the difference in length of one base length by denaturing polyacrylamide gel electrophoresis or capillary electrophoresis with high resolution.
[0011]
The dideoxy sequencing (Sanger method), also called enzymatic sequencing, uses DNA polymerase to synthesize complementary strands of single-stranded template DNA, and then produces four special types of dideoxynucleotides artificially created. The feature is to use. As a sequencing operation, a synthetic base sequence that complements the 3 'end of the single-stranded DNA to be sequenced is used as a primer, and deoxynucleotides added equally from the primer to DNA polymerase are extended by an enzymatic reaction. At this time, four reaction vessels were prepared at the same time, and each did not have a hydroxyl group at the 3 'end of the ATGC four bases, and therefore dideoxynucleotide, a base analog that could not continue the DNA extension reaction any more. Mix a small amount separately. As a result, DNA synthesis was stopped when dideoxynucleotide was added to the end of the extending DNA, and each reaction vessel had various lengths, but the ends were always added base analogs. Stranded DNA is formed. The reaction vessel is reacted with S1 endonuclease to digest all the single-stranded DNA into only double-stranded DNA. If the DNA strands of the four reaction vessels thus obtained are subjected to gel electrophoresis or capillary electrophoresis, and the separated DNA is read in order from the shorter one (moved faster), the base sequence of the DNA complementary to the template strand will be Recognize. At this time, the electrophoresis results are identified by, for example, radioactively labeling the added dideoxynucleotide phosphorus or sulfur or binding a fluorescent chemical substance. In the case of a radioactive label, detection is performed by exposure to a film. In the case of a fluorescent chemical substance, fluorescence is detected by irradiating a laser beam. Recently, a method has been developed in which four types of base analogs A, T, G, and C are labeled with four types of reagents having different fluorescence wavelengths, and the four colors of fluorescence are simultaneously detected.
[0012]
In this way, the conventional base sequence of a gene isolated and purified from a subject is determined by this dideoxy sequencing (Sanger method) or other base sequence determination method, and compared with a normal or standard base sequence. Confirmation of the presence of SNPs and mutations, identification of individuals, etc.
[0013]
[Problems to be solved by the invention]
As described above, genetic diagnosis and identification of individuals by gene using conventional gene sequencing methods are performed by isolating the target gene, then amplifying and purifying it, and using a device for determining the base sequence of the gene. Since it was performed by reading the base sequence of the target gene, the experiment required a huge amount of work, a very long time, and a great running cost. In addition, an automated apparatus for determining a base sequence is very expensive, occupies a large space, and requires a large amount of expensive reagents.
[0014]
Therefore, in order to solve such a conventional problem, the present invention can detect a genetic abnormality of one or more nucleotides in a short time, easily and accurately, and is small, light and inexpensive, and has a very low running cost. An object of the present invention is to provide a genetic diagnostic apparatus and a genetic diagnostic method capable of automating diagnosis.
[0015]
In addition, the present invention makes it possible to repeatedly use a DNA binding substance for separation, which is used for separating and measuring the normal type and the abnormal type of the gene to be determined, and has a large molecular weight derived from chromosomal DNA or blood. Provided are a genetic diagnostic device and a genetic diagnostic method that can remove noise substances, simplify diagnostic devices, reduce diagnostic costs, and realize highly accurate determination.
[0016]
[Means for Solving the Problems]
In order to solve the above problems, a genetic diagnosis apparatus of the present invention includes a first container that contains a buffer solution and is immersed in a first electrode, a second container that contains a buffer solution and is immersed in a second electrode, A sealed flow path in which a container containing a linear polymer and a DNA binding control agent is filled between the first container and the second container, a positive potential or a negative potential is applied to the second electrode, and a negative potential or a positive potential is applied to the first electrode. A power supply unit that applies a potential, a control unit that controls the power supply unit to apply a voltage between the second electrode and the first electrode, and a detection that is provided in the sealed channel and detects the amount of DNA passing through the inside. In the closed channel, the base sequence capable of hydrogen bonding to the sample DNA and the polymer compound are combined in the buffer solution, and the sample DNA is separated into normal DNA and abnormal DNA from the difference in binding force. A DNA binding substance for separation and sample DNA, Provided with a selective separation filter that allows the sample DNA to pass at least on the side of the electrophoresis direction and does not allow the DNA binding substance for separation to pass through, the sample DNA in the sealed channel is electrophoresed by applying a voltage, and the detection unit Is configured to measure the passing amount of normal DNA and / or abnormal DNA.
[0017]
Thereby, it becomes possible to repeatedly use the DNA binding substance for separation, and it is possible to prevent variations in measurement results due to noise DNA derived from chromosomes and the like. As a result, a genetic abnormality of one or more bases can be detected easily and accurately in a short time, and the diagnosis can be automated with a small size, light weight, low cost, and very low running cost.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
The invention according to claim 1 is a first container in which a buffer solution is stored and a first electrode is immersed, a second container in which a buffer solution is stored and a second electrode is immersed, and a first container and a second container. A sealed channel that is connected by filling a buffer containing a linear polymer and a DNA binding controller, and a power supply unit that applies a positive potential or a negative potential to the second electrode and applies a negative potential or a positive potential to the first electrode A control unit that controls the power supply unit to apply a voltage between the second electrode and the first electrode, and a detection unit that is provided in the sealed flow path and detects the amount of DNA passing through the inside. In the path, there is a DNA binding substance for separation in which a base sequence capable of hydrogen bonding to the sample DNA and the polymer compound are bound in a buffer solution, and the sample DNA is separated into normal DNA and abnormal DNA from the difference in binding strength. Sample DNA and at least on the electrophoresis direction side of the sealed channel Provided with a selective separation filter that allows sample DNA to pass and does not allow separation of DNA binding substances, and the sample DNA in the sealed channel is electrophoresed by applying a voltage, and the detection part is normal DNA and / or abnormal DNA It is characterized in that the amount of passage of is measured.
[0019]
In this way, by using electrophoresis and DNA hydrogen bonding, it is possible to determine the presence or absence of abnormality in the sample DNA by observing the separation or non-separation of the sample DNA and normal DNA. By reusing substances and removing noise generated from chromosome-derived DNA, it is possible to provide a device that can reduce running costs by repeated measurement and perform more accurate determination.
[0020]
Then, after the electrophoresis is completed and the result is judged, the sample DNA and the normal DNA are all flowed off by energizing for a long time. As a result, the separation DNA binding substance is present in the vicinity of the end of the closed flow path in the same direction as the electrophoresis. concentrate. By energizing the closed channel with a potential opposite to the measurement, the separation DNA-binding substance can be returned to the state before the measurement, and repeated measurement can be performed without replenishing the separation DNA-binding substance. It can also be done.
[0021]
The invention according to claim 2 is the method according to claim 1, wherein sample DNA and normal DNA used as a control are allowed to pass through the sealed channel, and a higher molecular weight substance is not allowed to pass through. A selective separation prefilter capable of capturing a polymer is provided, and a DNA binding substance for separation is sandwiched between the selective separation filter and the selective separation prefilter.
[0022]
Therefore, even if impurities such as DNA or protein having a large molecular weight are mixed in the sample to be measured, accurate measurement can be performed without being detected as noise.
[0023]
According to a third aspect of the present invention, there is provided a first container in which a buffer solution is stored and the first electrode is immersed, a second container in which the buffer solution is stored and the second electrode is immersed, and the first container and the second container. A sealed channel that is connected by filling a buffer containing a linear polymer and a DNA binding controller, and a power supply unit that applies a positive potential or a negative potential to the second electrode and applies a negative potential or a positive potential to the first electrode A control unit that controls the power supply unit to apply a voltage between the second electrode and the first electrode, and a detection unit that is provided in the sealed flow path and detects the amount of DNA passing through the inside. In the path, there is a DNA binding substance for separation in which a base sequence capable of hydrogen bonding to the sample DNA and the polymer compound are bound in a buffer solution, and the sample DNA is separated into normal DNA and abnormal DNA from the difference in binding strength. A sample DNA and sandwiching a DNA binding substance for separation in a sealed channel In addition, the sample DNA in the sealed flow path is electrophoresed by applying a voltage so that the sample DNA can pass through, and the selective separation filter that does not allow the DNA binding substance for separation to pass through is applied. It is characterized by measuring the passing amount of abnormal DNA.
[0024]
Therefore, when the electrophoresis is completed and the result is judged, the sample DNA and the normal DNA are all flowed off by energizing for a long time, and as a result, the separation DNA binding substance concentrates in the vicinity of the end of the sealed channel. By energizing the closed channel with a potential opposite to that of the measurement after the measurement is completed, the separation DNA-binding substance can be returned to the state before the measurement, without replenishing the separation DNA-binding substance. It can be used for repeated measurement. By attaching filters to both ends, it is possible to minimize the loss of the DNA binding substance for separation. The same effect can be obtained not by the operation of applying a reverse potential but by taking out only the closed flow channel and exchanging it before and after the measurement.
[0025]
According to a fourth aspect of the present invention, in the third aspect, the sample DNA and the normal DNA used as a control can pass at least upstream of the selective separation filter located on the opposite side of the electrophoretic direction of the sealed channel. Further, the present invention is characterized in that a selective separation prefilter capable of capturing a larger amount of polymer than a selective separation filter without passing a higher molecular substance is provided.
[0026]
Therefore, even if impurities such as DNA or protein having a large molecular weight are mixed in the sample to be measured, accurate measurement can be performed without being detected as noise.
[0027]
A fifth aspect of the present invention is the method according to the third aspect, wherein the sample DNA and normal DNA used as a control are allowed to pass through so as to sandwich the selective separation filter of the sealed channel, and a higher molecular weight substance is not allowed to pass through. And a selective separation prefilter capable of capturing a larger amount of polymer than the selective separation filter.
[0028]
Therefore, by supplying a potential opposite to the measurement to the closed channel after the measurement is completed, the DNA binding substance for separation can be returned to the state before the measurement, and noise that is captured by the prefilter can be increased. It is possible to remove molecular substances. Thereby, it becomes possible to use for the measurement repeatedly, without newly replenishing the DNA binding substance for separation. The same effect can be obtained not by the operation of applying a reverse potential but by taking out only the closed flow channel and exchanging it before and after the measurement.
[0029]
A sixth aspect of the present invention provides the method according to any one of the second to fifth aspects, wherein the detection windows for detecting the amount of DNA passing through the inside of the closed flow path are respectively sealed flow so as to sandwich at least the separation DNA binding substance. It is provided on both sides of the road.
[0030]
Therefore, it can be determined whether the sample DNA is normal or abnormal without removing or replacing the sealed channel.
[0031]
The invention described in claim 7 is characterized in that, in claim 2, the sealed flow path portion including the region sandwiched between the selective separation filter and the selective separation prefilter is detachable.
[0032]
Therefore, a part of the flow path can be formed into a cartridge or a chip, and since the separation DNA binding substance does not flow out by the measurement, a plurality of measurements can be performed.
[0033]
In addition, even if the sealed flow channel portion is turned over after the measurement is completed and the determination is performed again, even if the measurement is repeated many times, the amount of DNA passing through only one detection window can be measured. it can. In this case, the detection window is positioned outside the unit with the selective separation filter and the closed flow path as one unit, and the measurement is not affected even if the unit is freely replaced.
[0034]
The invention described in claim 8 is characterized in that, in claims 3 to 5, the sealed flow path portion including at least the region sandwiched between the selective separation filters is detachable.
[0035]
Therefore, a part of the flow path can be formed into a cartridge or a chip, and since the separation DNA binding substance does not flow out by the measurement, a plurality of measurements can be performed. In addition, even if the sealed flow channel portion is turned over after the measurement is completed and the determination is performed again, even if the measurement is repeated many times, the amount of DNA passing through only one detection window can be measured. it can.
[0036]
The invention described in claim 9 is characterized in that, in claim 8, the sealed flow path portion including the selective separation prefilter is detachable.
[0037]
Therefore, even if impurities such as DNA or protein having a large molecular weight are mixed in the sample to be measured, accurate measurement can be performed without being detected as noise.
[0038]
The invention according to claim 10 is a first container in which a buffer solution is stored and the first electrode is immersed, a second container in which the buffer solution is stored and the second electrode is immersed, and the first container and the second container. A sealed channel that communicates with a buffer containing a linear polymer and a DNA binding controller, and a power supply unit that applies a positive or negative potential to the second electrode and a negative or positive potential to the first electrode A control unit that controls the power supply unit to apply a voltage between the second electrode and the first electrode, and a detection unit that is provided in the sealed flow path and detects the amount of DNA passing through the inside. A member that can be attached to and detached from the path, and when attached to the sealed channel, a base sequence capable of hydrogen bonding to the sample DNA and a polymer compound are bonded to the member that forms part of the sealed channel. DNA binding for separation that separates sample DNA into normal DNA and abnormal DNA from the difference in force The sample DNA can be passed so as to sandwich the quality and the DNA binding substance for separation, a selective separation filter that does not allow the DNA binding substance for separation to pass is provided, the sample DNA is introduced into the sealed channel, and a voltage is applied. Thus, the sample DNA in the closed channel is electrophoresed, and the detection unit measures the passing amount of normal DNA and / or abnormal DNA.
[0039]
Therefore, a part of the flow path can be formed into a cartridge or a chip, and since the separation DNA binding substance does not flow out by the measurement, a plurality of measurements can be performed.
[0040]
The invention according to claim 11 is the method according to claim 10, wherein one of the selective separation filters allows passage of sample DNA and normal DNA used as a control, does not pass higher molecular weight substances, and is more selective than the selective separation filter. A selective separation prefilter capable of capturing a large amount of polymer is used.
[0041]
Therefore, even if impurities such as DNA or protein having a large molecular weight are mixed in the sample to be measured, accurate measurement can be performed without being detected as noise.
[0042]
The invention according to claim 12 is the selective separation filter according to claim 10, which allows the sample DNA and normal DNA used as a control to pass through so as to sandwich the selective separation filter, and does not allow a higher-molecular substance to pass through. It is characterized by having a selective separation prefilter capable of capturing a larger amount of polymer than that.
[0043]
Therefore, even if impurities such as DNA or protein having a large molecular weight are mixed in the sample to be measured, accurate measurement can be performed without being detected as noise.
[0044]
The invention according to claim 13 is characterized in that the closed flow path is a capillary tube, and efficient electrophoresis is possible.
[0045]
The invention described in claim 14 is characterized in that, in claim 13, the inner wall of the capillary tube is coated with acrylamide, and electroosmotic flow can be prevented.
[0046]
According to the fifteenth aspect of the present invention, the buffer solution is stored in the first container and the first electrode is immersed, the buffer solution is stored in the second container and the second electrode is immersed, and the first container and the second container A selective flow filter that allows sample DNA to pass through at least the electrophoresis direction side of the closed flow channel and does not pass a DNA binding substance for separation; and hydrogen bond to the sample DNA A closed channel containing a DNA binding substance for separation that separates sample DNA into normal DNA and abnormal DNA from the difference in binding force when the base sequence and the polymer compound are combined, and contains a linear polymer and a DNA binding control agent. Fill the buffer, introduce the sample DNA into the sealed channel, apply a voltage between the first electrode and the second electrode, electrophores the sample DNA in the sealed channel, and extract normal DNA and / or abnormal DNA. Genetics characterized by detection A diagnostic method, it is possible to achieve improved reproducibility and cost reduction of the determination.
[0047]
The invention according to a sixteenth aspect is the same as the fifteenth aspect, wherein the sealed channel allows the sample DNA and normal DNA used as a control to pass therethrough, does not pass a higher molecular weight substance, and has a larger amount than the selective separation filter. A genetic diagnosis method comprising a selective separation prefilter capable of capturing a macromolecule, wherein a separation DNA binding substance is sandwiched between the selective separation filter and the selective separation prefilter. In addition to improving the reproducibility of the determination and reducing the cost, the lifetime of the first selective separation filter, which aims to newly reduce the measurement noise and capture the DNA binding substance for separation, can be extended.
[0048]
According to the seventeenth aspect of the present invention, the buffer solution is stored in the first container and the first electrode is immersed, the buffer solution is stored in the second container and the second electrode is immersed, and the first container and the second container A separation channel that separates sample DNA into normal DNA and abnormal DNA based on the difference in binding strength, which is a closed flow channel that connects the DNA and a base compound capable of hydrogen bonding to the sample DNA. And a buffer containing a linear polymer and a DNA binding control agent in a closed flow path that includes a selective separation filter that allows sample DNA to pass therethrough and does not pass the separation DNA binding material so that the separation DNA binding material is sandwiched therebetween. Fill the solution, introduce the sample DNA into the sealed channel, apply a voltage between the first electrode and the second electrode, electrophores the sample DNA in the sealed channel, and detect normal DNA and / or abnormal DNA Genetic diagnosis characterized by A method, it is possible to achieve improved reproducibility and cost reduction of the determination.
[0049]
In the invention described in claim 18, a buffer solution is accommodated in the first container and the first electrode is immersed, a buffer solution is accommodated in the second container and the second electrode is immersed, and the first container and the second container This is a closed flow channel that communicates with each other, and is a closed flow channel equipped with a detachable member that constitutes a part of the closed flow channel, which binds a base sequence capable of hydrogen bonding to a sample DNA and a polymer compound. The separation of the sample DNA into normal DNA and abnormal DNA due to the difference in binding force and the separation DNA-binding material are allowed to pass between the sample DNA and the separation DNA-binding material are not allowed to pass. A closed channel equipped with a selective separation filter is filled with a buffer containing a linear polymer and a DNA binding control agent, sample DNA is introduced into the sealed channel, and a voltage is applied between the first electrode and the second electrode. Electrophoresis of sample DNA in the sealed channel It is a genetic diagnosis method characterized by detecting normal DNA and / or abnormal DNA, which can improve determination reproducibility and reduce costs, and can use cartridges and chips. The degree of freedom is improved.
[0050]
Hereinafter, a genetic diagnostic apparatus and a genetic diagnostic method according to embodiments of the present invention will be described with reference to the drawings.
[0051]
(Embodiment 1)
FIG. 1 is an external view of a genetic diagnostic apparatus according to Embodiment 1 of the present invention, FIG. 2 is an external view of the genetic diagnostic apparatus according to Embodiment 1 of the present invention, and FIG. 3 is a gene according to Embodiment 1 of the present invention. FIG. 4 is a main part diagram of the control circuit of the genetic diagnosis apparatus according to the first embodiment of the present invention, and FIG. 5 uses the DNA binding substance for separation of the genetic diagnosis apparatus according to the first embodiment of the present invention. FIG. 2 is a structural diagram of a closed flow path attached with a selective separation filter for electrophoresing sample DNA and normal DNA only in the vicinity of an end point.
[0052]
In FIG. 1, 1 is a power switch of the genetic diagnosis apparatus, 2 is an operation button for performing various operations of the apparatus, 3 is a display panel, 4 is an upper lid, and 5 is a casing of the apparatus. 2, 3, and 4, 6 is adjusted to a predetermined temperature for separating normal DNA and abnormal DNA, and at this portion, DNA is separated into normal DNA, abnormal DNA, and other noise DNA. In order to perform electrophoresis, an electrophoresis unit having a closed flow path, 7 is a support for supporting the electrophoresis unit 6, 8 is a control for performing electrophoresis, a suction pump (16) described later, and a detection unit. It is a control calculation part which consists of a board | substrate which performs control of (10) and calculates the detected data. Reference numeral 9 denotes a power supply box, and 9a denotes a power supply unit provided in the power supply box 9. In this genetic diagnosis apparatus, there is an optimum applied voltage value that differs depending on the type, concentration, and processing condition of the DNA, so that the most suitable electrophoresis can be performed for separating abnormal DNA and normal DNA from the sample DNA 21 described later. The control calculation unit 8 controls the power supply unit 9a to apply the optimum voltage. Reference numeral 11 denotes a temperature controller that adjusts the temperature of the electrophoresis unit 6. Although details of the configuration in the electrophoresis unit 6 will be described later, when the measurement is started, the separation DNA binding substance 20 is arranged so as to be already in the sealed flow path of the electrophoresis unit 6 as shown in FIG. Then, by adopting such an arrangement and performing voltage control, concentration adjustment, temperature control, etc., the present gene diagnostic apparatus converts the sample DNA 21 into normal DNA, abnormal DNA, and noise DNA for several to several tens of minutes while performing electrophoresis. Separating by degree. In the electrophoresis unit 6, the sample DNA 21 can be separated from normal DNA, abnormal DNA, and noise DNA by the difference in hydrogen bond binding force while the separation DNA binding substance 20 is subjected to the electrophoresis action, preferably 15 ° C. to 80 ° C. It is controlled so as to be kept at a predetermined temperature in a temperature range of 20 ° C to 60 ° C. In order to separate normal DNA, abnormal DNA and noise DNA, it is preferable to control within a range of ± 1 ° C. from this predetermined temperature suitable for DNA separation.
[0053]
Reference numeral 10 denotes a detection unit that measures the passing amount of the sample DNA to be electrophoresed. The detection unit 10 will be described with reference to FIG. 4. 10a is a D2 lamp for irradiating ultraviolet rays, 10b is a slit for concentrating the ultraviolet rays emitted from the D2 lamp 10a on a target portion, 10c is a photodiode for receiving ultraviolet rays, 10d is a preamplifier for amplifying the weak current detected by the photodiode 10c, and 10e is an A / D converter for converting it into a digital quantity. Details of these will be described later. Reference numeral 12 denotes an electrode that applies a positive potential during electrophoresis, and reference numeral 13 denotes an electrode that applies a negative potential during electrophoresis.
[0054]
3, 4, and 5, reference numeral 14 denotes a buffer solution for transporting charges and stabilizes the pH of the sample DNA during electrophoresis, 14 a denotes a container on the anode side that contains the buffer solution 14, and 14 b denotes a buffer solution 14. 14c is a buffer solution in which a DNA binding control agent and the following linear polymer 14d are added to the buffer solution 14; 14d enables electrophoresis; normal DNA, abnormal DNA, noise DNA, and noise DNA; It is a linear polymer such as polyacrylamide, which is a separation medium. 15 is a capillary tube (sealed channel) for electrophoresis of sample DNA 21 during electrophoresis, 17 is a selection that allows sample DNA to pass but does not allow a DNA binding substance for separation having a molecular weight larger than that of sample DNA to pass Sex separation filter. Reference numeral 16 denotes a suction pump for injecting a sample DNA 21 or linear polymer 14 d and a reagent such as a DNA binding control agent into the capillary tube 15. The electrode 12 is immersed in the buffer solution 14 of the container 14a, and the electrode 13 is immersed in the buffer solution 14 of the container 14b. The buffer solution 14 in the container 14 a and the container 14 b is communicated with the buffer solution 14 c in the capillary tube 15. When a voltage is applied between the electrode 12 and the electrode 13, electrophoresis is induced in the capillary tube 15, and the separation DNA binding substance 20 and the sample DNA 21 are negatively charged. Therefore, the separation is performed from the container 14a to the container 14b. The DNA binding substance 20 and the sample DNA 21 move.
[0055]
Next, details necessary for performing measurement with the genetic diagnosis apparatus of the present invention will be described. The sample DNA 21 measured by this genetic diagnostic apparatus is DNA obtained from human cells or blood. It is necessary to cut the target portion from the human genomic DNA to a target length using a method such as PCR (polymerase chain reaction) and increase the number for measurement. However, since this PCR is not necessary for the description of the present gene diagnostic apparatus, a specific description is omitted.
[0056]
The target DNA extracted by PCR or the like is about 20 to several thousand bases in terms of the number of bases, but there is a probability that the same DNA sequence does not exist in human genomic DNA which is said to have about 3 billion base pairs. As a practical number, it is about 40 or more. Separation of normal DNA and abnormal DNA is closely related to the concentration of sample DNA (μM, where M = mol / liter), concentration of DNA binding substance for separation (mol%), measurement temperature, etc. Since separation does not occur unless the conditions are satisfied, it is important whether such conditions can be set.
[0057]
Next, the capillary tube 15 shown in FIGS. 3, 4 and 5 will be described. When gel is put into the capillary tube 15 and electrophoresis is performed, a liquid flow called electroosmotic flow is generated. Therefore, in order to prevent this phenomenon from occurring, it is preferable to coat the inner wall of the capillary tube 15 with acrylamide or the like. As long as the generation of the electroosmotic flow can be prevented, another coating method may be used. For example, a commercially available coated capillary tube may be used. As the capillary tube 15, a fused silica capillary tube having an inner diameter of 50 to 100 μm can transmit ultraviolet rays of 90% or more, and when DNA is detected using ultraviolet rays as will be described later, the amount of passing ultraviolet rays is easy. It is most suitable because it can be detected. Even if the capillary tube 15 is configured by a combination of a plate with grooves and a plate that transmits 90% or more of ultraviolet rays, it can transmit 90% or more of ultraviolet rays and detect abnormal DNA by detecting the amount of ultraviolet rays passing therethrough. Can be easily performed. When the grooved plate is made a plate that can transmit ultraviolet rays, transmitted light is detected. When the grooved plate is made a plate that does not transmit ultraviolet rays, abnormal DNA is detected by reflected light. In the case of detecting reflected light, it is necessary to form a rectangular cross section in order to make the groove shape a uniform reflecting surface.
[0058]
As the buffer solutions 14 and 14c stored in the containers 14a and 14b and in the capillary tube 15, it is appropriate to use a Tris-based buffer solution (pH 7.2 to pH 8). Among these, the DNA binding control agent mixed in the buffer solution 14c accommodated in the capillary tube 15 includes a binding promoter such as magnesium chloride for promoting the binding of DNA to the DNA binding substance for separation, and a releasing agent such as urea for promoting the separation. There are two types. These two types of DNA binding control agents can control various migration speeds for DNA by selecting two types of mixing ratios and material substances (for example, other electrolytes as binding promoters). . As the linear polymer 14d for electrophoresis of the separation DNA binding substance 20, the sample DNA 21, etc., polyacrylamide can be used. Since this is also used for the separation DNA binding substance 20, the compatibility is good and appropriate. is there.
[0059]
Next, the order of filling into the capillary tube 15 will be described. First, as shown in FIG. 5, a buffer solution 14c containing a linear polymer 14d and a DNA binding control agent is introduced into the capillary tube 15, and then described in detail below. Add the DNA binding substance 20 for separation. At this time, the linear polymer 14d may be mixed and introduced, or after the separation DNA binding substance 20 is introduced, the linear polymer 14d may be introduced. Subsequently, the sample DNA 21 diluted with the buffer solution 14c in the separated state and the separation DNA binding substance 20 are introduced and electrophoresed.
[0060]
In the first embodiment, since acrylamide and DNA are polymerized to create the separation DNA binding substance 20, the weight difference and the structure difference with DNA are large, and the migration speed (0 of the separation DNA binding substance 20) .6 cm / min to 0.7 cm / min) is about 1/20 to 1/30 of the optimal migration speed of DNA (13 cm / min to 20 cm / min) due to inertia, and the relative movement is very slow. Thus, a state that may be said to be fixed in a pseudo manner is realized. In addition to a mechanism for exchanging each solution of sample DNA, DNA binding material for separation, and linear polymer into the capillary tube 15 of the genetic diagnosis apparatus, for example, the suction pump 16 shown in FIG. It is desirable to equip a column for storing each solution of the DNA binding substance for use and the linear polymer, and a mechanism for automatically replacing the column and connecting it to the capillary tube 15.
[0061]
Further, the capillary tube 15 may be unitized in units of one or a plurality, and this may be attached to the electrophoretic unit 6 as a replacement separation channel cartridge and temperature controlled by the temperature controller 11. Is appropriate. The capillary tube 15 is preliminarily filled with a buffer solution 14c containing a linear polymer 14d and a DNA binding control agent, and the separation DNA binding substance 20 and the sample DNA 21 are filled in a separated state to prepare a separation flow path cartridge for separation. It becomes possible to keep. With this configuration, since the separation sealed channel cartridge is replaced every time measurement is performed, the arrangement of the separation DNA binding substance 20 and the sample DNA 21 can be set in advance for each separation sealed channel cartridge. Can be performed easily and accurately. In this separation flow path cartridge, the separation DNA binding substance 20 and the sample DNA 21 are separated and filled with a linear polymer 14d interposed therebetween. The linear polymer 14d may be mixed and filled in each of them.
[0062]
Next, the separation DNA binding substance 20 will be described.
[0063]
The DNA binding substance 20 for separation includes the sample DNA to be determined (there is a sequence difference of one or more bases compared to normal DNA, or the same sequence as normal DNA) and the DNA to be determined. Correspondingly known to be normal, normal DNA having the same number of bases as the sample, normal DNA or DNA having a base sequence homologous to the DNA to be determined and a substance having a higher molecular weight than the sample DNA Is. In addition, the DNA binding substance for separation is normal DNA and the same number of bases, but when abnormal DNA having a sequence difference of one base or more is simultaneously moved in a closed channel by electrophoresis, Separation of normal or abnormal DNA using the difference in hydrogen bonding strength with a base sequence that is completely homologous to either normal DNA or abnormal DNA existing in the DNA binding substance for separation. It refers to substances that can be used. This substance is characterized by always having a higher molecular weight than the DNA to be determined.
[0064]
Here, FIG. 11 is a conceptual diagram of the relationship between the DNA binding substance for separation and the sample DNA in the closed flow path of the genetic diagnostic apparatus according to Embodiment 1 of the present invention. In FIG. 11, 20 is a DNA binding substance for separation.
[0065]
There are two types of DNA: double-stranded and single-stranded, but the four bases A, T, C, and G of DNA have the property that A and T, and G and C are easy to hydrogen bond with each other. The double strands of DNA are also paired with AT and GC. Therefore, when DNA of one strand is arranged as ATCGCGTCTAGC (described in SEQ ID NO: 1), the DNA of the other strand has a base sequence of TAGCGCAGATCG (described in SEQ ID NO: 2). This relationship is called a complementary relationship. As long as this complementary relationship is satisfied, A and T and G and C are bonded by hydrogen bonds to form a double strand. In the present invention, in order to utilize this relationship, as shown in FIG. 11, the DNA portion of the separating DNA binding substance 20 has a base sequence complementary to the normal DNA of the sample DNA. Therefore, the base sequence of the normal DNA of the sample DNA contains ATCGCGTCTAGC (described in SEQ ID NO: 1), and the abnormal DNA is ATCA. ^* When the bases of normal DNA, abnormal DNA, and noise DNA are different in the portion indicated by * in CGTCTAGC (described in SEQ ID NO: 3), the sequence of the DNA portion of the separating DNA binding substance 20 is TAGCGCAGATCG (SEQ ID NO: 2). The abnormal DNA is A ^* In this case, hydrogen bonds do not occur because they are no longer complementary to the separating DNA binding substance 20, and the binding force of the whole hydrogen bond is larger by the binding force of one base than the abnormal DNA. As a result, during electrophoresis described later, normal DNA binds to the separation DNA binding substance 20 for a longer time with a stronger binding force than abnormal DNA, so that normal DNA is relatively delayed from abnormal DNA. This is because not only the binding force during electrophoresis but also the pulling force due to electrophoresis acts, so that a large number of DNAs are in a binding state that repeats binding and detachment intermittently. When this migration speed is viewed on average, the migration speed of normal DNA that binds for a long time is lower than that of abnormal DNA. Sample DNA includes DNA other than normal DNA, abnormal DNA, and noise DNA, such as the remaining single-stranded DNA that is not to be measured among double-stranded DNA. However, since the noise DNA hardly reacts and binds to the DNA of the separating DNA binding substance 20, it is separated with the fastest electrophoresis speed. The concentration of the separating DNA binding substance 20 is appropriately 20 to 600 times the concentration of the sample DNA.
[0066]
Next, a method for producing and synthesizing such a separating DNA binding substance 20 will be described. In order to synthesize vinylated DNA, the DNA for separating DNA-binding substance 20 is cut out by PCR. In the above example, TAGCGCAGATCG (described in SEQ ID NO: 2) is the DNA of the separation DNA binding substance 20.
[0067]
Subsequently, the 5 ′ end of the DNA having the target base sequence is aminated (usually aminated via a hexyl group). The aminated DNA thus obtained is diluted by adding ultrapure water sterilized to 2.6 mM. Next, MOSU (methacryloid oxysuccinimide) is diluted with DMSO (dimethyl sulfoxide) to 71.388 mM. Then, the aminated DNA thus obtained and MOSU are added and adjusted so as to have a ratio of 1:50. Further, a solution adjusted with sodium hydrogen carbonate and sodium hydroxide so as to have a pH of 9 for pH adjustment is added to this adjusted solution in an amount equal to the amount of aminated DNA.
[0068]
The resulting solution is then shaken overnight. Thereafter, the vinylated DNA in the shaken solution is separated from the aminated DNA, MOSU, and others using HPLC (High Performance Liquid Chromatography). Since vinylated DNA contains an eluent (TEAA; mixed solution of triethylamine-acetic acid and acetonitrile), it is further concentrated under reduced pressure by a centrifugal evaporator having a vacuum drying function.
[0069]
Then, 53 μmol of nitrogen is substituted for 10% AAM (acrylamide) as a polymerization solution. Further, 1.34% of TEMD (N, N, N′N′-tetramethylethylenediamine) which is a polymerization initiator is diluted with sterilized ultrapure water deaerated by ultrasonic waves. This is diluted with sterilized ultrapure water in which 2% APS (ammonium persulfate), which is a polymerization initiator, is similarly deaerated by ultrasonic waves. Furthermore, the concentrated vinylated DNA is diluted with sterilized ultrapure water. Then, in order to synthesize 100 μl of the DNA binding substance 20 for separation, 34 μl of the above AAM, 5 μl each of the above TEMD and APS, and 0.01% mol to 0.05% mol of vinylated DNA with respect to AAM In addition, sterilized ultrapure water is added to 100 μl, and the mixture is allowed to stand for about 60 minutes, whereby an acrylamide-ized DNA binding substance for separation 20 is obtained.
[0070]
Subsequently, the operation of the genetic diagnosis apparatus according to the first embodiment will be described. First, the capillary tube 15 into which the sample DNA 21 and each solution are introduced is set in the genetic diagnosis apparatus, and the buffer solution 14 in the containers 14a and 14b is immersed at both ends as shown in FIGS. A predetermined voltage is applied between the electrode 12 and the electrode 13 by the power supply unit 9a. The magnitude of the applied voltage is preferably 10 to 20 kilovolts, but may be 100 to 30 kilovolts depending on the state of the electrolyte and electrodes. For example, when the electrolyte concentration is low or the electrode area is large, the voltage is lowered. Then, instead of applying a predetermined voltage from the beginning, a high voltage of 30 kilovolts or more for preparation is applied before applying a constant voltage, and noise DNA is separated and then a predetermined voltage is applied. Can be done.
[0071]
Here, the reason why a predetermined voltage is applied between the electrode 12 and the electrode 13 will be described. Since the difference between the binding force of the sample DNA 21 to the separating DNA binding substance 20 and the separation force due to the electrophoretic force governs the expression of the difference in migration speed of each DNA, separation of normal DNA, abnormal DNA, and noise DNA is prevented. This is because it is necessary to select and apply the most effective voltage. That is, this voltage must be as low as possible in order to increase the resolution, since the normal DNA that is most difficult to migrate can be electrophoresed, and the resolution of normal DNA and abnormal DNA decreases when high voltage is applied. The voltage satisfies the two conditions. Therefore, the optimum voltage to be applied in advance is examined for each DNA and for each condition, and as described above, after initially applying a preparation voltage of about 30 kilovolts or more for a short time, this voltage is applied. Is optimal. Since the DNA in the capillary tube 15 is negatively charged and proceeds to the anode side, the power source 9a needs to apply the electrode 12 so as to have a positive potential and the electrode 13 have a negative potential. In addition, in electrophoresis, if the migration time is too long, the buffer solution 14c is dried in the capillary tube 15, so it is necessary to avoid running for a longer time than necessary.
[0072]
Alternatively, a high voltage of 30 kilovolts or more for preparation may be applied to quickly separate noise DNA, and then the absolute value of the voltage may be gradually increased to apply the high voltage. When the absolute value of the voltage is gradually increased, it may be increased regularly or irregularly, but a particularly preferable method is to sweep and apply the voltage. The sweep is to change the voltage at a constant value per unit time. For example, if the sweep is started from 0 to 1 kilovolt / second, 10 kilovolts are applied after 10 seconds. The reason why the applied voltage is swept will be explained. The difference between the binding force of the DNA sample 21 to the separating DNA binding substance 20 and the separation force due to the electrophoretic force greatly affects the migration speed and movement difference of DNA. In order to adjust the voltage at which separation of normal DNA, abnormal DNA, and noise DNA is most effectively performed, the sweep is performed. If the voltage that causes the difference in the migration speed most by the sweep is known, this voltage may be maintained. By sweeping the applied voltage, it is possible to obtain an effect that it can be adjusted very easily to an optimum voltage with high resolution. This is because noise DNA migrates first at a stage where the sweep voltage is low and is detected by the detection unit, but abnormal DNA has a weak binding force for one base to the DNA binding substance 20 for separation. If it doesn't become a little high voltage, it can't be removed. In addition, normal DNA cannot be removed without increasing the voltage. If a voltage in the vicinity is applied, abnormal DNA and normal DNA are clearly separated. However, since the resolution of normal DNA and abnormal DNA is lowered when the sweep voltage is increased, it is optimal to keep the voltage near the voltage at which normal DNA starts to migrate. Then, after a preliminary voltage of about 30 kilovolts or more is initially applied for a short time, the sweep start voltage may be simply started from 0 volts normally. However, depending on the binding conditions between the separation DNA binding substance 20 and the sample DNA 21, 30 kilovolts may be used. After applying the above, the sweep may be started from 5 kilovolts to 7 kilovolts. Since the DNA in the capillary tube 19 proceeds to the anode side, the variable power supply unit 9a needs to apply the electrode 16 so as to have a positive potential and the electrode 17 have a negative potential. When the voltage is swept, the DNA sample 23 is migrated, and the separating DNA-binding substance 20 has a difference of one base in the binding force between normal DNA and abnormal DNA. And a large movement difference is generated from the noise DNA.
[0073]
Next, the electrophoresis unit 6 where the separation is performed will be described. The electrophoresis unit 6 varies depending on the state of the sample DNA, but can be separated at 15 ° C. so that normal DNA, abnormal DNA, or noise DNA can be separated based on the difference in binding force between the separation DNA binding substance 20 and the sample DNA 21. It must be kept at a predetermined temperature in the temperature range of -80 ° C, preferably 20 ° C-60 ° C. In the genetic diagnostic apparatus according to the first embodiment, a silicon rubber heater, a nichrome wire, etc., and a temperature sensor such as a thermocouple, thermal, etc. are arranged below the electrophoresis unit 6 covering the capillary tube 15. The temperature is controlled to be a predetermined temperature ± 1 ° C. or lower. However, depending on the environmental temperature, the room temperature may exceed the target predetermined temperature, and it is better to use a component that can be heated and cooled such as Peltier instead of a silicon rubber heater or nichrome wire.
[0074]
Next, how to detect normal DNA, abnormal DNA, and noise DNA in which the migration speed is different due to the action of the separation DNA binding substance 20 and the movement difference is generated will be described. FIG. 12 is a relationship diagram between elapsed time and absorbance when the elapsed time from the start of electrophoresis is plotted on the horizontal axis and the absorbance is plotted on the vertical axis. The detection is performed by measuring the absorbance when ultraviolet irradiation is shielded by normal DNA, abnormal DNA, noise DNA, and noise DNA. In the first embodiment, as shown in FIGS. 3 and 4, the glass portion is exposed at a part of the capillary tube 15, and ultraviolet light having a wavelength of 260 nm is irradiated from the D2 lamp 10a. Absorbance is measured by detecting with the diode 10c. The control calculation unit 8 controls the power supply unit 9a to cause the D2 lamp 10a to emit light, and the current detected by the photodiode 10c is amplified by the preamplifier 10d, and converted to the absorbance as a digital quantity by the A / D converter 10e. Is done. The control calculation unit 8 has a built-in timer (not shown), and can measure the elapsed time from the migration start time. In FIG. 7, the direction (I) having a shorter elapsed time (passing earlier in time) is noise DNA that does not bind to the DNA conjugate, the middle (II) is abnormal DNA, and the elapsed time is longer (III ) Is normal DNA.
[0075]
From this relationship diagram, if the peak height, time, and number of peaks are read, it can be seen from the number of peaks that the sample DNA contains abnormal DNA. That is, it can be determined from the number of peaks whether abnormal DNA exists. Since the number of peaks can be limited to abnormal DNA and noise DNA depending on the applied voltage, DNA concentration, and DNA length (number of bases), only the passing amount of abnormal DNA is measured at this time. In addition, comparing peak heights shows the difference in absorbance between two groups with different migration speeds in DNA electrophoresed under the same conditions, which corresponds to the abundance ratio of abnormal DNA and normal DNA. The ratio can be determined. To determine the abundance of abnormal DNA, standard data obtained from the detection peak waveform of the standard sample DNA may be input in advance to the control calculation base 8, and the measured data and the measured data may be compared and converted.
[0076]
Here, as shown in FIG. 5, this selective separation filter 17 has a selective permeability such that the sample DNA 21 can pass but the separation DNA binding substance 20 having a molecular weight larger than that of the sample DNA cannot pass. For example, an ultrafiltration membrane or a nanofiltration membrane can be considered as the material.
[0077]
The selective separation filter 17 can pass the sample DNA 21 to be determined (and normal DNA put as a control), but the sample DNA 21 or the separating DNA binding substance 20 having a molecular weight larger than that of the normal DNA passes. It has selectivity that cannot. The selective separation filter 17 used here may be anything as long as it exhibits selective permeability due to a difference in molecular weight, such as a semipermeable membrane (dialysis membrane) or an ultrafiltration membrane. For example, DNA to be determined and normal DNA as a control are assumed to be single-stranded DNA of about 20 mer to 200 mer, and have a molecular weight of about 6000 to 60,000. On the other hand, the separating DNA-binding substance 20 needs to be a substance having a molecular weight larger than that of DNA to be constantly determined or normal DNA. The selective separation filter 17 can pass sample DNA 21 having a molecular weight of 6000 to 60,000 and normal DNA used as a control, and can pass a DNA binding substance 20 for separation having a larger molecular weight or a large DNA derived from a chromosome. It is selected on condition that it is not possible.
[0078]
In FIG. 5, when a voltage is applied to the closed channel, the sample DNA 21 starts migration toward the anode, and separation is performed due to the difference in chemical bonding force while passing through the separation DNA binding substance 20. Two peaks are detected by the detection device outside the closed channel. When a voltage is applied to both ends of the hermetic container to cause the sample DNA 21 to migrate, the separation DNA-binding substance 20 having a large molecular weight is slightly moved toward the anode as compared with the sample DNA. When electrophoresis is performed a plurality of times using the same sealed channel, depending on the total migration time, the DNA binding substance for separation 20 also comes out of the sealed channel, and the subsequent sample DNA cannot be separated. It is expected that. In order to prevent this, a selective separation filter 17 was installed. No matter how many times electrophoresis is performed with this filter, the DNA binding substance 20 for separation is not lost. After being supplemented by the filter, it is possible to return the separation DNA-binding substance 20 to the original position by switching the anode and the cathode and flowing the current in reverse, which can be used repeatedly.
[0079]
As described above, according to the genetic diagnosis apparatus and the genetic diagnosis method of the first embodiment, among DNA extracted from cells, blood, etc., specific DNA is included in sample DNA extracted by PCR or the like. By knowing the abundance ratio of normal DNA, abnormal DNA, and noise DNA, genetic diagnosis and determination can be made. In addition, since the separation DNA binding substance can be prevented from leaking out of the system, it is possible to perform a repetitive operation and diagnose / determine at low cost.
[0080]
(Embodiment 2)
A genetic diagnostic apparatus and a genetic diagnostic method according to Embodiment 2 of the present invention will be described with reference to the drawings. In addition, about the part which overlaps with Embodiment 1, and description to FIGS. 1-4, it hands over to Embodiment 1 and description is abbreviate | omitted.
[0081]
FIG. 6 is a diagram in which the selective separation filter 17 described in the first embodiment in the second embodiment of the present invention is attached to both ends of the sealed flow path. The selective separation filter 17 is a filter having a selective permeability that allows the sample DNA 21 to pass through, but cannot pass through the separation DNA binding substance 20 having a molecular weight larger than that of the sample DNA. An outer filtration membrane or a nanofiltration membrane can be considered.
[0082]
In FIG. 6, when a voltage is applied to the sealed channel, the sample DNA 21 starts migration toward the anode, and separation is performed due to the difference in chemical bonding force while passing through the separation DNA binding substance 20. Two peaks are detected by the detection device outside the closed channel. When a voltage is applied to both ends of the hermetically sealed container to cause the sample DNA 21 to migrate, the separation DNA binding substance 20 having a large molecular weight is slightly moved toward the anode as compared with the sample DNA 21. When electrophoresis is performed a plurality of times using the same sealed channel, depending on the total migration time, the DNA binding substance 20 for separation also goes out of the sealed channel, making it impossible to separate the sample DNA 21 thereafter. It is expected that. In order to prevent this, a selective separation filter 17 was installed at both ends of the sealed flow path. No matter how many times electrophoresis is performed with the filter in the vicinity of the end of the closed flow path, the DNA binding substance for separation 20 is not lost. After being supplemented by the filter, it is possible to return the DNA binding substance 20 for separation to the original position by switching the anode and the cathode, and returning the current to the original position. Even if it is caused to flow too much, the separating DNA binding substance 20 is not lost. By attaching the filter to both ends, it can be used repeatedly with peace of mind.
[0083]
Furthermore, by making the sealed channel described in FIG. 6 removable, if the entire sealed channel is turned over after several migrations, the biased DNA binding substance 20 for separation is repeated without returning by a reverse current. You can use it.
[0084]
FIG. 6 shows a state in which the sample DNA 21 is introduced, but when the sealed flow path part including at least the region sandwiched by the selective separation filter 17 is detachable to form a cartridge and chip, It goes without saying that the sample DNA 21 is not introduced into the region sandwiched by the selective separation filter 17 and is filled with the separation DNA binding substance 20 in the cartridge and chip.
[0085]
As described above, according to the genetic diagnostic apparatus and genetic diagnostic method of the second embodiment, among DNA extracted from cells, blood, etc., specific DNA is included in sample DNA 21 extracted by PCR or the like. By knowing the abundance ratio of normal DNA, abnormal DNA, and noise DNA, genetic diagnosis and determination can be made. Further, since it is possible to prevent the separation DNA binding substance 20 from leaking out of the system, it is possible to perform repeated operations, and it is possible to completely prevent the separation DNA binding substance 20 from leaking out of the system. Long-term accurate measurement is possible. Furthermore, since the selective separation filter 17 is mounted at both ends, the entire flow path can be turned over so that continuous electrophoresis operation can be performed, and continuous diagnosis and determination can be performed at low cost.
[0086]
(Embodiment 3)
A genetic diagnostic apparatus and a genetic diagnostic method according to Embodiment 3 of the present invention will be described with reference to the drawings. In addition, about the part which overlaps with Embodiment 1, and description to FIGS. 1-4, it hands over to Embodiment 1 and description is abbreviate | omitted.
[0087]
FIG. 7 shows that the selective separation filter 17 described in the first embodiment in the third embodiment of the present invention is mounted in the vicinity of the end point of the closed flow path and is larger in volume than the selective separation filter described in the first and second embodiments. It is the figure which mounted | worn with the 2nd selective separation filter (pre filter) which can capture | acquire the polymer of most upstream part. Here, the selective separation filter 17 is a filter having a selective permeability such that the sample DNA 21 can pass through but the separation DNA binding substance 20 having a molecular weight larger than that of the sample DNA 21 cannot pass through. The selective separation filter (prefilter) 18 can pass the sample DNA 21 and normal DNA used as a control, but cannot pass higher molecular weight substances, and the selection described in the first and second embodiments. A larger amount of polymer can be captured than the sex separation filter. The materials of both filters may be the same or different. For example, a microfiltration membrane, an ultrafiltration membrane, or a nanofiltration membrane can be considered.
[0088]
In FIG. 7, when a voltage is applied to the sealed channel, the sample DNA 21 starts migration toward the anode, and separation is performed due to a difference in chemical bonding force while passing through the separation DNA binding substance 20, Although detected as two peaks by the detection device outside the closed channel, when the sample DNA 21 is mounted at the position shown in FIG. 7, it was mixed in the sample by passing it through the selective separation prefilter 18 in advance. Polymer impurities can be removed, and accurate detection can be performed. Furthermore, by attaching the selective separation filter 17 in the vicinity of the end of the closed flow path, as described in Embodiment 1, it is possible to prevent the DNA binding substance 20 for separation from being lost no matter how many times electrophoresis is performed. . As described above, according to the genetic diagnosis apparatus and the genetic diagnosis method of the third embodiment, among DNA extracted from cells, blood, etc., specific DNA is included in sample DNA extracted by PCR or the like. By knowing the abundance ratio of normal DNA, abnormal DNA, and noise DNA, genetic diagnosis and determination can be made. In addition, impurities can be removed in advance by a prefilter near the migration start point, and further, a filter near the end point can be prevented from leaking out of the DNA binding substance for separation, enabling repeated and accurate detection. Diagnosis and determination at low cost.
[0089]
(Embodiment 4)
A genetic diagnostic apparatus and a genetic diagnostic method according to Embodiment 4 of the present invention will be described with reference to the drawings. In addition, about the part which overlaps with Embodiment 1, and description to FIGS. 1-4, it hands over to Embodiment 1 and description is abbreviate | omitted.
[0090]
FIG. 8 shows that the selective separation filter 17 described in the first embodiment in the fourth embodiment of the present invention is attached to both ends of the sealed flow path, and the prefilter 18 described in the third embodiment is near the start point of the sealed flow path. FIG.
[0091]
By using these three filters, accurate measurement can be performed for a long period of time by removing impurities without losing the DNA binding substance 20 for separation regardless of the direction of electrophoresis.
[0092]
As described above, according to the genetic diagnostic apparatus and genetic diagnostic method of the fourth embodiment, among DNA extracted from cells, blood, etc., specific DNA is included in sample DNA extracted by PCR or the like. By knowing the abundance ratio of normal DNA, abnormal DNA, and noise DNA, genetic diagnosis and determination can be made. In addition, since it is possible to completely prevent the DNA binding substance for separation from leaking out of the system, it is possible to perform repetitive operations, and diagnosis / determination can be performed at low cost.
[0093]
As described above, according to the genetic diagnostic apparatus and genetic diagnostic method of the fourth embodiment, among DNA extracted from cells, blood, etc., specific DNA is included in sample DNA extracted by PCR or the like. By knowing the abundance ratio of normal DNA, abnormal DNA, and noise DNA, genetic diagnosis and determination can be made. In addition, impurities can be removed in advance by a pre-filter near the starting point of electrophoresis, and the DNA-binding substance for separation can be completely prevented from leaking out of the system by filters at both ends. This makes it possible to make diagnosis and judgment at low cost.
[0094]
(Embodiment 5)
A genetic diagnostic apparatus and a genetic diagnostic method according to Embodiment 5 of the present invention will be described with reference to the drawings. In addition, about the part which overlaps with Embodiment 1, and description to FIGS. 1-4, it hands over to Embodiment 1 and description is abbreviate | omitted.
[0095]
FIG. 9 shows that the selective separation filter 17 described in the first embodiment in the fifth embodiment of the present invention is attached to both ends of the sealed flow path, and the prefilter 18 described in the third embodiment is mounted on both ends of the sealed flow path. FIG. 5 is a view of the attachment of the selective separation filter 17 closer to the start point and the end point than the attached selective separation filter 17.
[0096]
By using these four filters, impurities can be removed without losing the DNA binding substance 20 for separation regardless of the direction of electrophoresis, so that accurate measurement can be performed for a long period of time. Furthermore, by making the sealed channel described in FIG. 9 removable, if the entire sealed channel is turned over after several migrations, the biased DNA binding substance for separation is repeatedly used without returning by reverse current. I can do things. Furthermore, since the impurities are removed by the prefilter, it can be used for long-term continuous use.
[0097]
As described above, according to the genetic diagnostic apparatus and genetic diagnostic method of the fifth embodiment, among DNA extracted from cells, blood, etc., specific DNA is included in sample DNA extracted by PCR or the like. By knowing the abundance ratio of normal DNA, abnormal DNA, and noise DNA, genetic diagnosis and determination can be made. In addition, the separation DNA-binding substance can be completely prevented from leaking out of the system, and impurities can be removed by the prefilter, so that accurate measurement can be performed for a long period of time. Furthermore, since the filter and the pre-filter are mounted on both sides, the entire flow path can be turned over so that continuous electrophoresis operation is possible, and continuous diagnosis and determination can be performed at low cost.
[0098]
(Embodiment 6)
A genetic diagnostic apparatus and a genetic diagnostic method according to Embodiment 6 of the present invention will be described with reference to the drawings. In addition, about the part which overlaps with Embodiment 1, and description to FIGS. 1-4, it hands over to Embodiment 1 and description is abbreviate | omitted.
[0099]
FIG. 10 shows that the selective separation filter 17 described in Embodiment 1 in Embodiment 6 of the present invention is attached to both ends of the sealed flow path, and transparent detection windows 19 for detection are provided at both ends of the sealed flow path. It is a figure. Here, the position of the selective separation filter 17 and the detection window 19 may be either outside, and both may be located near the end of the sealed flow path.
[0100]
By using two selective separation filters, it becomes possible to perform electrophoresis without losing the DNA binding substance 20 for separation regardless of the direction of electrophoresis, and there is a detection window 19 at both ends. Thus, repetitive migration / detection can be performed only by converting the cathode / anode of the electrode 12 and the electrode 13 without removing the sealed channel portion.
[0101]
As described above, according to the genetic diagnostic apparatus and genetic diagnostic method of the fifth embodiment, among DNA extracted from cells, blood, etc., specific DNA is included in sample DNA extracted by PCR or the like. By knowing the abundance ratio of normal DNA, abnormal DNA, and noise DNA, genetic diagnosis and determination can be made. Further, since the filter and the prefilter are mounted on both sides, the separation DNA binding substance can be prevented from leaking out of the system, and furthermore, the detection window 19 is provided at both ends of the sealed channel, so that the sealed channel part Since it is possible to perform repetitive migration / detection simply by converting the positive and negative electrodes without removing the electrode, continuous diagnosis / determination can be performed at low cost without much labor.
[0102]
【The invention's effect】
As described above, according to the present invention, a genetic abnormality of one or more nucleotides can be detected in a short time, easily and accurately, and the diagnosis is automated with a small size, light weight, low cost, and very low running cost. It is possible to provide a genetic diagnostic apparatus and a genetic diagnostic method that can be performed.
[0103]
It enables repeated use of the DNA binding substance for separation, which is used to separate and measure the normal type and abnormal type of the gene to be determined, and also removes chromosomal DNA and blood-derived high-molecular-weight noise substances. It is possible to provide a genetic diagnostic apparatus and a genetic diagnostic method that can simplify the diagnostic apparatus, reduce the cost of diagnosis, and realize highly accurate determination.
[0104]
In addition, according to the genetic diagnosis apparatus described in claim 1, a sealed flow path for performing electrophoresis for separating DNA existing in the apparatus and discriminating whether the sample DNA is normal type or abnormal type Needs to be filled with a DNA binding substance for separation. The separating DNA binding substance used at this time is the material that requires the most running cost. If it is not necessary to dispose the DNA binding substance for separation, in addition to reducing costs, various adjustments derived from changes in the concentration and quality of the DNA binding substance for separation will be eliminated, improving measurement accuracy and shortening measurement time. We can expect merit such as. For this reason, it is possible to obtain a low-cost and high-accuracy apparatus at a low running cost, and it is very easy to automate diagnosis.
[0105]
Further, it is possible to prevent the separation DNA-binding substance that requires the most running cost from flowing out of the sealed channel by electrophoresis and suction or extrusion of the sealed channel material.
[0106]
In addition to the effect of the first aspect, the genetic diagnosis apparatus according to the second aspect can improve the measurement accuracy and extend the life of the measurement by removing impurities other than the measurement target in advance.
[0107]
The genetic diagnosis apparatus according to claim 3 can prevent the separation DNA-binding substance that requires the most running cost from flowing out of the sealed channel regardless of the direction of movement.
[0108]
In addition to the effect of the third aspect, the genetic diagnosis apparatus according to the fourth aspect can remove the impurities other than the measurement target in advance, thereby improving the measurement accuracy and extending the measurement life.
[0109]
In addition to the effect of the third aspect, the genetic diagnosis apparatus according to the fifth aspect can remove the impurities other than the measurement target in advance, thereby improving the measurement accuracy and extending the measurement life.
[0110]
In addition to the effects of claims 2 to 5, the genetic diagnosis apparatus according to claim 6 can continue the measurement without exchanging or moving the sealed channel regardless of the direction of electrophoresis. It is.
[0111]
In addition to the effect of the second aspect, the genetic diagnosis apparatus according to the seventh aspect can perform measurement while replacing the sealed flow path portion, and therefore can continuously measure multiple samples. It is also possible to reduce the size of the device by measuring with one detection unit.
In addition to the effects of the third to fifth aspects, the genetic diagnostic device according to the eighth aspect can perform measurement while replacing the sealed flow path, and therefore can continuously measure multiple samples. . It is also possible to reduce the size of the device by measuring with one detection unit.
In addition to the effect of the eighth aspect, the genetic diagnosis apparatus according to the ninth aspect is capable of detecting as noise even if impurities such as DNA or protein having a large molecular weight are mixed in the sample to be measured. And accurate measurement can be performed.
[0112]
The genetic diagnostic device according to claim 10 can partly form a flow path into a cartridge and chip, and since there is no outflow of the DNA binding substance for separation by measurement, it can be measured multiple times. Become.
[0113]
In addition to the effect of the tenth aspect, the genetic diagnosis apparatus according to the eleventh aspect can detect noise even if the sample to be measured is contaminated with impurities such as DNA or protein having a large molecular weight. And accurate measurement can be performed.
[0114]
In addition to the effect of the tenth aspect, the genetic diagnosis apparatus according to the twelfth aspect can be detected as noise even if impurities such as DNA or protein having a large molecular weight are mixed in the sample to be measured. And accurate measurement can be performed.
[0115]
In addition to the effects of the tenth to twelfth aspects, the genetic diagnosis device according to the thirteenth aspect enables efficient electrophoresis.
[0116]
In addition to the effect of the thirteenth aspect, the genetic diagnostic device according to the fourteenth aspect can prevent electroosmotic flow.
[0117]
The genetic diagnosis method described in claim 15 can improve the reproducibility of the determination and reduce the cost.
[0118]
In addition to the effect of claim 15, the gene diagnosis method described in claim 16 can prolong the life of a selective separation filter that aims to newly reduce measurement noise and capture a DNA binding substance for separation. it can.
[0119]
The genetic diagnosis method according to claim 17 can improve the reproducibility of the determination and reduce the cost.
[0120]
The genetic diagnosis method described in claim 18 can improve the reproducibility of the determination and reduce the cost, can use a member formed in a cartridge or in a chip, and the degree of freedom is improved.
[0121]
[Sequence Listing]

[Brief description of the drawings]
FIG. 1 is an external view of a genetic diagnosis apparatus according to Embodiment 1 of the present invention.
FIG. 2 is an external view of the open top lid of the genetic diagnosis apparatus according to Embodiment 1 of the present invention.
FIG. 3 is a device configuration diagram of the genetic diagnosis device according to the first embodiment of the present invention.
FIG. 4 is a main part diagram of the control circuit of the genetic diagnosis apparatus according to the first embodiment of the present invention.
FIG. 5 shows a closed flow path with a selective separation filter according to the present invention for electrophoresis of sample DNA and normal DNA using the separation DNA binding substance of the genetic diagnosis apparatus of Embodiment 1 of the present invention only near the end point. Structural drawing
FIG. 6 is a diagram in which the selective separation filter described in the first embodiment in the second embodiment of the present invention is attached to both ends of the sealed flow path.
7 shows the selectivity separation filter described in the first embodiment in the third embodiment of the present invention in the vicinity of the end point of the closed flow path and is larger in volume than the selectivity separation filter described in the first and second embodiments. Fig. 2 is a top view of the second selective separation filter (prefilter) that can capture the polymer of
8 shows the selectivity separation filter described in the first embodiment in the fourth embodiment of the present invention is attached to both ends of the sealed flow path, and the prefilter described in the third embodiment is in the vicinity of the starting point of the sealed flow path. Attached figure
9 shows the selective separation filter described in Embodiment 1 in Embodiment 5 of the present invention is attached to both ends of the sealed flow path, and the pre-filter described in Embodiment 3 is attached to both ends of the sealed flow path. FIG. Figure attached to the place closer to the start and end points than the selective separation filter
FIG. 10 shows the selective separation filter described in the first embodiment in the sixth embodiment of the present invention attached to both ends of the sealed channel, and provided with transparent detection windows for detection at both ends of the sealed channel. Figure
FIG. 11 is a conceptual diagram of the relationship between a DNA binding substance for separation and sample DNA in a sealed channel of the genetic diagnostic apparatus according to Embodiment 1 of the present invention.
FIG. 12 is a relationship diagram between elapsed time and absorbance.
[Explanation of symbols]
1 Power switch
2 Operation buttons
3 Display panel
4 Top cover
5 Case
6 Electrophoresis part
7 Support stand
8 Control operation part
9 Power box
9a Power supply
10 detector
10a D ₂ lamp
10b slit
10c photodiode
15d preamplifier
10e A / D converter
11 Temperature controller
12,13 electrode
14, 14c Buffer solution
14a, 14b container
14d linear polymer
15 Capillary tube
16 Suction pump
17 Selective separation filter
18 Selective separation pre-filter
19 Detection window
20 DNA-binding substance for separation
21 Sample DNA

Claims (18)

A first container containing a buffer solution and immersed in the first electrode;
A second container containing a buffer solution and immersed in the second electrode;
A sealed flow path in which the first container and the second container are filled and filled with a buffer containing a linear polymer and a DNA binding control agent;
A power supply unit that applies a positive potential or a negative potential to the second electrode and applies a negative potential or a positive potential to the first electrode;
A control unit for controlling the power supply unit to apply a voltage between the second electrode and the first electrode;
Provided in the closed flow path, provided with a detection unit for detecting the amount of DNA passing through the inside,
In the closed channel, in the buffer solution,
A DNA binding substance for separation that binds a base sequence capable of hydrogen bonding to a sample DNA and a polymer compound, and separates the sample DNA into normal DNA and abnormal DNA from the difference in binding force;
With sample DNA,
A selective separation filter that allows the sample DNA to pass and does not allow the separation DNA-binding substance to pass, at least on the electrophoresis direction side of the sealed flow path;
A genetic diagnosis apparatus, wherein the sample DNA in the sealed flow path is electrophoresed by applying the voltage, and the detection unit measures the passing amount of normal DNA and / or abnormal DNA. Selective separation that allows the sample DNA and normal DNA used as a control to pass through the closed channel, prevents a higher molecular weight substance from passing, and captures a larger amount of polymer than the selective separation filter. The genetic diagnosis apparatus according to claim 1, further comprising a prefilter, wherein the separation DNA binding substance is sandwiched between the selectivity separation filter and the selectivity separation prefilter. A first container containing a buffer solution and immersed in the first electrode;
A second container containing a buffer solution and immersed in the second electrode;
A sealed flow path in which the first container and the second container are filled and filled with a buffer containing a linear polymer and a DNA binding control agent;
A power supply unit that applies a positive potential or a negative potential to the second electrode and applies a negative potential or a positive potential to the first electrode;
A control unit for controlling the power supply unit to apply a voltage between the second electrode and the first electrode;
Provided in the closed flow path, provided with a detection unit for detecting the amount of DNA passing through the inside,
In the closed channel, in the buffer solution,
A DNA binding substance for separation that binds a base sequence capable of hydrogen bonding to a sample DNA and a polymer compound, and separates the sample DNA into normal DNA and abnormal DNA from the difference in binding force;
With sample DNA,
A selective separation filter that allows the sample DNA to pass therethrough so as to sandwich the separation DNA binding substance in the sealed channel, and does not pass the separation DNA binding substance;
A genetic diagnosis apparatus, wherein the sample DNA in the sealed flow path is electrophoresed by applying the voltage, and the detection unit measures the passing amount of normal DNA and / or abnormal DNA. At least upstream of the selective separation filter located on the opposite side of the electrophoretic direction of the sealed channel, the sample DNA and normal DNA used as a control can be passed, and a higher molecular substance is not allowed to pass through. The genetic diagnostic apparatus according to claim 3, further comprising a selective separation prefilter capable of capturing a larger amount of polymer than the selective separation filter. The sample DNA and normal DNA used as a control can be passed so as to sandwich the selective separation filter of the sealed channel, and a larger amount of polymer than the selective separation filter can be passed without passing a higher molecular substance. The genetic diagnostic apparatus according to claim 3, further comprising a selective separation pre-filter capable of capturing sucrose. The detection window for detecting the amount of DNA passing through the inside of the sealed channel is provided on each side of the sealed channel so as to sandwich at least the separation DNA binding substance. The gene diagnostic apparatus according to any one of -5. 3. The genetic diagnosis apparatus according to claim 2, wherein a sealed channel portion including a region sandwiched between the selectivity separation filter and the selectivity separation prefilter is detachable. The genetic diagnostic apparatus according to any one of claims 3 to 5, wherein at least a sealed channel portion including a region sandwiched between the selective separation filters is detachable. 9. The genetic diagnosis apparatus according to claim 8, wherein the sealed flow path portion including the selective separation prefilter is detachable. A first container in which the buffer electrode is stored and the first electrode is immersed; a second container in which the buffer solution is stored and the second electrode is immersed; and a linear polymer and DNA bond between the first container and the second container A closed flow path filled with a buffer containing a control agent, a power supply unit that applies a positive potential or a negative potential to the second electrode and a negative potential or a positive potential to the first electrode, and the power supply unit A control unit for controlling the voltage to apply a voltage between the second electrode and the first electrode, and a detection unit that is provided in the sealed channel and detects the amount of DNA passing through the inside,
A member detachably attached to the sealed channel, and a base sequence capable of hydrogen bonding to a sample DNA and a polymer compound in a member constituting a part of the sealed channel when attached to the sealed channel The separation DNA binding substance that separates the sample DNA into normal DNA and abnormal DNA from the difference in binding force, and the separation DNA binding substance so that the sample DNA can pass through the separation DNA binding substance. Equipped with a selective separation filter that does not allow the passage of substances,
Introducing sample DNA into the sealed channel and applying the voltage to cause electrophoresis of the sample DNA in the sealed channel, and the detection unit measures the amount of normal DNA and / or abnormal DNA passing through A characteristic genetic diagnosis device. Selection that allows one of the selective separation filters to pass through the sample DNA and normal DNA used as a control, does not allow the passage of higher-molecular substances, and can capture a larger amount of polymer than the selective separation filter The genetic diagnosis device according to claim 10, wherein the genetic diagnosis device is a sex separation prefilter. The sample DNA and normal DNA used as a control can be passed so as to sandwich the selective separation filter, and a larger amount of polymer can be captured than the selective separation filter without passing a higher molecular substance. The genetic diagnostic apparatus according to claim 10, further comprising a selectable separation prefilter that can be used. The genetic diagnosis apparatus according to any one of claims 10 to 12, wherein the sealed channel is a capillary tube. The genetic diagnostic apparatus according to claim 13, wherein the inner wall of the capillary tube is coated with acrylamide. The buffer solution is stored in the first container and the first electrode is immersed, the buffer solution is stored in the second container and the second electrode is immersed,
Selective separation that is a sealed channel that connects between the first container and the second container, and allows sample DNA to pass through at least the electrophoresis direction side of the sealed channel and does not allow a DNA binding substance for separation to pass through. A closed flow path comprising a filter, a DNA binding substance for separating the sample DNA into normal DNA and abnormal DNA based on the difference in binding force, when a base sequence capable of hydrogen bonding to the sample DNA and the polymer compound are combined. Is filled with a buffer solution containing a linear polymer and a DNA binding control agent,
Introducing sample DNA into the closed channel,
A voltage is applied between the first electrode and the second electrode, the sample DNA in the sealed channel is electrophoresed,
A genetic diagnosis method comprising detecting normal DNA and / or abnormal DNA. The closed flow path allows the sample DNA and normal DNA used as a control to pass through, does not allow a higher molecular weight substance to pass through, and can selectively capture a larger amount of polymer than the selective separation filter. The genetic diagnosis method according to claim 15, further comprising a prefilter, wherein the separation DNA-binding substance is sandwiched between the selective separation filter and the selective separation prefilter. The buffer solution is stored in the first container and the first electrode is immersed, the buffer solution is stored in the second container and the second electrode is immersed,
A closed flow path connecting the first container and the second container, wherein a base sequence capable of hydrogen bonding to a sample DNA and a polymer compound are bonded to each other, and the sample DNA is compared with normal DNA from the difference in binding force A sealed flow comprising: a separation DNA-binding substance that separates into abnormal DNA; and a selective separation filter that allows the sample DNA to pass through the separation DNA-binding substance and does not allow the separation DNA-binding substance to pass through. The path is filled with a buffer containing a linear polymer and a DNA binding control agent,
Introducing sample DNA into the closed channel,
A voltage is applied between the first electrode and the second electrode, the sample DNA in the sealed channel is electrophoresed,
A genetic diagnosis method comprising detecting normal DNA and / or abnormal DNA. The buffer solution is stored in the first container and the first electrode is immersed, the buffer solution is stored in the second container and the second electrode is immersed,
A sealed channel that communicates between the first container and the second container, and is a sealed channel equipped with a detachable member that constitutes a part of the sealed channel, and is capable of hydrogen bonding to sample DNA. A base compound and a high molecular weight compound, and the separation DNA binding substance that separates the sample DNA into normal DNA and abnormal DNA from the difference in binding force, and the sample DNA passing through the separation DNA binding substance A closed flow path comprising a selective separation filter that does not allow the separation DNA-binding substance to pass through, and is filled with a buffer containing a linear polymer and a DNA binding control agent;
Introducing sample DNA into the closed channel,
A voltage is applied between the first electrode and the second electrode, the sample DNA in the sealed channel is electrophoresed,
A genetic diagnosis method comprising detecting normal DNA and / or abnormal DNA.

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