• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Protozoa detection equipment and procedure that integrates a sampling device and a protozoon detection kit in a single unit, preferably housed in a portable enclosure, the sampling device admitting two variants, one of them, more complete, to take of samples for a longer time, of the order of days or weeks, while the other, simpler, is indicated for taking samples in a short time, of the order of hours at most. The protozoan detection kit includes reactive strips along with portable equipment and reagents to carry out in-situ dna extraction processes (deoxyribonucleic acid), amplification by pcr (polymerase chain reaction), and hybridization/revealed. These test strips present the result of the analysis by means of specific markings of the amplified products. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2603380A1
    申请号:ES201730046
    申请日:2017-01-17
    公开日:2017-02-27
    发明作者:Javier ORÓS MONGE;Ignacio Dominguez Ubieto
    申请人:Ox-Cta S L;Ox-Cta Sl;
    IPC主号:
    专利说明:

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    DESCRIPTION
    Equipment and procedure for detecting protozoa
    The present specification refers, as its title indicates, to a device and procedure for detecting protozoa of the type used discontinuously and portablely for water analysis.
    Field of the Invention
    The invention relates to the field of analysis and measurement equipment and procedures for the optimal use of water resources, especially water for human / animal consumption, aquaculture, cooling water, as well as water for other industrial uses. The equipment is integrated into an efficient, ecological and economically viable biocidal procedure that guarantees the complete sanitation of water, that is, the elimination of bacteria, fungi, viruses, algae and also protozoa and the bacteria that they can harbor inside.
    Current state of the art
    Water is essential for our daily life. Water quality, whether it is used for drinking, domestic use, food production or recreational purposes, has an important impact on health. Poor quality water can cause disease outbreaks at different scales: 80% of gastrointestinal infectious and parasitic diseases and one third of the deaths caused by these infections are due to the use and consumption of contaminated water.
    At present, European legislation establishes microbiological limits for water consumption with respect to some bacteria. However, bacteria control is not enough to ensure water quality.
    Studies have shown that not only bacteria can cause disease; In fact, free-living amoebas can also be found in the water (protozoa capable of colonizing water networks that pose a serious health risk). Acanthamoeba is the most frequent amoeba, (representing more than 90% of the total amoebae present in the water) having a great capacity to house an important variety of pathogenic microorganisms, such as viruses (adenovirus, polio virus, enterovirus, etc. .), bacteria (Campylobacter, E. coli, Legionella, Listeria, Staphylococcus, Salmonella, etc.) and fungi (Cryptococcus, Blastomyces, Sporothrix, Histoplasma, etc.).
    This means that there is a high need for equipment for the detection of protozoa, with a view to their subsequent elimination.
    There are several patents and scientific documents published, related to this type of problem. Most of the solutions, such as those included in patents ES2177380 "Procedure for the elimination of biological contaminants from water" and WO2015015027 "Method for eliminating micro-organisms in water by filtration", are limited to a general filtering, trying to eliminate micro organisms, but without being able to specifically detect protozoa.
    Some methods are known for detecting organisms such as protozoa in water, as we find claimed in patents ES2158854 "Oligonucleootides derived from the family of SOD genes" and ES2331645 "Procedure for controlling the growth of aquatic plants and zoological organisms", but they are complicated processes, which require very specific and delicate equipment that can only be carried out in the laboratory, not being capable of being carried out on-site or portable.
    Some sampling equipment is also known, such as the one described in ES2346630 "Continuous monitoring device for species suspended in water", but they are intended for a fixed use in a location and for continuous, non-discontinuous sampling, not incorporating any type of specific detection element of protozoa.
    Description of the invention
    In order to solve the problem currently existing in the detection of protozoa in water in a discontinuous and portable manner, the protozoan detection equipment and procedure object of the present invention has been devised, which integrates a single device into a single device. Sampling and a protozoan detection kit, which is housed either in a single portable enclosure, or in two portable enclosures, one for the sampling device and the other for the protozoan detection kit.
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    The sampling device is provided in two variants, one of them, more complete, for sampling for a longer time, of the order of days or weeks, while the other, more simple, is indicated for sampling in short time, of the order of minutes or hours.
    The protozoan detection kit includes test strips together with portable equipment and reagents to perform in-situ DNA extraction processes (deoxyribonucleic acid), PCR amplification (polymerase chain reaction), and hybridization / development . These test strips present the result of the analysis by means of specific markings of the amplified products, in the form of colored bands that react to the presence of the protozoa sought.
    In both cases the equipment has a main filter through which the water passes, with a passing light chosen so that the cysts of the protozoa or the individuals who are free in the water remain in it. Once the water is filtered, the filter material with the protozoa remains, if any. This material, the result of filtering, is the one that is subsequently used to make the pCr and study the presence of the species or species throughout its DNA.
    Advantages of the invention
    This equipment and procedure of detection of protozoa that is presented provides multiple advantages over the systems currently available, being the most important that allows to be integrated into an effective, ecological and economically viable biocidal procedure that allows to guarantee the complete sanitation of water, that is, elimination of bacteria, fungi, viruses, algae and also protozoa and the bacteria that they can harbor inside.
    Another important advantage is that it is a portable system, which can be used anywhere, including the installation of the client, and in much less time than required by laboratory processes.
    It is important to note that this equipment is specifically designed for discontinuous use, allowing results to be obtained with samples of days or weeks in the case of the preferred embodiment, or with samples of minutes or hours in the case of the alternative embodiment, providing that personnel technician can perform measurements in a wide variety of sites with the same equipment.
    Another of the most important advantages to highlight is that it is based on the amplification through the polymerase chain reaction (PCR) of a particular region of the DNA corresponding to the target protozoan species or species, and its subsequent detection by hybridization to a specific probe and revealed by an immunochromatography strip, thus allowing the detection and identification of the protozoan with great sensitivity and specificity, superior to other systems.
    It is also important to highlight that it is a fast and easy DNA extraction system, and there is not much dependence on the instrumental equipment, which leads to a complete Acanthamoeba detection equipment in the water that can be applied outside the laboratory, in situ where require the end customer, with extraordinary sensitivity.
    Description of the figures
    To better understand the object of the present invention, a preferential practical embodiment of a protozoan detection equipment has been represented in the annexed plan.
    In this plan, figure -1- shows a general block diagram of the equipment.
    Figure -2- shows a general block diagram of the sampling device in its preferred embodiment.
    Figure -3- shows a general block diagram of the sampling device in its alternative embodiment.
    Figure -4- shows a general block diagram of the protozoan detection kit
    Figure -5- shows a test strip and its main areas.
    Preferred Embodiment of the Invention
    The protozoan detection equipment object of the present invention basically comprises, as can be seen in the attached drawing, a sampling device (1) and a protozoan detection kit (2), preferably integrated within a single enclosure ( 23) portable, although it is planned that alternatively
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    They can be housed in two portable enclosures, one for the sampling device and another for the protozoan detection kit.
    In a preferred embodiment, the sampling device (1a) in turn comprises a water inlet from the distribution line (3), a water inlet without pressure (4), associated with a pump (5) and a valve safety (6), a prefilter (7) followed by a main filter (8), with an associated sample filter (9), a flow meter (10) associated with a water outlet (11), and a programmer (12) control.
    The prefilter (7) cleans the water of the largest impurities and prevents the main filter (8) from clogging.
    The control programmer (12) controls the sampling period, which can be days to weeks, and regulates with the pump the filtering parameters: flow and frequency, commanding the start-up and stop of the equipment.
    An alternative embodiment of the invention, more simplified, is provided in which the sampling device (1b) comprises a water inlet from the distribution line (3), a water inlet without pressure (4), associated with a pump (5) and a safety valve (6), a main filter (8), and a flow meter (10) associated with a water outlet (11).
    In both cases the equipment has a main filter (8) through which the water passes, with a minimum passing light, chosen so that the cysts of the protozoa or the individuals who are free in the water remain . Once the water is filtered, the filter material with the protozoa remains, if any. This material, the result of filtering, is the one that is subsequently used to perform the PCR and study the presence of the species or species through its DNA.
    The sample inlet in the equipment can be by direct connection to the water inlet coming from the distribution line (3) or without that connection, to a water inlet without pressure (4). In the first case it is the same installation that drives the water through the equipment (including to avoid possible overpressure problems a regulating valve). The pump (5) is responsible for boosting the water flow to allow the sample to be processed when the equipment has not been able to connect directly to the customer's supply line. At the end of the system there is a flow meter (10) that allows us to check the volume of processed sample.
    The protozoan detection kit (2) comprises a plurality of test strips (13), PCR reagents (14), hybridization / development reagents (15), a portable thermoblock (16) powered by a thermoblock battery ( 17) and a portable thermal cycler (18) powered by a thermocycler battery (19).
    The test strips (13) are nitrocellulose strips, preferably rectangular, on which the antibodies that detect the specific labels of the amplified products have been dosed, each of the strips being divided into three areas that recognize the different labels employees or the control of the development control.
    The test strips (13) comprise an absorption area (24), which corresponds to the lower part of the strip, and which is introduced into the sample, a test area (25) formed by a chromatographic membrane protected with a transparent plastic , and a manipulation area (26) corresponding to the final part of the strip, formed of an absorbent material protected by a plastic of color that can be labeled. The test area (25) of the test strips (13) has up to 3 different bands, the first line (22) indicating on the bottom the presence or not of protozoa, the second line (21) acts as a control of the process of extraction and amplification, and the third line (20) acting as control of the development process.
    The protozoan detection equipment object of the present invention is directed to develop a protozoan detection procedure in water comprising:
    - a first phase of sampling,
    - and a second phase of detection of protozoa in the samples obtained.
    The first sampling phase has slight differences depending on whether we use the sampling device (1) in its preferred embodiment (1a) or in its alternative embodiment (1b).
    In the case of using the preferred embodiment of the sampling device (1a), the sampling phase is performed by said sampling device (1a) and comprises in this case:
    - a first filtering stage, in which the analyte is retained in the main filter (8),
    - a second stage of backwashing, in which the organisms sought are moved from the main filter (8) to the sample filter (9),
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    - and a third final stage of reassembly in which the connections are left as they were initially, the circuit is disinfected by the passage of a biocide and the tubenas are forged.
    The filtering stage comprises in this case:
    - a first homogenization step, in which a few liters of water are allowed to pass biocidal remains from the last operation,
    - a second filtering step, in which the water is allowed to pass, coming from the water inlet coming from the distribution line (3) or from the inlet of water without pressure (4), through the prefilter (7) and of the main filter (8), controlling by means of the flow meter (10) that the water flow is adequate.
    The backwashing stage is carried out, in this case, after the necessary time has elapsed, controlled by the control programmer (12), and comprises:
    - a first investment step, connecting the pipes so that the water flow, coming from the water inlet coming from the distribution line (3) or from the inlet of water without pressure (4), enters through the filter outlet main (8), changing the direction of the water circulation and causing the particles attached to the main filter (8) to peel off and thus be trapped in the sample filter
    (9),
    - and a second sample removal step, in which the sample filter (9) is removed for further examination.
    In the case of using the alternative embodiment of the sampling device (1b), the sampling phase is carried out by means of said sampling device (1b) and comprises in this case:
    - a first homogenization step, in which a few liters of water are allowed to pass biocidal remains from the last operation,
    - a second filtering step, in which the water is allowed to pass, coming from the water inlet coming from the distribution line (3) or from the inlet of water without pressure (4), through the main filter (8 ), controlling by means of the flow meter (10) that the water flow is adequate,
    - ending with a third filter separation step for your next exam.
    The phase of detection of protozoa in the samples obtained is carried out by means of the detection kit of protozoa (2), and is based on the amplification by means of the polymerase chain reaction (PCR) of a specific region of the DNA corresponding to the species or target protozoan species, and their subsequent detection by hybridization to a specific probe and revealed by an immunochromatography strip. In this way, the kit allows the detection and identification of the protozoan with great sensitivity and specificity.
    The phase of detection of protozoa in the samples includes:
    - a first step of DNA extraction (deoxyribonucleic acid),
    - a second amplification step by PCR (polymerase chain reaction)
    - and a third step of hybridization and development,
    obtaining, at the end of the process, bands of different colors along the membrane of the test strips (13), depending on the presence or absence of protozoa in the sample, the color and number of bands obtained.
    The DNA extraction step is based on the union of the DNA to silica-coated magnetic particles, carrying out the DNA extraction directly from the filter samples.
    In the step of amplification by PCR, the simultaneous amplification of a fragment of the DNA polymerase gene of the target species or species and a fragment of a human control gene (beta-globin), which is used as an indicator of absence, is performed of PCR inhibitors in the amplified DNA sample.
    In the hybridization and development step, specific binding of the amplified DNA fragments to a series of probes anchored to colored latex particles occurs, migrating this colloid + DNA complex along a membrane on which antibodies have been deposited. specific, the antibodies recognizing some marks added to the amplification products during PCR, so that the PCR + colloid complex binds to the membrane resulting in the appearance of a colored band.
    Each of the products generated during the PCR (amplified from the control gene, amplified from the target species or species) carries a specific marking so that, at the end of the process, bands of different colors will be visualized along the membrane. The color and number of bands will depend on the presence or absence of protozoa in the sample. Thus, all test strips include a development control line (20)
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    preferably green, whose appearance is indicative that the immunochromatography has been developed correctly, a process control line (21) (extraction + amplification), preferably blue, which informs us that the extraction and amplification process has developed correctly, and a line associated with the presence of protozoa (22), preferably red.
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    The person skilled in the art will easily understand that he can combine characteristics of different embodiments with characteristics of other possible embodiments, provided that such combination is technically possible.
    10 All information referring to examples or embodiments is part of the description of the invention.
    权利要求:
    Claims (1)
    [1]
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    1 - Protozoan detection equipment, of the type used discontinuously and portable for water analysis, characterized in that it comprises a sampling device (1) and a protozoan detection kit (2), within one or two portable enclosures (23), including the protozoan detection kit (2) a plurality of test strips (13), PCR reagents (14), hybridization / development reagents (15), a portable thermoblock (16) , powered by a thermoblock battery (17) and a portable thermal cycler (18) powered by a thermocycler battery (19).
    2 - Protozoan detection equipment, according to the previous claim, characterized in that the sampling device (1a) comprises a water inlet coming from the distribution line (3), a water inlet without pressure (4), associated with a pump (5) and a safety valve (6), a prefilter (7) followed by a main filter (8), with an associated sample filter (9), a flow meter (10) associated with a water outlet (11), and a control programmer (12).
    3 - Protozoan detection equipment, according to claim 1, characterized in that the sampling device (1b) comprises a water inlet coming from the distribution line (3), a water inlet without pressure (4), associated with a pump (5) and a safety valve (6), a main filter (8), and a flow meter (10) associated with a water outlet (11).
    4 - Protozoan detection equipment, according to any of the preceding claims, characterized in that the test strips (13) are nitrocellulose strips, preferably rectangular, on which the antibodies that detect the specific product labels have been dosed amplified, each of the strips being divided into three areas that recognize the different markings used or the development control protein.
    5 - Protozoan detection equipment, according to any of the preceding claims, characterized in that the test strips (13) comprise an absorption area (24), which corresponds to the lower part of the strip, and which is introduced into the sample, a test area (25) formed by a chromatographic membrane protected with a transparent plastic, and a manipulation area (26) corresponding to the final part of the strip, formed of an absorbent material protected by a plastic of color that can be labeled.
    6 - Protozoan detection equipment, according to any of the preceding claims, characterized in that the test area (25) of the test strips (13) has up to 3 different bands, indicating the first line (22) on the bottom of the presence or not of protozoa, the second line (21) acts as a control of the extraction and amplification process, and the third line (20) acts as a control of the development process.
    7 - Procedure for detecting protozoa in water using equipment such as that described in the preceding claims, characterized in that it comprises a first phase of water sampling by means of the sampling device (1a) or (1b), and a second phase of detection of protozoa in the samples obtained, using the protozoan detection kit (2).
    8 - Procedure for detecting protozoa in water, according to claim 7, characterized in that, when the sampling phase is carried out by means of the sampling device (1a), it comprises a first filtering stage, in which the analyte is retained in the main filter (8), a second backwash stage, in which the organisms sought are moved from the main filter (8) to the sample filter (9), and a third final reassembly stage in which the connections are left as they were initially, the circuit is disinfected by the passage of a biocide and the pipes are emptied.
    9 - Procedure for detecting protozoa in water, according to claim 8, characterized in that the filtering stage comprises a first homogenization step, in which a few liters of water are allowed to pass biocide residues from the last operation, followed of a second filtering step, in which the water is allowed to pass, coming from the water inlet coming from the distribution line (3) or from the inlet of water without pressure (4), through the prefilter (7) and of the main filter (8), controlling by means of the flow meter (10) that the water flow is adequate.
    10 - Procedure for detecting protozoa in the water, according to any of claims 8 and 9, characterized in that the backwash stage is performed after the necessary time has elapsed, controlled by the control programmer (12), and comprises a first step of inversion, connecting the pipes so that the water flow, coming from the water inlet coming from the distribution line (3) or from the water inlet without pressure (4), enters through the main filter outlet (8) , changing the direction of the water circulation and causing the particles attached to the main filter (8) to peel off and thus be trapped in
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    the sample filter (9), and a second sample removal step, in which the sample filter (9) is disassembled for further examination.
    11 - Procedure for detecting protozoa in water, according to claim 7, characterized in that, when the sampling phase is carried out by means of the sampling device (1b), it comprises a first homogenization step, in which a few liters are allowed to pass of water to remove biocidal remains from the last operation, followed by a second filtering step, in which the water is allowed to pass, coming from the water inlet coming from the distribution line (3) or from the water inlet without pressure (4), through the main filter (8), controlling by means of the flow meter (10) that the water flow is adequate, ending with a third step of separating the filter for its next examination.
    12 - Method of detecting protozoa in water, according to any of claims 7 to 11, characterized in that the phase of detecting protozoa in the samples obtained comprises a first step of DNA extraction, a second step of amplification by PCR and a third step of hybridization and development, obtaining at the end of the process bands of different colors along the membrane of the test strips (13), depending on the color and number of bands of the presence or absence of protozoa in the sample.
    13 - Procedure for detecting protozoa in water, according to claim 12, characterized in that the DNA extraction step is based on the union of DNA to magnetic particles coated with silica, performing DNA extraction directly from the filter samples.
    14 - Procedure for detecting protozoa in the water, according to any of claims 12 and 13, characterized in that in the step of amplification by PCR simultaneous amplification of a fragment of the DNA polymerase gene of the target species or species is performed and of a fragment of a human control gene (beta-globin), which is used as an indicator of the absence of PCR inhibitors in the amplified DNA sample.
    15 - Method of detecting protozoa in water, according to any of claims 12 to 14, characterized in that in the hybridization and development step the specific union of the amplified DNA fragments to a series of probes anchored to particles of particles of colored latex, migrating this DNA + colloid complex along a membrane on which specific antibodies have been deposited, the antibodies recognizing marks added to the amplification products during PCR, so that the PCR + colloid complex is joins the membrane resulting in the appearance of a colored band.
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    同族专利:
    公开号 | 公开日
    WO2018134452A1|2018-07-26|
    ES2603380B1|2017-09-12|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20060148068A1|2003-01-09|2006-07-06|Jacques Noury|Biological sensor|
    US20100216225A1|2009-02-25|2010-08-26|Ag-Defense Systems, Inc.|Portable microorganism detection unit|
    WO2011157584A1|2010-06-16|2011-12-22|Hochschule Niederrhein|Legionella test|WO2019043277A1|2017-08-31|2019-03-07|Medina Venegas Pedro Manuel|Method and device for analysing nucleic acids|PT592894E|1992-10-13|2001-11-30|Hoffmann La Roche|OLIGONUCLEOTIDES DERIVED FROM THE SOD FAMILY|
    ES2177380B1|2000-02-09|2004-08-16|Universidad De Granada|PROCEDURE FOR THE ELIMINATION OF WATER BIOLOGICAL POLLUTANTS.|
    OA12217A|2000-02-17|2006-05-09|Garnett Inc|Method of controlling zoological and aquatic plantgrowth.|
    ES2346630B1|2010-06-07|2011-08-04|Ox-Cta, S.L|CONTINUOUS MONITORING DEVICE FOR WATER SUSPENSION SPECIES.|
    ES2530591B1|2013-07-31|2015-12-09|Consejo Superior De Investigaciones Científicas |PROCEDURE FOR THE ELIMINATION OF MICROORGANISMS IN WATER BY FILTRATION|
    法律状态:
    2017-09-12| FG2A| Definitive protection|Ref document number: 2603380 Country of ref document: ES Kind code of ref document: B1 Effective date: 20170912 |
    2017-11-30| PC2A| Transfer of patent|Owner name: OX-COMPANIA DE TRATAMIENTO DE AGUAS, S.L. Effective date: 20171130 |
    优先权:
    申请号 | 申请日 | 专利标题
    ES201730046A|ES2603380B1|2017-01-17|2017-01-17|PROTOZO DETECTION EQUIPMENT AND PROCEDURE|ES201730046A| ES2603380B1|2017-01-17|2017-01-17|PROTOZO DETECTION EQUIPMENT AND PROCEDURE|
    PCT/ES2017/070625| WO2018134452A1|2017-01-17|2017-09-21|Device and methods for detecting protozoa|
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