WO2022071908A1 - A modular and rapid real-time pcr device - Google Patents

A modular and rapid real-time pcr device Download PDF

Info

Publication number
WO2022071908A1
WO2022071908A1 PCT/TR2021/050984 TR2021050984W WO2022071908A1 WO 2022071908 A1 WO2022071908 A1 WO 2022071908A1 TR 2021050984 W TR2021050984 W TR 2021050984W WO 2022071908 A1 WO2022071908 A1 WO 2022071908A1
Authority
WO
WIPO (PCT)
Prior art keywords
heating
carrier
heating unit
sample
region
Prior art date
Application number
PCT/TR2021/050984
Other languages
French (fr)
Inventor
Mehmet Can ALPHAN
Ibrahim Ertugrul YALCIN
Lutfi ARDA
Ibrahim Ilker OZYIGIT
Original Assignee
Bahcesehir Universitesi
Marmara Universitesi Rektorlugu Ozel Kalem Birimi
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from TR2020/15580A external-priority patent/TR202015580A2/en
Application filed by Bahcesehir Universitesi, Marmara Universitesi Rektorlugu Ozel Kalem Birimi filed Critical Bahcesehir Universitesi
Priority to US18/029,119 priority Critical patent/US20230372943A1/en
Publication of WO2022071908A1 publication Critical patent/WO2022071908A1/en

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L7/00Heating or cooling apparatus; Heat insulating devices
    • B01L7/52Heating or cooling apparatus; Heat insulating devices with provision for submitting samples to a predetermined sequence of different temperatures, e.g. for treating nucleic acid samples
    • B01L7/525Heating or cooling apparatus; Heat insulating devices with provision for submitting samples to a predetermined sequence of different temperatures, e.g. for treating nucleic acid samples with physical movement of samples between temperature zones
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L2300/00Additional constructional details
    • B01L2300/08Geometry, shape and general structure
    • B01L2300/0803Disc shape
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L2300/00Additional constructional details
    • B01L2300/08Geometry, shape and general structure
    • B01L2300/0832Geometry, shape and general structure cylindrical, tube shaped
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L3/00Containers or dishes for laboratory use, e.g. laboratory glassware; Droppers
    • B01L3/50Containers for the purpose of retaining a material to be analysed, e.g. test tubes
    • B01L3/508Containers for the purpose of retaining a material to be analysed, e.g. test tubes rigid containers not provided for above
    • B01L3/5085Containers for the purpose of retaining a material to be analysed, e.g. test tubes rigid containers not provided for above for multiple samples, e.g. microtitration plates
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N35/00Automatic analysis not limited to methods or materials provided for in any single one of groups G01N1/00 - G01N33/00; Handling materials therefor
    • G01N2035/00346Heating or cooling arrangements
    • G01N2035/00356Holding samples at elevated temperature (incubation)
    • G01N2035/00366Several different temperatures used

Definitions

  • the present invention relates to a new design for providing amplification in shorter time when compared with real-time PCR devices used presently and for using the device in different equipment thanks to the modular structure thereof, in order to provide subjecting of samples to denaturation, annealing and extension processes in real-time PCR (polymerase chain reaction) devices and heating of samples and applying of light to samples which become ready for measurement and measuring of light intensity emitted by samples where light has been applied.
  • real-time PCR polymerase chain reaction
  • PCR polymerase chain reaction
  • PCR polymerase chain reaction
  • PCR is essentially formed by the repetitions of three main cycles: (1) Denaturation, separating of the DNA with double strand to two single strands at 94 e C, (2) annealing, binding of primers specifically to the mold DNA in the form of strand at 50-60 e C and (3) extension, amplification of the region, delimited by primers, by Tag DNA polymerase at 72 e C.
  • the real-time PCR comprises a measurement step additionally. When samples prepared by means of different dye substances and tags come to the measurement position, they are stimulated by means of light at suitable wavelength, and correspondingly, the emission intensity of the light emitted by the samples is measured.
  • the targeted DNA part is copied at desired amounts and measurements thereof are realized.
  • the devices which exist already in the market, provide copying of the genetic material by means of repeating the reaction by realizing heating and cooling processes with the help of thermo-electric elements.
  • Samples are placed to the devices known in the present art, and heating, cooling and measurement processes are realized respectively as needed.
  • the cooling process and the heating process for reaching the desired temperature lead to long-lasting of the PCR processes.
  • the present invention relates to a new real-time PCR device which provides heating of the samples and which provides amplification in short time when compared with the presently used systems and which provides usage of the device with different equipment thanks to the modular structure thereof, for eliminating the abovementioned disadvantages and for bringing new advantages to the related technical field.
  • An object of the present invention is to provide an alternative system which provides subjecting of the samples to process in an accelerated manner.
  • Another object of the present invention is to provide an alternative system for real-time PCR device which will provide simultaneous subjecting of the samples, which are higher in number when compared with the presently used devices, to processes.
  • the present invention is a real-time PCR device comprising a heating mechanism for providing heating of samples and realizing measurement in the heated samples in order to subject the samples to denaturation, annealing and extension processes.
  • the subject matter PCR device comprises a heating unit carrier comprising at least one first heating unit which provides heating of a first heating region at a first temperature for the denaturation process, at least one second heating unit which provides heating of a second heating region at a second temperature for the annealing process, at least one third heating unit which provides heating of a third heating region at a third temperature for the extension process, a measurement unit for stimulating samples by sending light to a measurement region and for measuring the light emitted by the samples in correspondence with the sent light for the measurement process, wherein said first heating unit, said second heating unit, said third heating unit and said measurement unit are arranged in a first circular axis;
  • the subject matter PCR device comprises a sample carrier comprising at least one sample chamber placed in at least one point at a second circular axis which is parallel to said first circular axis; subject matter PCR device further comprises at least one movement mechanism which provides movement of the sample chamber in a manner providing passage of the sample chamber between said first heating region, said second heating
  • said heating unit carrier further comprises a measurement unit provided in said first circular axis and which defines a measurement region. Thanks to this structure, samples with increased number when compared with the present art are heated.
  • the heating units comprise a first heating element and a second heating element positioned mutually in a manner defining a heating region in between.
  • said sample carrier is in plate form
  • the heating unit carrier is in the form of a plate placed in a parallel manner to the sample carrier
  • the movement mechanism is configured to move the sample carrier and/or heating unit carrier in an axis passing through the center of the sample carrier and/or heating unit carrier.
  • said sample carrier is in cylindrical form
  • said heating unit carrier is configured to telescopically engage with the sample carrier
  • the movement mechanism is configured to move the sample carrier and/or heating unit carrier in an axis passing through the center of the sample carrier and/or heating unit carrier.
  • said sample carrier is in hexagonal or octagonal prism form
  • said heating unit carrier is in the form of a prism configured to telescopically engage with the sample carrier
  • the movement mechanism is configured to move the sample carrier and/or heating unit carrier in an axis passing through the center of the sample carrier and/or heating unit carrier.
  • the sample carrier comprises pluralities of sample chambers positioned in said second circular axis.
  • the sample carrier comprises sample chambers provided in the same number as the total number of measurement units and as the number of the heating units positioned in said second circular axis.
  • the sample chambers are arranged in a manner annealing with the radian between the radian sequential heating units between the sequentially arranged sample chambers and the measurement unit.
  • DNA parts can be amplified with PCR and the sufficient amount is obtained for sequencing and similar analyses from the samples in nano-gram amount.
  • the amount of genetic material to be obtained in short-duration cycles stays at very low amounts.
  • the desired genetic material can be obtained in a very rapid manner and in very high amounts.
  • much more amount of samples can be amplified when compared with real-time PCR devices used presently.
  • the present invention is a modular heating mechanism (10) which provides the placed samples to be subjected to denaturation, annealing, extension processes and which provides sending of light to the samples which are subjected to these processes and which provides measurement of the emission intensity of the light emitted by said samples as a reaction to the sent light, and a real-time PCR device comprising said heating mechanism (10). It essentially provides movement in a circular axis between the heating regions where the heaters, which provide realization of the denaturation, annealing, extension and measurement processes of samples, provide heating, and the measurement region where the measurement device (photoluminescence - PL) makes measurement.
  • the present invention comprises a heating unit carrier (100) and a sample carrier (200).
  • the sample carrier (200) and the heating unit carrier (100) move relatively with respect to each other and provide passage of the sample chambers (210) in the sample carrier (200) between the heating units (110) and the measurement unit (114) in the heating unit carrier (100) and provides subjecting to the denaturation, annealing and extension processes.
  • Figure 1 the representative view of the heating unit carrier and the sample carrier is given.
  • the sample carrier and the heating unit carrier can have any form which can realize the movement which will be defined below.
  • the heating unit carrier (100) comprises a first heating unit (111), a second heating unit (112), a third heating unit (113) and a measurement unit (114) arranged in a first axis.
  • the heating unit carrier (100) further comprises a holding unit (not shown in the figures).
  • the heating units (110) emit heat for providing subjecting of the samples to denaturation, annealing and extension processes.
  • the measurement unit (114) sends light at suitable wavelength and stimulates the samples prepared by means of different dye substances and tags when said samples come to a measurement region (134), and measures the emission intensity of the light emitted by the samples stimulated by means of light.
  • the holding unit provides waiting of the samples in a holding region.
  • the first heating unit (111 ) realizes heating in a manner keeping a first heating region (131) at a first temperature.
  • the second heating unit (112) realizes heating in a manner keeping a second heating region (132) at a second temperature.
  • the third heating unit (113) realizes heating in a manner keeping a third heating region (133) at a third temperature.
  • the heating units (110) can be associated with components like sensors, processors, etc. which control operation.
  • the measurement unit (114) can comprise light emitters for sending light to the samples, and sensors (photodiodes, etc.) for measuring the intensity of the light emitted by the samples stimulated by means of light. Since the details of the heating units and the measurement unit in real-time PCR devices are well known in the art, these details have not been given here.
  • the first temperature can be 94 degrees centigrade which is needed for denaturation
  • the second temperature can be 50-60 degrees centigrade which is needed for annealing
  • the third temperature can be 72 degrees centigrade which is needed for extension.
  • the heating units (110) can comprise a first heating element (121) and a second heating element (122) positioned in a manner defining a heating region in between.
  • the sample chambers (210) describe the mechanisms where the samples to be processed are placed in real-time PCR device.
  • a movement mechanism (not shown in the figures) provides movement of the heating unit carrier (100) and/or sample carrier (200) in a manner visiting of a first heating region (131 ), a second heating region (132), a third heating region (133) and a measurement region (134) by the sample chamber (210).
  • the movement mechanism can comprise drive elements like motor and can be controlled by drivers.
  • the sample carrier (200) comprises four sample chambers (210).
  • the sample carrier (200) also comprises a holding chamber (not illustrated in the figures) provided for waiting.
  • Said sample chambers (210) are arranged in the second circular axis (22) and are arranged at radians between the heating units (110) and the measurement region (114).
  • the heating units (110) and the measurement unit (114) can be arranged at 90 degrees/pi radian intervals.
  • the center angle through the center of the first circular axis (21) between two sequential units is 90 degrees.
  • three heating units and a measurement unit are placed to the first circular axis (21 ) with equal intervals.
  • the sample chambers (210) are arranged through the center of the second axis such that the center angles in between are 90 degrees, in other words, such that the center angles in between are 90 degrees/pi radians. While a sample chamber (210) is in a heating region (130), all other sample chambers (210) are positioned in the remaining heating regions (130) and one is positioned in the measurement region (134). Thus, the four samples are subjected to denaturation, annealing, extension and measurement processes simultaneously by using only three heating units (110) and a measurement unit (114).
  • the sample carrier (200) is provided in plate form, preferably in circular plate form.
  • the sample carrier (200) can realize its movement by rotating in an axis which passes through the center thereof and which is orthogonal to the plane where the plate extends.
  • the heating unit carrier (100) can also be in plate form and can be positioned in a parallel manner to the sample carrier (200).
  • the heating unit carrier (100) can comprise two bodies in plate form in a manner facing two faces of the sample carrier (200), and the first heating element (121) and the second heating element (122) of the heating units (110) can be positioned at these plates.
  • the heating unit carrier and the axes have also been shown in a representative manner in the lateral views.
  • the sample carrier (200) can be in cylindrical or octagonal prism or hexagonal prism form.
  • the heating unit carrier (100) can be provided in a manner telescopically engaging with the sample carrier (200).
  • One of the heating unit carrier (100) or the sample carrier (200) can rotate at an axis which passes through the centers thereof. In this manner, only the representative view of the sample carrier (200) is given and the heating unit carrier (100) can be configured in a fixed or movable manner in a compliant manner.
  • a sample is placed to one of the sample chambers (210).
  • the sample carrier (200) or the heating unit carrier (100) is moved such that the sample arrives at the first heating region (131).
  • the sample is placed to the sample chamber (210) which is positioned after the full sample chamber (210), and the heating unit carrier (100) or the sample carrier (200) is moved such that the recently filled sample chamber (210) comes to the first heating region (131).
  • the other chambers are respectively filled, and when the firstly filled sample chamber (210) exits the third heating unit (113), said firstly filled sample chamber (210) can come to the measurement region (134) and afterwards come to the first heating region (111 ) again, and the cycle can be repeated at a desired number of times.
  • One of the sample carrier (200) and the heating unit carrier (100) can be movable and other one can be fixed. While the movable one can have a body formed by cylindrical plate or arms, and the other one can be fixed to the body of the real-time PCR device by means of various arms.

Landscapes

  • Health & Medical Sciences (AREA)
  • Chemical & Material Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Biochemistry (AREA)
  • General Health & Medical Sciences (AREA)
  • Molecular Biology (AREA)
  • Clinical Laboratory Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Apparatus Associated With Microorganisms And Enzymes (AREA)

Abstract

The present invention relates to a real-time PCR device comprising a heating mechanism (10) for providing heating of samples and realizing measurement in the heated samples in order to subject the samples to denaturation, annealing and extension processes. Accordingly, the subject matter PCR device comprises a heating unit carrier (100) comprising at least one first heating unit (111) which provides heating of a first heating region (131) at a first temperature for the denaturation process, at least one second heating unit (112) which provides heating of a second heating region (132) at a second temperature for the annealing process, at least one third heating unit (113) which provides heating of a third heating region (133) at a third temperature for the extension process, a measurement unit (114) for stimulating samples by sending light to a measurement region (134) and for measuring the light emitted by the samples in correspondence with the sent light for the measurement process, wherein said first heating unit (111), said second heating unit (112), said third heating unit (113) and said measurement unit (114) are arranged in a first circular axis (21); the subject matter PCR device comprises a sample carrier (200) comprising at least one sample chamber (210) placed in at least one point at a second circular axis (22) which is parallel to said first circular axis (21); subject matter PCR device further comprises at least one movement mechanism which provides movement of the sample chamber in a manner providing passage of the sample chamber between said first heating region (131), said second heating region (132), said third heating region (133) and said measurement region (134).

Description

A MODULAR AND RAPID REAL-TIME PCR DEVICE
TECHNICAL FIELD
The present invention relates to a new design for providing amplification in shorter time when compared with real-time PCR devices used presently and for using the device in different equipment thanks to the modular structure thereof, in order to provide subjecting of samples to denaturation, annealing and extension processes in real-time PCR (polymerase chain reaction) devices and heating of samples and applying of light to samples which become ready for measurement and measuring of light intensity emitted by samples where light has been applied.
PRIOR ART
Studies in the field of molecular biology and bio-engineering are rapidly increasing worldwide. In molecular biology studies, amplifying of the specific DNA and RNA parts by isolation and presence of specific gene parts in the target living being and the detection of the amount are among the most important components of these studies. In these studies, PCR (polymerase chain reaction) device is frequently used. PCR is based on amplifying the genetic material by means of chemical methods upon amplifying and measuring of targeted DNA region (mostly genes). In amplifying of the desired gene part, the target gene part is copied by a very repetitive reaction with the help of Tag DNA polymerase enzyme and bases added to the medium. Thanks to purified DNA polymerases and chemically extended DNA oligonucleotides, it is possible that a specially determined DNA array is copied without needing a rapid and living cell. This technique is called “polymerase chain reaction (PCR)”. Thanks to this technique, that DNA part is copied billions of times in an in vitro manner without knowing all of the genome and without needing host cell and only by knowing the desired DNA array. The polymerase chain reaction (PCR) is an in vitro and in vivo DNA amplification method, and the reactions are based on repeating three events, which are at different temperatures, in the form of cycles. DNA parts can be amplified with PCR, and sufficient amount can be obtained for sequencing and similar analyses from the samples in nano-gram amount.
PCR is essentially formed by the repetitions of three main cycles: (1) Denaturation, separating of the DNA with double strand to two single strands at 94eC, (2) annealing, binding of primers specifically to the mold DNA in the form of strand at 50-60eC and (3) extension, amplification of the region, delimited by primers, by Tag DNA polymerase at 72eC. The real-time PCR comprises a measurement step additionally. When samples prepared by means of different dye substances and tags come to the measurement position, they are stimulated by means of light at suitable wavelength, and correspondingly, the emission intensity of the light emitted by the samples is measured.
As a result of repetition of these three steps many times, the targeted DNA part is copied at desired amounts and measurements thereof are realized. The devices, which exist already in the market, provide copying of the genetic material by means of repeating the reaction by realizing heating and cooling processes with the help of thermo-electric elements.
Samples are placed to the devices known in the present art, and heating, cooling and measurement processes are realized respectively as needed. The cooling process and the heating process for reaching the desired temperature lead to long-lasting of the PCR processes.
In order to realize the exact diagnosis of viral diseases like Covid-19, the genetic material of the virus which leads to the disease is copied in the samples taken from the body of the person who is being tested, and is brought to amounts which can be detected, and PCR method is frequently used in making the detection and in exact realization of the diagnosis and is accepted as the most reliable diagnosis method. However, since the detection of the target genetic material lasts long by realizing sufficient copying and since the sampling capacities of presently used devices are low, usage of alternative systems like fast test kits, which have low accuracy ratios but which can give more rapid result, is needed.
As a result, because of the abovementioned problems, an improvement is required in the related technical field.
BRIEF DESCRIPTION OF THE INVENTION
The present invention relates to a new real-time PCR device which provides heating of the samples and which provides amplification in short time when compared with the presently used systems and which provides usage of the device with different equipment thanks to the modular structure thereof, for eliminating the abovementioned disadvantages and for bringing new advantages to the related technical field. An object of the present invention is to provide an alternative system which provides subjecting of the samples to process in an accelerated manner.
Another object of the present invention is to provide an alternative system for real-time PCR device which will provide simultaneous subjecting of the samples, which are higher in number when compared with the presently used devices, to processes.
In order to realize the abovementioned objects and the objects which are to be deducted from the detailed description below, the present invention is a real-time PCR device comprising a heating mechanism for providing heating of samples and realizing measurement in the heated samples in order to subject the samples to denaturation, annealing and extension processes. Accordingly, the improvement of the present invention is that the subject matter PCR device comprises a heating unit carrier comprising at least one first heating unit which provides heating of a first heating region at a first temperature for the denaturation process, at least one second heating unit which provides heating of a second heating region at a second temperature for the annealing process, at least one third heating unit which provides heating of a third heating region at a third temperature for the extension process, a measurement unit for stimulating samples by sending light to a measurement region and for measuring the light emitted by the samples in correspondence with the sent light for the measurement process, wherein said first heating unit, said second heating unit, said third heating unit and said measurement unit are arranged in a first circular axis; the subject matter PCR device comprises a sample carrier comprising at least one sample chamber placed in at least one point at a second circular axis which is parallel to said first circular axis; subject matter PCR device further comprises at least one movement mechanism which provides movement of the sample chamber in a manner providing passage of the sample chamber between said first heating region, said second heating region, said third heating region and said measurement region. Thus, by using different heating units for different processes, the need for waiting for cooling and heating is avoided, and the process is accelerated.
In a possible embodiment of the present invention, said heating unit carrier further comprises a measurement unit provided in said first circular axis and which defines a measurement region. Thanks to this structure, samples with increased number when compared with the present art are heated. In another possible embodiment of the present invention, the heating units comprise a first heating element and a second heating element positioned mutually in a manner defining a heating region in between.
In another possible embodiment of the present invention, said sample carrier is in plate form, and the heating unit carrier is in the form of a plate placed in a parallel manner to the sample carrier, and the movement mechanism is configured to move the sample carrier and/or heating unit carrier in an axis passing through the center of the sample carrier and/or heating unit carrier.
In another possible embodiment of the present invention, said sample carrier is in cylindrical form, and said heating unit carrier is configured to telescopically engage with the sample carrier, and the movement mechanism is configured to move the sample carrier and/or heating unit carrier in an axis passing through the center of the sample carrier and/or heating unit carrier.
In another possible embodiment of the present invention, said sample carrier is in hexagonal or octagonal prism form, and said heating unit carrier is in the form of a prism configured to telescopically engage with the sample carrier, and the movement mechanism is configured to move the sample carrier and/or heating unit carrier in an axis passing through the center of the sample carrier and/or heating unit carrier.
In another possible embodiment of the present invention, the sample carrier comprises pluralities of sample chambers positioned in said second circular axis.
In another possible embodiment of the present invention, the sample carrier comprises sample chambers provided in the same number as the total number of measurement units and as the number of the heating units positioned in said second circular axis.
In another possible embodiment of the present invention, the sample chambers are arranged in a manner annealing with the radian between the radian sequential heating units between the sequentially arranged sample chambers and the measurement unit.
DNA parts can be amplified with PCR and the sufficient amount is obtained for sequencing and similar analyses from the samples in nano-gram amount. Normally, in real-time PCR methods, long amplification duration is needed for obtaining desired amount of DNA. This situation is a disadvantage for obtaining high amount of genetic material. The amount of genetic material to be obtained in short-duration cycles stays at very low amounts. However, by means of the speed advantage which will be presented by the designed system/device, the desired genetic material can be obtained in a very rapid manner and in very high amounts. Moreover, much more amount of samples can be amplified when compared with real-time PCR devices used presently.
BRIEF DESCRIPTION OF THE FIGURES
In Figure 1 , a view of an embodiment of the heating mechanism of the real-time PCR device is given.
In Figure 2, a representative cross-sectional view of an embodiment of one of the heating unit is given.
In Figure 3, a top representative view of the embodiment where the sample carrier is in plate form and a lateral cross-sectional view where said embodiment comprises heating elements and a lateral cross-sectional view where said embodiment comprises the first heating element and the second heating element of the heating unit are given.
In Figure 4, a top representative view of the embodiment where the sample carrier is in octagonal prism form is given.
DETAILED DESCRIPTION OF THE INVENTION
In this detailed description, the subject matter is explained with references to examples without forming any restrictive effect only in order to make the subject more understandable.
The present invention is a modular heating mechanism (10) which provides the placed samples to be subjected to denaturation, annealing, extension processes and which provides sending of light to the samples which are subjected to these processes and which provides measurement of the emission intensity of the light emitted by said samples as a reaction to the sent light, and a real-time PCR device comprising said heating mechanism (10). It essentially provides movement in a circular axis between the heating regions where the heaters, which provide realization of the denaturation, annealing, extension and measurement processes of samples, provide heating, and the measurement region where the measurement device (photoluminescence - PL) makes measurement. With reference to Figure 1 , the present invention comprises a heating unit carrier (100) and a sample carrier (200). The sample carrier (200) and the heating unit carrier (100) move relatively with respect to each other and provide passage of the sample chambers (210) in the sample carrier (200) between the heating units (110) and the measurement unit (114) in the heating unit carrier (100) and provides subjecting to the denaturation, annealing and extension processes. In Figure 1 , the representative view of the heating unit carrier and the sample carrier is given. The sample carrier and the heating unit carrier can have any form which can realize the movement which will be defined below.
In more details, the heating unit carrier (100) comprises a first heating unit (111), a second heating unit (112), a third heating unit (113) and a measurement unit (114) arranged in a first axis. In a possible embodiment of the present invention, the heating unit carrier (100) further comprises a holding unit (not shown in the figures). The heating units (110) emit heat for providing subjecting of the samples to denaturation, annealing and extension processes. As known well in the art, the measurement unit (114) sends light at suitable wavelength and stimulates the samples prepared by means of different dye substances and tags when said samples come to a measurement region (134), and measures the emission intensity of the light emitted by the samples stimulated by means of light. The holding unit provides waiting of the samples in a holding region. The first heating unit (111 ) realizes heating in a manner keeping a first heating region (131) at a first temperature. The second heating unit (112) realizes heating in a manner keeping a second heating region (132) at a second temperature. The third heating unit (113) realizes heating in a manner keeping a third heating region (133) at a third temperature. The heating units (110) can be associated with components like sensors, processors, etc. which control operation. The measurement unit (114) can comprise light emitters for sending light to the samples, and sensors (photodiodes, etc.) for measuring the intensity of the light emitted by the samples stimulated by means of light. Since the details of the heating units and the measurement unit in real-time PCR devices are well known in the art, these details have not been given here.
The first temperature can be 94 degrees centigrade which is needed for denaturation, and the second temperature can be 50-60 degrees centigrade which is needed for annealing, and the third temperature can be 72 degrees centigrade which is needed for extension.
In a possible embodiment of the present invention, the heating units (110) can comprise a first heating element (121) and a second heating element (122) positioned in a manner defining a heating region in between. The sample chambers (210) describe the mechanisms where the samples to be processed are placed in real-time PCR device. There is at least one sample chamber (210) in a manner positioned in a second circular axis (22) which is parallel to the first circular axis (21 ) on the sample carrier (200).
A movement mechanism (not shown in the figures) provides movement of the heating unit carrier (100) and/or sample carrier (200) in a manner visiting of a first heating region (131 ), a second heating region (132), a third heating region (133) and a measurement region (134) by the sample chamber (210). The movement mechanism can comprise drive elements like motor and can be controlled by drivers.
In a possible embodiment of the present invention, the sample carrier (200) comprises four sample chambers (210). In a possible embodiment, the sample carrier (200) also comprises a holding chamber (not illustrated in the figures) provided for waiting. Said sample chambers (210) are arranged in the second circular axis (22) and are arranged at radians between the heating units (110) and the measurement region (114). For instance, the heating units (110) and the measurement unit (114) can be arranged at 90 degrees/pi radian intervals. In other words, the center angle through the center of the first circular axis (21) between two sequential units is 90 degrees. In other words, three heating units and a measurement unit are placed to the first circular axis (21 ) with equal intervals. In this case, the sample chambers (210) are arranged through the center of the second axis such that the center angles in between are 90 degrees, in other words, such that the center angles in between are 90 degrees/pi radians. While a sample chamber (210) is in a heating region (130), all other sample chambers (210) are positioned in the remaining heating regions (130) and one is positioned in the measurement region (134). Thus, the four samples are subjected to denaturation, annealing, extension and measurement processes simultaneously by using only three heating units (110) and a measurement unit (114).
With reference to Figure 3, the sample carrier (200) is provided in plate form, preferably in circular plate form. The sample carrier (200) can realize its movement by rotating in an axis which passes through the center thereof and which is orthogonal to the plane where the plate extends. In this possible embodiment, the heating unit carrier (100) can also be in plate form and can be positioned in a parallel manner to the sample carrier (200). In this possible embodiment, the heating unit carrier (100) can comprise two bodies in plate form in a manner facing two faces of the sample carrier (200), and the first heating element (121) and the second heating element (122) of the heating units (110) can be positioned at these plates. In the form seen from above, only the sample carrier (200) has been given, and the heating unit carrier and the axes have also been shown in a representative manner in the lateral views.
With reference to Figure 4, in a possible embodiment of the present invention, the sample carrier (200) can be in cylindrical or octagonal prism or hexagonal prism form. The heating unit carrier (100) can be provided in a manner telescopically engaging with the sample carrier (200). One of the heating unit carrier (100) or the sample carrier (200) can rotate at an axis which passes through the centers thereof. In this manner, only the representative view of the sample carrier (200) is given and the heating unit carrier (100) can be configured in a fixed or movable manner in a compliant manner.
The operation of the present invention whose details are given above can be realized as follows. A sample is placed to one of the sample chambers (210). The sample carrier (200) or the heating unit carrier (100) is moved such that the sample arrives at the first heating region (131). After a predetermined duration, the sample is placed to the sample chamber (210) which is positioned after the full sample chamber (210), and the heating unit carrier (100) or the sample carrier (200) is moved such that the recently filled sample chamber (210) comes to the first heating region (131). In this arrangement, the other chambers are respectively filled, and when the firstly filled sample chamber (210) exits the third heating unit (113), said firstly filled sample chamber (210) can come to the measurement region (134) and afterwards come to the first heating region (111 ) again, and the cycle can be repeated at a desired number of times.
One of the sample carrier (200) and the heating unit carrier (100) can be movable and other one can be fixed. While the movable one can have a body formed by cylindrical plate or arms, and the other one can be fixed to the body of the real-time PCR device by means of various arms.
The protection scope of the present invention is set forth in the annexed claims and cannot be restricted to the illustrative disclosures given above, under the detailed description. It is because a person skilled in the relevant art can obviously produce similar embodiments under the light of the foregoing disclosures, without departing from the main principles of the present invention. REFERENCE NUMBERS
10 Heating mechanism
100 Heating unit carrier
110 Heating unit
111 First heating unit
112 Second heating unit
113 Third heating unit
114 Measurement unit
121 First heating element
122 Second heating element
130 Heating region
131 First heating region
132 Second heating region
133 Third heating region
134 Measurement region
200 Sample carrier
210 Sample chamber
21 First circular axis
22 Second circular axis

Claims

1. A real-time PCR device (1 ) comprising a heating mechanism (10) for providing heating of samples and realizing measurement in the heated samples in order to subject the samples to denaturation, annealing and extension processes, wherein the subject matter PCR device comprises a heating unit carrier (100) comprising at least one first heating unit (111) which provides heating of a first heating region (131) at a first temperature for the denaturation process, at least one second heating unit (112) which provides heating of a second heating region (132) at a second temperature for the annealing process, at least one third heating unit (113) which provides heating of a third heating region (133) at a third temperature for the extension process, a measurement unit (114) for stimulating samples by sending light to a measurement region (134) and for measuring the light emitted by the samples in correspondence with the sent light for the measurement process, wherein said first heating unit (111), said second heating unit (112), said third heating unit (113) and said measurement unit (114) are arranged in a first circular axis (21); the subject matter PCR device comprises a sample carrier (200) comprising at least one sample chamber (210) placed in at least one point at a second circular axis (22) which is parallel to said first circular axis (21 ); subject matter PCR device further comprises at least one movement mechanism which provides movement of the sample chamber in a manner providing passage of the sample chamber between said first heating region (131), said second heating region (132), said third heating region (133) and said measurement region (134).
2. The real-time PCR device according to claim 1 , wherein said heating unit carrier (100) further comprises a holding unit provided in said first circular axis and which defines a holding region.
3. The real-time PCR device according to claim 1 , wherein the heating units (110) comprise a first heating element (121) and a second heating element (122) positioned mutually in a manner defining a heating region (130) in between.
4. The real-time PCR device according to claim 1 , wherein said sample carrier (200) is in plate form, and the heating unit carrier (100) is in the form of a plate placed in a parallel manner to the sample carrier (200), and the movement mechanism is configured to move the sample carrier (200) and/or heating unit carrier in an axis passing through the center of the sample carrier (200) and/or heating unit carrier (100). The real-time PCR device according to claim 1 , wherein said sample carrier (200) is in cylindrical form, and said heating unit carrier (100) is configured to telescopically engage with the sample carrier (200), and the movement mechanism is configured to move the sample carrier (200) and/or heating unit carrier (100) in an axis passing through the center of the sample carrier (200) and/or heating unit carrier (100). The real-time PCR device according to claim 1 , wherein said sample carrier (200) is in hexagonal or octagonal prism form, and said heating unit carrier (100) is in the form of a prism configured to telescopically engage with the sample carrier (200), and the movement mechanism is configured to move the sample carrier (200) and/or heating unit carrier in an axis passing through the center of the sample carrier (200) and/or heating unit carrier (100). The real-time PCR device according to claim 1 , wherein the sample carrier (200) comprises pluralities of sample chambers (210) positioned in said second circular axis (22). The real-time PCR device according to claim 6, wherein the sample carrier (200) comprises sample chambers (210) provided in the same number as the total number of measurement units (114) and as the number of the heating units (110) positioned in said second circular axis (22). The real-time PCR device according to claim 6 or 7, wherein the sample chambers (210) are arranged in a manner annealing with the radian between the radian sequential heating units (110) between the sequentially arranged sample chambers (210) and the measurement unit (114).
PCT/TR2021/050984 2020-09-30 2021-09-27 A modular and rapid real-time pcr device WO2022071908A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US18/029,119 US20230372943A1 (en) 2020-09-30 2021-09-27 Modular and rapid real-time pcr device

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
TR2020/15580 2020-09-30
TR2020/15580A TR202015580A2 (en) 2020-09-30 2020-09-30 A FAST AND MODULAR PCR DEVICE
TR2021/005429 2021-03-25
TR202105429 2021-03-25

Publications (1)

Publication Number Publication Date
WO2022071908A1 true WO2022071908A1 (en) 2022-04-07

Family

ID=80950649

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/TR2021/050984 WO2022071908A1 (en) 2020-09-30 2021-09-27 A modular and rapid real-time pcr device

Country Status (1)

Country Link
WO (1) WO2022071908A1 (en)

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5525300A (en) * 1993-10-20 1996-06-11 Stratagene Thermal cycler including a temperature gradient block
JP2008185389A (en) * 2007-01-29 2008-08-14 Yamaha Corp Temperature control device

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5525300A (en) * 1993-10-20 1996-06-11 Stratagene Thermal cycler including a temperature gradient block
JP2008185389A (en) * 2007-01-29 2008-08-14 Yamaha Corp Temperature control device

Similar Documents

Publication Publication Date Title
JP6996717B2 (en) Nucleic acid amplification device, nucleic acid amplification method and nucleic acid amplification chip
JP6745958B2 (en) Systems, methods, and apparatus for automated incubation
Yamamoto et al. PDMS–glass hybrid microreactor array with embedded temperature control device. Application to cell-free protein synthesis
US9388467B2 (en) Biochip and target DNA quantitative method
EP3954458A1 (en) Polymerase chain reaction system
KR20100070977A (en) A disposable multiplex polymerase chain reaction (pcr) chip and device
EP1964610B1 (en) Nucleic acid amplifier
KR101086611B1 (en) Apparatus for polynucleotide detection and quantitation
CA2631589A1 (en) Monitoring real-time pcr with label free intrinsic imaging
US20230372943A1 (en) Modular and rapid real-time pcr device
Lien et al. A microfluidic-based system using reverse transcription polymerase chain reactions for rapid detection of aquaculture diseases
WO2022071908A1 (en) A modular and rapid real-time pcr device
US20230372941A1 (en) Modular and rapid pcr device
CN109536384B (en) Digital PCR system for rapid absolute quantification of nucleic acid and application thereof
JP4426528B2 (en) Nucleic acid analysis method, nucleic acid analysis cell, and nucleic acid analyzer
CN111560310B (en) Random access type digital nucleic acid detection device and use method
KR20190084048A (en) Microfluidic device and sample analysis method
US20110195417A1 (en) Device for Thermally Regulating a Rotationally Symmetrical Container
RU2800583C2 (en) Polymerase chain reaction system
Chiou Biochip technology: a triad of micro-electro-mechanical (MEM), biochemical, and photonic technologies
Kim et al. Electrokinetically integrated microfluidic isolation and amplification of biomolecule-and cell-binding nucleic acids
JP2002000300A (en) Simple method for confirming base sequence

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 21876127

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

122 Ep: pct application non-entry in european phase

Ref document number: 21876127

Country of ref document: EP

Kind code of ref document: A1