|Publication number||US20060101830 A1|
|Application number||US 10/987,931|
|Publication date||May 18, 2006|
|Filing date||Nov 12, 2004|
|Priority date||Nov 12, 2004|
|Also published as||CA2586559A1, CA2586559C, CA2689969A1, CA2689969C, CA2731998A1, CA2731998C, CN100478629C, CN101099067A, CN101504221A, CN101504221B, EP1809957A2, EP1809957A4, US7051536, WO2006055073A2, WO2006055073A3|
|Publication number||10987931, 987931, US 2006/0101830 A1, US 2006/101830 A1, US 20060101830 A1, US 20060101830A1, US 2006101830 A1, US 2006101830A1, US-A1-20060101830, US-A1-2006101830, US2006/0101830A1, US2006/101830A1, US20060101830 A1, US20060101830A1, US2006101830 A1, US2006101830A1|
|Inventors||David Cohen, Sunand Banerji, Michael Denninger|
|Original Assignee||Bio-Rad Laboratories, Inc., A Corporation Of The State Of Delaware|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (20), Referenced by (4), Classifications (15), Legal Events (3)|
|External Links: USPTO, USPTO Assignment, Espacenet|
1. Field of the Invention
This invention resides in the field of laboratory apparatus for performing procedures that require simultaneous temperature control in a multitude of samples in a multi-receptacle sample block. In particular, this invention addresses concerns arising with the use of thermoelectric modules for temperature modulation and control.
2. Description of the Prior Art
The polymerase chain reaction (PCR) is one of many examples of chemical processes that require precise temperature control of reaction mixtures with rapid temperature changes between different stages of the procedure. PCR is a process for amplifying DNA, i.e., producing multiple copies of a DNA sequence from a single copy. PCR is typically performed in instruments that provide reagent transfer, temperature control, and optical detection in a multitude of reaction vessels such as wells, tubes, or capillaries. The process includes a sequence of stages that are temperature-sensitive, different stages being performed at different temperatures and the temperature being cycled through repeated temperature changes. In the typical PCR process, each sample is heated and cooled to three different target temperatures where the sample is maintained for a designated period of time. The first target temperature is about 95° C. which is the temperature required to separate double strands. This is followed by cooling to a target temperature of 55° C. for hybridization of the separated strands, and then heating to a target temperature of 72° C. for reactions involving the polymerase enzyme. The cycle is then repeated to achieve multiples of the product DNA, and the time consumed by each cycle can vary from a fraction of a minute to two minutes, depending on the equipment, the scale of the reaction, and the degree of automation. This thermal cycling is critical to the successful performance of the process, and is an important feature of any process that requires close control of temperature and a succession of stages at different temperatures. Many of these processes involve the simultaneous processing of large numbers of samples, each of a relatively small size, often on the microliter scale. In some cases, the procedure requires that certain samples maintained at one temperature while others are maintained at another. Laboratory equipment known as thermal cyclers have been developed to allow these procedures to be performed in an automated manner.
One of the methods for achieving temperature control over a multitude of samples in a thermal cycler or in any planar array, and also for placing segregated groups of samples at different temperatures, is by the use of thermoelectric modules. These modules are semi-conductor-based electronic components that function as small heat pumps through use of the Peltier effect, and can cause heat to flow in either direction, depending on the direction of current through the component. The many uses of thermoelectric modules include small laser diode coolers, portable refrigerators, and liquid coolers.
Thermoelectric modules are of particular interest in thermal cyclers in view of the localized temperature effect, electronic control, and rapid response that the modules offer. The modules are typically arranged edge-to-edge in a planar array to provide heating or cooling of a multitude of samples over a wide area, particularly when the samples are contained in a sample block, which is a unitary piece that has a flat undersurface and a number of wells or receptacles formed in its upper surface in a standardized geometrical arrangement. In the typical arrangement, the modules are placed under the sample block, and a heat sink, typically finned, is placed under the modules.
While the modules are highly effective and versatile, their efficiency can be compromised by a variety of factors in the construction of the cycler. The temperature changes can cause condensation on the module surfaces, for example, and the clamping apparatus that assures that the components are in full thermal contact can interfere with the heat sink fins. These and other concerns are addressed by the present invention.
In accordance with the present invention, the thermoelectric modules in a thermal cycler are placed inside an enclosure that is formed by the sample block, the heat sink and a support frame, and that is sealed against the intrusion of atmospheric moisture by gaskets, one of which is compressed between the sample block and the support frame and the other between the heat sink and the support frame. The gaskets allow for rapid assembly of the components and do not require manual positioning or alignment. Sealing can be achieved by simply placing the sample block, modules, and heat sink in the frame and securing these parts together.
This invention further resides in a construction for securement of a finned heat sink to the thermoelectric modules in a manner that does not compromise the fins of the heat sink in terms of the surface area of the fins or the access of the fins to air flowing past them. Securement is achieved by way of one or more clamping bars that are sufficiently thin to fit between the fins and of substantially smaller depth than the fins so that the most of the surface of each adjacent fin remains exposed. Preferably, the bars extend the full length of the adjacent fins, and most preferably, are in fact longer than the fins so that the ends of the bars will protrude beyond the fins to be secured to the remaining components of the assembly.
A still further innovation present by this invention is a novel configuration of an electric lead in a molded part that serves as a partition dividing a region sealed against atmospheric exposure from a neighboring region. The electric lead has two legs joined at one end by a cross-bar to form a “U” shape. The cross-bar is embedded in the molded part and both legs are exposed and available for electrical connections, one leg extending into the sealed region and the other leg extending into the neighboring region. The “U” shape facilitates the molding of the part around the lead, and the part with the lead thus embedded is useful in any electronic device or instrument that contains electronic components that require an environment in which they are protected from exposure to atmospheric moisture. One such instrument is a thermal cycler, where one leg of the lead is electrically connected to the thermoelectric module inside the enclosure and the other leg is electrically connected to external electrical components such as a power supply, a controller, or any such component that feeds or regulates current to the module.
Each of the several different aspects of the present invention is susceptible to a wide range of variation in terms of the configurations of each component, the arrangements of the components in the assembly, the particular instrument or apparatus in which they are incorporated, and the function that the instrument is designed to perform. A detailed review of one particular embodiment however will provide an understanding of the function and operation of the invention in each of its many embodiments. The figures hereto depict a thermal cycler for a PCR instrument as one such embodiment.
The components shown in the exploded perspective view of
The remaining components shown in
Components that are not shown in
The cross section of
Also visible in
The profile of the retainer element 26 has a section that is T-shaped with a vertical section 43 and a horizontal section 44 at one end of the vertical section. The vertical section 43 serves as a partition that separates the sealed enclosure from the external regions. The horizontal section 44 serves as a mounting surface for the fastening screws referred to above (shown only in
Also shown in
The orientation of the cross section of
While the Figure shows only the bolt, washers, and threaded boss at one end of the clamping bars, an identical bolt, washers and threaded boss exist at the other end in a symmetrical arrangement with those that are shown.
The components used in the practice of this invention can be components that were in existence at the time of filing of this application, including those that are readily available from suppliers. The thermoelectric modules, which are also known as Peltier devices, are units widely used as components in laboratory instrumentation and equipment, well known among those familiar with such equipment, and readily available from commercial suppliers of electrical components. Thermoelectric modules are small solid-state devices that function as heat pumps, operating under the theory that when electric current flows through two dissimilar conductors, the junction of the two conductors will either absorb or release heat depending on the direction of current flow. The typical thermoelectric module consists of two ceramic or metallic plates separated by a semiconductor material, of which a common example is bismuth telluride. In addition to the electric current, the direction of heat transport can further be determined by the nature of the charge carrier in the semiconductor (i.e., N-type vs. P-type). Thermoelectric modules can thus be arranged and/or electrically connected in the apparatus of the present invention to heat or to cool the sample block or portions of the sample block. A single thermoelectric module can be as thin as a few millimeters with surface dimensions of a few centimeters square, although both smaller and larger thermoelectric modules exist and can be used. A single thermoelectric module can be used, or two or more thermoelectric modules can be grouped together to control the temperature of a region of the sample block whose lateral dimensions exceed those of a single module. Adjacent thermoelectric modules can also be controlled to produce different rates or directions of heat flow, thereby placing different samples or groups of samples at different temperatures.
Further variations are also within the scope of the invention. The loop-shaped gaskets, for example, are shown as different sizes but the shapes of the components can be adjusted or varied to permit the use of gaskets of the same size. The construction shown in the Figures contains two clamping bars, but effective securement can also be achieved with a single clamping bar or with three or more clamping bars. As shown, the clamping bars are greater in length than the fins, and extend beyond the fins in both directions, leaving the ends of the bars accessible for securement to the retainer element. Alternatively, the bars can be equal to or less than the length of each fin, or secured to the retainer element at only one end rather than at both ends. A further alternative is the use of pairs of bars that extend to less than half the distance toward the fin centers, with one bar of each pair entering the fin area from one end of the fin array and the other from the other end. A still further alternative is the use of a pair of bars that are joined at both ends to form a loop to encircle a fin or two or more fins. The spacing between the clamping bars can also vary. In the embodiment shown, the bars are spaced such that only one fin passes between them. Alternatively, the spacing can be increased to allow two or more fins pass between the bars. The heat sink shown in the Figures contains fifteen fins, but this number can vary widely, from as few as three or four to as many as fifty or more. A preferred range is six to twenty. Furthermore, alternatives to the threaded bolts, such as clips or cams, can also be used and will be readily apparent to those skilled in the art.
The materials of construction will preferably be selected to allow each component to serve its function in an optimal manner. Components that are in contact with the samples, for example, will be fabricated from inert materials, such as polycarbonate or other plastics, and sample blocks and heat sinks that respond rapidly to changes in the heat transfer rate induced by the thermoelectric modules can be obtained by the use of thin materials or materials that conduct heat readily. Still further variations will be readily apparent to those skilled in the art of laboratory equipment design, construction, and use.
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|U.S. Classification||62/3.3, 62/371|
|International Classification||F25B21/02, F25D3/08|
|Cooperative Classification||B01L3/50851, B01L2300/0838, B01L2200/0689, B01L2300/0829, B01L2200/025, B01L2300/1894, F25B2321/023, B01L2300/1822, F25B21/04, B01L7/52|
|Mar 17, 2005||AS||Assignment|
Owner name: BIO-RAD LABORATORIES, INC., CALIFORNIA
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:COHEN, DAVID A.;BANERJI, SUNAND;DENNINGER, MICHAEL J.;REEL/FRAME:015920/0336;SIGNING DATES FROM 20050124 TO 20050214
|Nov 30, 2009||FPAY||Fee payment|
Year of fee payment: 4
|Dec 2, 2013||FPAY||Fee payment|
Year of fee payment: 8