The present teachings relate to thermal cycling of biological samples. Improvement in thermal cycling can be provided by a thermal diffusivity plate.
In the biological field, thermal cycling can be utilized to provide heating and cooling of reactants in a reaction vessel. Examples of reactions of biological samples include polymerase chain reaction (PCR) and other reactions such as ligase chain reaction, antibody binding reaction, oligonucleotide ligations assay, and hybridization assay. In PCR, biological samples can be thermally cycled through a temperature-time protocol that includes melting DNA into single strands, annealing primers to the single strands, and extending those primers to make new copies of double-stranded DNA. During thermal cycling, it is desirable to maintain thermal uniformity throughout a thermal block assembly so that different sample wells can be heated and cooled uniformly to obtain uniform sample yields. Uniform yields can provide quantification between samples wells.
According to various embodiments, an apparatus for thermally cycling biological samples can comprise a thermal block assembly for receiving the biological sample; a thermoelectric module coupled to the thermal block assembly; and a heat sink, wherein the heat sink is coupled to the thermoelectric module, wherein the heat sink comprises a base plate, fins, and a thermal diffusivity plate, and wherein the thermal diffusivity plate comprises a different material than the base plate and fins, wherein the thermal diffusivity plate provides substantial temperature uniformity to the thermal block assembly during thermal cycling.
According to various embodiments, an apparatus for thermally cycling biological samples can comprise a thermal block assembly for receiving the biological sample; a thermoelectric module coupled to the thermal block assembly; a heat sink; and a thermal diffusivity plate coupled to the thermoelectric module and the heat sink, wherein the thermal diffusivity plate is positioned between the thermoelectric module and the heat sink, wherein the thermal diffusivity plate has a significantly greater thermal diffusivity than the heat sink.
According to various embodiments, a method for thermally cycling biological samples can comprise contacting a thermoelectric module to a thermal block assembly; heating the thermal block assembly, wherein the thermal block assembly is adapted for receiving the biological sample; and cooling the thermal block assembly, wherein the cooling comprises diffusing heat to a heat sink through a thermal diffusivity plate.
It is to be understood that both the foregoing general description and the following description of various embodiments are exemplary and explanatory only and are not restrictive.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate various embodiments. In the drawings,
a illustrates various embodiments of an edge heater;
a is a cross-sectional view of
Reference will now be made to various embodiments, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description to refer to the same or like parts.
According to various embodiments, the apparatus for thermally cycling biological samples provides heat-pumping into and out of a thermal block assembly, resistive heating of the thermal block assembly, and diffusive cooling of the thermal block assembly. The term “thermal cycling” or grammatical variations of such as used herein refer to heating, cooling, temperature ramping up, and/or temperature ramping down. Thermal cycling during temperature ramping up, when heating the thermal block assembly above ambient (20° C.), can comprise resistive heating of the thermal block assembly and/or pumping heat into the thermal block assembly by the thermoelectric module against diffusion of heat away from the thermal block assembly. Thermal cycling during temperature ramping down, when cooling the thermal block assembly above ambient (20° C.), can comprise pumping heat out of the thermal block assembly by the thermoelectric module and diffusion of heat away from the thermal block assembly against resistive heating.
According to various embodiments,
Names of metals as used herein such as copper, aluminum, etc. refer to the pure metal, alloys of the metal, amalgams of the metal, or any variation of the metal known in the art of material science.
According to various embodiments, the thermal diffusivity plate can be constructed of different material than the rest of the heat sink such that the thermal diffusivity plate can have significantly greater thermal diffusivity than the rest of the heat sink. According to various embodiments, the base plate and fins can be constructed of different materials. According to various embodiments, the thermal diffusivity plate can comprise other composite materials that provide thermal diffusivity as known in the art of material science. According to various embodiments, as illustrated in
It can be desirable to reduce the cost and weight of the heat sink while providing significantly greater thermal diffusivity with the thermal diffusivity plate. According to various embodiments, the thermal diffusivity plate can be constructed of copper and the base plate and fins can be constructed of aluminum because copper can weigh more and can be more expensive than aluminum. According to various embodiments, the thermal diffusivity plate, base plate, and fins can be constructed of the same material providing similar thermal diffusivity throughout the heat sink.
“Thermal diffusivity” or “diffusion” of heat or grammatical variations of such as used herein refer to the transport property for transient conduction. Thermal diffusivity can measure the ability of a material to conduct thermal energy relative to its ability to store thermal energy. Materials with greater thermal diffusivity can respond more rapidly to changes in their thermal environment. Thermal diffusivity can be calculated using the formula (1):
where a is thermal diffusivity which can be measured in square meters per second, k is thermal conductivity which can be measured in watts per meters-Kelvin, Cp is specific heat capacity which can be measured in joules per kilograms-Kelvin, and ρ is density which can be measured in kilograms per cubic meter. As known in the art of material science, there are alternative ways of measuring these thermal properties.
According to various embodiments, the thermal diffusivity plate can comprise copper, silver, gold, or silicone carbide. “Thermal capacitance” as used herein refers to the ability of a material to store thermal energy. It can be desirable to provide a thermal block assembly that can have a significantly lower thermal capacitance so that heat diffuses to the thermal diffusivity plate. Thermal capacitance can be calculated using the formula (2):
C
T
=ρ×C
p (2)
where CT is thermal capacitance which can be measured in joules per cubic meter-Kelvin, Cp is specific heat capacity which can be measured in joules per kilograms-Kelvin, and ρ is density which can be measured in kilograms per cubic meter. “Significantly” greater or lower as used herein refers to a thermal diffusivity or thermal capacitance values of at least twenty-five percent greater or lower than the values to which they are compared. Table 1 contains values for each of the aforementioned thermal properties according to various embodiments:
According to various embodiments, a thermal diffusivity plate constructed of copper, silver, gold, or silicone carbide (for example silicone carbide plated by chemical vapor deposition) can have significantly greater thermal diffusivity than a base plate and fins constructed of aluminum or magnesium. According to various embodiments, a thermal diffusivity plate constructed of copper can have a significantly greater thermal capacitance than a thermal block assembly constructed of silver, gold, or magnesium.
According to various embodiments,
According to various embodiments, the thermal block assembly can comprise at least one of silver, gold, aluminum alloy, silicone carbide, and magnesium. Other materials known in the art of thermal cycling can be used to construct the thermal block assembly. These materials can provide high thermal conductivity.
According to various embodiments,
“Thermoelectric module” as used herein refers to Peltier devices, also known as thermoelectric coolers (TEC), that are solid-state devices that function as heat pumps. The Peltier device can comprise two ceramic plates with a bismuth telluride composition in between. When a DC current can be applied heat is moved from one side of the device to the other, where it can be removed with a heat sink and/or a thermal diffusivity plate. The “cold” side can be used to pump heat out of the thermal block assembly. If the current is reversed the device can be used to pump heat into the thermal block assembly. The Peltier devices can be stacked to achieve increase the cooling and heating effects of heat pumping. Peltier devices are known in the art and manufactured by several companies, including Tellurex Corporation (Traverse City, Mich.), Marlow Industries (Dallas, Tex.), Melcor (Trenton, N.J.), and Ferrotec America Corporation (Nashua, N.H.).
According to various embodiments,
According to various embodiments,
According to various embodiments, the apparatus for thermal cycling can provide the top 26 of thermal block assembly 20 access to the environment. It can be desirable to protect thermoelectric module 30 from moisture in the environment. Seal 44 can provide a connection between the top 26 of the thermal block assembly 20 and a cover (not shown) that provides a skirt down to gasket 36. The cover (not shown) can isolate the components on top of which it is positioned from the environment. Seal 44 and/or gasket 36 can provide sealing with or without the application of moldable adhesive/sealant, including RTV silicone rubber (Dow Corning).
According to various embodiments, as illustrated in
According to various embodiments, as illustrated in
According to various embodiments,
According to various embodiments, the thermoelectric module can be configured to provide a variety of heat gradients to minimize TNU. Multiple thermoelectric modules can provide a variety of heat gradients to minimize TNU. According to various embodiments, the thermoelectric module 30 can be configured to provide a constant pumping of heat into thermal block assembly 20 by increasing corner heat flux to minimize TNU as described below. According to various embodiments, as illustrated in
According to various embodiments, TNU can be measured by sampling the temperature at different points on the thermal block assembly. TNU is the non-uniformity of temperature from place to place within the thermal block assembly. According to various embodiments, TNU can be measured by sampling the temperature of the sample in the sample well tray at different openings in the thermal block assembly. Actual measurement of the temperature of the sample in each well in the sample well tray can be difficult because of the small volume in each well and the large number of wells. Temperature can be measured by any method known in the art of temperature control, including a temperature sensor or thermistor.
According to various embodiments, the components of the thermal cycling apparatus can be coupled together with thermal interface media, including thermal grease. According to various embodiments, thermal grease can be positioned at the interface of at least two of the thermal block assembly, the thermoelectric module, thermal diffusivity plate, and the base plate. Thermal grease can avoid the requirement of high pressure to ensure sufficient thermal contact between components. Thermal grease can provide lubrication between expanding and contracting components that are coupled together to decrease wear on the components. Examples of thermal grease include Thermalcote™ II (Aavid Thermalloy, LLC; k=0.699 W/m−K).
According to various embodiments, methods for thermally cycling biological sample can comprise contacting a thermoelectric module to a thermal block assembly; heating the thermal block assembly, wherein the thermal block assembly is adapted for receiving the biological sample; and cooling the thermal block assembly, wherein the cooling comprises diffusing heat to a heat sink with a thermal diffusivity plate. According to various embodiments, thermally cycling the biological sample can comprise contacting said thermal block assembly with an edge heater, wherein the edge heater is coupled to the perimeter of said thermal block assembly. According to various embodiments, thermally cycling the biological sample can provide substantial temperature uniformity to the thermal block assembly. According to various embodiments, diffusing can provide cooling of at least 10° C. in at most ten seconds for said biological sample. According to various embodiments, thermally cycling the biological sample can provide heating and cooling to achieve a PCR cycle time of less than thirty seconds. For example, PCR protocols requiring 30 cycles can be completed in less than fifteen minutes. Various PCR protocols are known in the art of thermal cycling and can include maintaining 4° C. per second temperature ramping up or ramping down.
According to various embodiments, the thermal block assembly is heated by ramping up the set point on the temperature controller for the thermal block assembly and is cooled by ramping down the set point on the temperature controller. Following are several examples whose temperature curves are illustrated in
In Example 1, a thermal diffusivity plate constructed of 99.9% EDM copper having a thickness of 8.0 millimeters was coupled to a base plate and pin fins constructed of 6063-T5 aluminum having a thickness of 5.0 millimeters. A thermal block assembly constructed of silver plated with gold was coupled to a thermoelectric device constructed of bismuth telluride. The thermoelectric device was coupled to the thermal diffusivity plate. An edge heater having a power output of 9.3 Watts manufactured by Minco Products, Inc. (Minneapolis, Minn.) was coupled to the thermal block assembly. A seal constructed of silicone rubber was positioned on the top of thermal block assembly. This thermal cycling apparatus was compared to a thermal cycling apparatus similar to the one described above except that the thermal diffusivity plate was replaced with a base plate having a thickness of 13.0 millimeters.
In Example 2, a thermal cycling apparatus with a thermal diffusivity plate similar to the one described in Example 1 was modified to replace the pin fin heat sink with a swage fin heat sink. The thermal cycling apparatus with a thermal diffusivity plate and swage fins was compared to a similar thermal cycling apparatus except that the thermal diffusivity plate was replaced with a base plate having a thickness of 13.0 millimeters.
In Examples 1 and 2, as illustrated by
In Example 3, a thermal diffusivity plate constructed of 99.9% EDM copper having a thickness of 8.0 millimeters was coupled to a base plate and fins constructed of 6063-T5 aluminum having a thickness of 5.0 millimeters. A thermal block assembly constructed of silver plated with gold was coupled to a thermoelectric device constructed of bismuth telluride. The thermoelectric device was coupled to the thermal diffusivity plate. An edge heater having a power output of 9.3 Watts manufactured by Minco Products, Inc. (Minneapolis, Minn.) was coupled to the thermal block assembly. A seal constructed of silicone rubber was positioned on the top of thermal block assembly. This thermal cycling apparatus was compared to a thermal cycling apparatus similar to the one described above except that more than one edge heaters was coupled to the thermal block assembly.
Example 3 illustrates that an increased edge heating reduces TNU in heating cycles whether a pin fin or swage fin heat sink diffuses heat away from the thermal diffusivity plate. In the swage fin configuration, additional heat provided by the edge heater during heating increased the TNU during cooling.
In Example 4, a thermal diffusivity plate constructed of 99.9% EDM copper having a thickness of 8.0 millimeters was coupled to a base plate and pin fins constructed of 6063-T5 aluminum having a thickness of 5.0 millimeters. A thermal block assembly constructed of silver plated with gold was coupled to a thermoelectric device constructed of bismuth telluride. The thermoelectric device was coupled to the thermal diffusivity plate. A seal constructed of silicone rubber was positioned on the top of thermal block assembly. The thermal cycling apparatus described above was compared to a thermal cycling apparatus similar to the one described above except that the seal was removed.
Example 4 illustrates that a silicon rubber seal can provide a barrier to condensation without significantly affecting the TNU change in a thermal cycling apparatus with a thermal diffusivity plate and pin fin heat sink.
For the purposes of this specification and appended claims, unless otherwise indicated, all numbers expressing quantities, percentages or proportions, and other numerical values used in the specification and claims, are to be understood as being modified in all instances by the term “about.” Accordingly, unless indicated to the contrary, the numerical parameters set forth in the following specification and attached claims are approximations that may vary depending upon the desired properties sought to be obtained by the present invention. At the very least, and not as an attempt to limit the application of the doctrine of equivalents to the scope of the claims, each numerical parameter should at least be construed in light of the number of reported significant digits and by applying ordinary rounding techniques.
Notwithstanding that the numerical ranges and parameters setting forth the broad scope of the invention are approximations, the numerical values set forth in the specific examples are reported as precisely as possible. Any numerical value, however, inherently contains certain errors necessarily resulting from the standard deviation found in their respective testing measurements. Moreover, all ranges disclosed herein are to be understood to encompass any and all subranges subsumed therein. For example, a range of “less than 10” includes any and all subranges between (and including) the minimum value of zero and the maximum value of 10, that is, any and all subranges having a minimum value of equal to or greater than zero and a maximum value of equal to or less than 10, e.g., 1 to 5.
It is noted that, as used in this specification and the appended claims, the singular forms “a,” “an,” and “the,” include plural referents unless expressly and unequivocally limited to one referent. Thus, for example, reference to “a thermoelectric module” includes two or more thermoelectric modules.
It will be apparent to those skilled in the art that various modifications and variations can be made to various embodiments described herein without departing from the spirit or scope of the present teachings. Thus, it is intended that the various embodiments described herein cover other modifications and variations within the scope of the appended claims and their equivalents.
This application is a continuation of application Ser. No. 12/421,568 filed Apr. 9, 2009, which is a continuation of application Ser. No. 10/448,804 filed May 30, 2003, which applications are incorporated herein by reference in their entirety.
Number | Date | Country | |
---|---|---|---|
Parent | 12421568 | Apr 2009 | US |
Child | 13029085 | US | |
Parent | 10448804 | May 2003 | US |
Child | 12421568 | US |