PT876218E - HEATING A SAMPLE DOOR - Google Patents

Abstract

A method and apparatus for heating specimens in wells of a metallic specimen carrier. The specimen carrier is heated by applying resistive heating directly to the carrier. An AC source and transformer may be used where the specimen carrier is in series with a single turn secondary winding of the transformer.

Description

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DESCRIPTION " HEATING A SAMPLE PORT "" The present invention relates to sample rack heating and more specifically to its thermal cycling.

In many fields of application are used sample holders configured as support blocks or plates for the realization of various processes in which the samples are heat sealed.

A particular example is the polymerase chain reaction (often referred to as PCR) to effect the replication of DNA samples. These samples require a rigorous and rapid thermal cycling and are typically placed in a block with a large number of wells and inserted between several pre-selected temperatures in a pre-established repetitive cycle. Earlier methods for heating these sample carriers involved the use of electric resistance wires wound around the wells, the use of peltier-effect devices or methods involving the application of hot air. However, these methods are difficult to control with the required accuracy, require slow cycle times and can give rise to errors in excess in the thermal scope. The present invention solves this problem by directly heating a metal sample holder using the electrical resistivity thereof. Thus, the present invention 1

V L L K provides a method for heating a sample holder configured as a metal foil by applying a heating stream to said foil.

Preferably, the metal foil is of silver which has high thermal and electrical conductivities. The sheet has, as a rule, a low thickness of the order of 0.3 mm and may be shaped so as to define a well array for sample placement.

While the metal foil may be a solid sheet or a silver block (which may have wells), an alternative is to use a metal foil tray (which may have wells in it) in which the metal deposited by metallization constitutes the heating element by electrical resistivity.

Another alternative is to form by electroforming a low thickness metal tray (which may also have wells printed) and coat the metal with a bio-compatible polymer.

These measures allow an intimate, indispensable contact between the metal heating element and the sample receptacles made of bio-compatible material. This contact provides substantially improved thermal performance in terms of temperature control and rate of temperature change when measuring the temperatures of the reactants contained in the wells.

Plastic trays are conventionally disposable articles intended for single use. The incorporation of the heating element in the plastic trays can increase its cost but the reduction of the 2Γ cycling times for the PCR reaction more than makes up for any cost increase of the disposable articles. The bottom of the composite material tray should not introduce any obstruction when using fan cooling. If cooling to temperatures below room temperature at the end of the PCR cycles is desired, either with a tray made of composite material or with a block, spray cooling of a cooled liquid at low temperature can be used. The boiling point of the liquid should be less than the lower point of the PCR cycle so that the liquid does not remain on the metal of the tray or the block, preventing heating. This also allows the latent heat of evaporation of the liquid to increase the cooling effect. The heating current may be an alternating current supplied by the secondary winding of a transformer. This allows the control of the cycling to be made in the primary circuit of the transformer (higher voltage, lower intensity) in a convenient way, without facing the problems that arise when working with devices where the current intensity is high. The transformer may comprise a toric core with a suitable primary winding connected to the network and a secondary one simply constituted by a busbar which circles through the core and is connected in series with the metal sheet to form a secondary circuit with a single loop. An embodiment of the present invention will now be described, as an example described in correlation with the drawings, in which: Fig. 1 is a side elevation of a heating apparatus and Fig. 2 is a plan view of the apparatus shown in Fig. 1.

A metal sample holder configured as a multi-cavity block (1), having dimensions of 110 mm x 75 mm and with 96 wells (2) arranged in a grid, is made of silver with a nominal thickness of 0.3 mm . This block is connected to busbars (3) of cross-section with a substantially large area. The busbars constitute a single turn passing through the core (4) (torus or square) of a transformer. The core 4 has a primary winding 5 suitable for the mains voltage used. The primary current of the transformer is controlled using a triac (6). The triac receives current from the alternating current source and is controlled by a temperature control circuit (7) using a thin wire thermocouple (8) welded in the central region of the lower part of the block in order to detect the temperature of the block . The temperature control circuit can be operated manually or by a personal computer (9). Cooling of the block is done by blowing ambient air against the projecting shapes of the wells 2, with the aid of a fan 10 mounted under the block, the blown air being directed by the housing where the block is mounted. The fan is controlled by the same temperature control circuit which controls the heating triac. The measured performance of the exemplified apparatus gave rates of temperature change of more than 6 degrees per second and errors of excess / defect of less than 0.25 degrees within the typical working range of the PCR of 50-100 degrees. 4

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In the example described, a silver block with cavities was used but metallized plastic trays or low thickness trays made by electroforming could also be used, as previously mentioned. The system, as described, has several important advantages. 1.1 The block is directly heated, and heat transfer from a connected heat source is not required. This is highly efficient and when taken in conjunction with the extremely low specific heat of the silver allows very rapid temperature variations to be obtained. 1.2 Direct heating means that there is no thermal inertia. The temperature control functions are immediate so that the block can be temperature cycled with little or no over or under error. Temperature control is therefore inherently accurate. 1.3 Since there are no obstructions or thermal barriers associated with the block, a simple forced air cooling of the rear part of the block (which may have conformations intended to increase its exposed surface) provides a fast and controllable cooling. 1.4 The fine wire thermocouple is welded directly to the block to provide rigorous temperature control and measurement. Any other temperature measuring device may be used as long as it does not introduce a significant delay of the sensor actuation. 5 1.5 The temperature distribution around the block surface depends on the regularity of the heating and the thermal conductivity of the block. The thermal conductivity of the silver is very high and the distribution of the heat energy around the block depends on the distribution of the heating current. This can be regulated by varying the geometry of the block provided with multiple wells.

The required raised chains can easily be

produced and controlled when the block is part of a secondary circuit of the transformer, which has a high mass. The cross-section of the busbars has a considerably larger area than that of the block so that significant heat generation occurs only in the block. The current can be easily controlled in the primary winding (where current is reduced) using thyristors, triacs, or other devices. Alternatively, the primary winding may be actuated by a controllable, high frequency, modulated switching power source. This allows for the same degree of control of the induced current in the secondary winding in which the block is incorporated, but the high frequency allows use of a more compact core in the transformer and reduces the " self " when the power is turned on and off.

Lisbon, November 30, 2000

THE OFFICIAL AGENT OF INDUSTRIAL PROPERTY

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Claims (13)

V Γ u A method of heating a sample holder of the type comprising various sample placement points, such as wells, each sample holder having the shape of a metal foil and the method comprising the steps of applying current to said mode sheet to provide a resistivity heating of said sheet in order to heat the samples placed in said sample holder. A method according to claim 1 wherein the heating is applied by means of an alternating current which gives rise to a resistivity heating and that the method is controlled so as to provide repetitive heating cycles. A method according to any preceding claim wherein the metal foil is a solid block of silver. A method according to any preceding claim wherein the sheet is a metallized plastic tray. A method according to any preceding claim wherein said sheet is a thin metal tray, produced by electroforming. A method according to any preceding claim wherein said metal foil includes several wells for the placement of the various samples. 1, An apparatus for carrying out the method of any of the preceding claims comprising a sample holder of the type including a plurality of sampling points, such as wells, the sample holder being constituted by an electrically conductive metal foil, power supply and a transformer with the primary winding connected to said power source and the secondary winding directly connected to said conductive sheet. The apparatus of claim 7 wherein said secondary winding is a winding with a single winding. Apparatus as claimed in any one of claims 7 or 8 comprising temperature control means connected in order to regulate the flow of heating current passing in the secondary winding to values which maintain a controlled heating temperature in said sample holder . An apparatus according to claim 9 comprising fan cooling means arranged to direct a cooling air flow to the back side of the sample holder and operatively connected to said temperature control means. The apparatus of any one of claims 7 to 10 wherein the metal sheet is a solid, silver block. The apparatus of any one of claims 7 to 10 wherein said metal sheet is comprised of a metallized plastic tray. 2 The apparatus of any one of claims 7 to 10 wherein said metal sheet is comprised of a small thickness metal tray manufactured by electroforming. Lisbon, November 30, 2000 0 OFFICIAL AGENT OF INDUSTRIAL PROPERTY 3