Methods of pre-heating a test vessel prior to transfer of the test vessel to an incubator may shorten an incubation cycle, ensure proper temperature of a test specimen in the test vessel, and/or improve testing accuracy and/or throughput in a bio-liquid specimen testing apparatus. The methods include providing a test vessel pre-heating apparatus having a receptacle sized to receive a test vessel therein and having at least one heating unit configured to heat by direct conduction at least one side of the test vessel. The methods also include heating at least one side of the test vessel via direct contact using the at least one heating unit. Specimen testing apparatus and test vessel pre-heating apparatus configured to carry out the method are described, as are other aspects.

Methods of pre-heating a test vessel prior to transfer of the test vessel to an incubator may shorten an incubation cycle, ensure proper temperature of a test specimen in the test vessel, and/or improve testing accuracy and/or throughput in a bio-liquid specimen testing apparatus. The methods include providing a test vessel pre-heating apparatus having a receptacle sized to receive a test vessel therein and having at least one heating unit configured to heat by direct conduction at least one side of the test vessel. The methods also include heating at least one side of the test vessel via direct contact using the at least one heating unit. Specimen testing apparatus and test vessel pre-heating apparatus configured to carry out the method are described, as are other aspects.

A tissue processing station includes a housing and a first heated plate that is either disposed on or forms a first horizontally oriented surface of the housing. The first heated plate is configured to either (i) contain water, or (ii) receive a dish containing water. The tissue processing station may also include a vertically-oriented heated well for heating slides. A second heated plate is either disposed on or forms an angled surface of the housing for supporting one or more laboratory slides. The angled surface is angled relative to the first horizontally oriented surface. A third heated plate is either disposed on or forms a second horizontally oriented surface of the housing for supporting one or more laboratory slides. The first and second horizontally oriented surfaces are defined at different elevations on the housing. The angled surface extends between the two horizontally oriented surfaces.

A tissue processing station includes a housing and a first heated plate that is either disposed on or forms a first horizontally oriented surface of the housing. The first heated plate is configured to either (i) contain water, or (ii) receive a dish containing water. The tissue processing station may also include a vertically-oriented heated well for heating slides. A second heated plate is either disposed on or forms an angled surface of the housing for supporting one or more laboratory slides. The angled surface is angled relative to the first horizontally oriented surface. A third heated plate is either disposed on or forms a second horizontally oriented surface of the housing for supporting one or more laboratory slides. The first and second horizontally oriented surfaces are defined at different elevations on the housing. The angled surface extends between the two horizontally oriented surfaces.

A system for precision temperature control of thermal bead baths used in biological laboratories to heat biological samples. An insulated outer shell and an inner shell sealed together to form a recirculation pathway. The inner shell has an air extraction port opening into the recirculation pathway and at least one air injection port opening into the recirculation pathway. A fan in the recirculation pathway draws air through the air extraction port. A thermal sensor is connected to a control and is disposed in close proximity to one of the air injection ports. Thermal beads are placed in a mesh basket inside the inner shell. The fan draws air from the inner shell through the beads and into the recirculation pathway, where the air is heated by a thermal element. The air flows past the thermal element and through the air injection ports back into the inner shell.

Thermal cycling apparatus for polymerase chain reaction (PCR) of nucleic acid is provided. Bath media in a first bath and a second bath are maintainable at two different temperatures. A transfer means allows the reactor to be in the two baths in a plurality of thermal cycles to alternately attain a predetermined high target temperature T.sub.HT and a predetermined low target temperature T.sub.LT. A florescent imaging means images the reaction material during the thermal cycling. A powder-cleaning device mechanically removes particles of powder that adhere to the reactor, when powder is the bath medium in use in at least one of the baths.

Thermal cycling apparatus for polymerase chain reaction (PCR) of nucleic acid is provided. Bath media in a first bath and a second bath are maintainable at two different temperatures. A transfer means allows the reactor to be in the two baths in a plurality of thermal cycles to alternately attain a predetermined high target temperature T.sub.HT and a predetermined low target temperature T.sub.LT. A florescent imaging means images the reaction material during the thermal cycling. A powder-cleaning device mechanically removes particles of powder that adhere to the reactor, when powder is the bath medium in use in at least one of the baths.

The embodiment of the present disclosure provides a temperature control device and a temperature control system. The temperature control device comprises an object stage, a housing, and at least one temperature control structure. The temperature control structure has a main body portion and a temperature control component, and main body portion defines an air duct, and wherein, the main body portion has a second air inlet and a second air outlet, and the first air inlet is connected to the second air outlet, and the external air enters the air duct defined by the main body portion from the second air inlet of the main body portion, and the air then enters the housing through the second air outlet, and the temperature control component is connected, so as to the main body portion to control the temperature of the air in the air duct.

The embodiment of the present disclosure provides a temperature control device and a temperature control system. The temperature control device comprises an object stage, a housing, and at least one temperature control structure. The temperature control structure has a main body portion and a temperature control component, and main body portion defines an air duct, and wherein, the main body portion has a second air inlet and a second air outlet, and the first air inlet is connected to the second air outlet, and the external air enters the air duct defined by the main body portion from the second air inlet of the main body portion, and the air then enters the housing through the second air outlet, and the temperature control component is connected, so as to the main body portion to control the temperature of the air in the air duct.

A laboratory sample/specimen temperature control device, specifically a metal bead bath that has its metal bead temperature controlled by a continuous flow of air into the bed of beads that is heated or cooled by a Peltier device that the air flows over. This provides great thermal uniformity across the bed of beads and constantly monitors and regulates the heat or cooling input rather than utilizing an on/off modulation temperature input approach.