Embodiments include a reaction vessel having a first reaction chamber filled with a first material; a first light absorbing region adhered to an interior-facing surface of the first reaction chamber; a second reaction chamber filled with a second material; a second light absorbing region adhered to an interior-facing surface of the second reaction chamber; a temperature sensor disposed within the second reaction chamber; and one or more energy sources configured to direct light at the first light absorbing region and the second light absorbing region. A processor may be employed to determine a first temperature of the first material from a second temperature of the second material measured by the temperature sensor. Methods of manufacturing such a reaction vessel are also disclosed.

A receptacle comprises opposed members, a plurality of chambers having perimeter walls defined by seals formed between the opposed members and portals interconnecting the chambers, and a rigid frame supporting the opposed members at their peripheral edges. The frame comprises a front frame portion and a rear frame portion, and the peripheral edges of the opposed members are retained between the front and rear frame portions. An inlet port extends between the front and rear frame portions and is in fluid communication with one of the chambers.

An insulated chamber having an interior region for storing items therein includes a phase change material to facilitate controlling the temperature of the interior region and the items. A heating device or cooling device may be used to melt or freeze the phase change material. The phase change material (PCM) may be in various locations such as the walls of the chamber in the form of packets or in the form of containers that serve as shelves and may be removable from the interior region. The packets may have recesses for receiving the items. The phase change material may be within capsules that may be within a liquid or a solid matrix. Controls may be provided to control humidity, oxygen, and carbon dioxide within the interior chamber.

An apparatus includes a substrate, a first heating element, and a second heating element. The substrate includes a first portion, a second portion, and a third portion that is between the first portion and the second portion. The first portion is characterized by a first thermal conductivity, the second portion is characterized by a second thermal conductivity, and the third portion is characterized by a third thermal conductivity. The third thermal conductivity is less than the first thermal conductivity and the second thermal conductivity. The first heating element is coupled to the first portion of the substrate, and is configured to produce a first thermal output. The second heating element is coupled to the second portion of the substrate, and configured to produce a second thermal output. The second thermal output is different from the first thermal output.

An apparatus comprising a magnetic assembly and methods for operating the apparatus are provided. The magnetic assembly may be used to manipulate molecules in a liquid preparation, for example to isolate or separate the molecules from the liquid. The magnetic assembly may be used to wash and/or isolate nucleic acid molecules of interest from a liquid preparation.

There is described a variable-temperature reactor for hosting a predetermined reaction therein. The reactor comprises a reaction cell, a heater, and a heat sink. The reaction cell has a reaction volume with thickness H.sub.v and width W.sub.v where W.sub.v>4H.sub.v and is defined by faces with one of the larger area faces of the reaction volume being bounded by an outer wall with thickness H.sub.w. The heater is in contact with the said outer wall. The heater comprises a heat-generating heater element located on the face closer to the reaction volume and a heater support on the opposite face. The heater support is in contact with a heat sink, such that the heater support provides a thermal resistance R.sub.T between the heater element and the heat sink. The reactor, when filled with reagents having thermal diffusion coefficient D.sub.v has a diffusion time t.sub.v, in the thickness direction, t.sub.v=H.sub.v.sup.2|D.sub.v. t.sub.v is less than the reaction time constant t.sub.R. The outer wall has a thermal diffusion coefficient D.sub.w and has a thermal diffusion time t.sub.w=H.sub.w.sup.2|D.sub.w<t.sub.v.

A micro-fluidic device is described. The micro-fluidic device includes a semiconductor substrate; at least one micro-reactor in the semiconductor substrate; one or more micro-fluidic channels in the semiconductor substrate, connected to the at least one micro-reactor; a cover layer bonded to the semiconductor substrate for sealing the one or more micro-fluidic channels; and at least one through-substrate trench surrounding the at least one micro-reactor and the one or more micro-fluidic channels.

A tissue sample that has been removed from a subject can be properly fixed for evaluation using the disclosed transporter assembly for carrying a tissue sample and method for fixing an unfixed tissue sample. In one embodiment, the disclosed assembly includes a transport container, a fixative in the transport container, and a cooling device that reduces and/or maintains the temperature of the fixative to perform a pre-soaking process at a temperature of less than about 7° C. The pre-soaking process can, for example, be performed during sample transport or during extended periods of storage, such as over a weekend.

An apparatus includes a substrate, a first heating element, and a second heating element. The substrate includes a first portion, a second portion, and a third portion that is between the first portion and the second portion. The first portion is characterized by a first thermal conductivity, the second portion is characterized by a second thermal conductivity, and the third portion is characterized by a third thermal conductivity. The third thermal conductivity is less than the first thermal conductivity and the second thermal conductivity. The first heating element is coupled to the first portion of the substrate, and is configured to produce a first thermal output. The second heating element is coupled to the second portion of the substrate, and configured to produce a second thermal output. The second thermal output is different from the first thermal output.

A disease screening device (100) comprising a substrate (101) and a sonication chamber (102) formed on the substrate (101). The sonication chamber (102) is provided with an ultrasonic transducer (105) which generates ultrasonic waves to lyse cells in a sample fluid within the sonication chamber (102). The device (100) comprises a reagent chamber (111) formed on the substrate (101) for receiving a liquid PCR reagent. The device (100) comprises a controller (23) which controls the ultrasonic transducer (105) and a heating arrangement (128) which is provided on the substrate (101). The device (100) further comprises a detection apparatus which detects the presence of an infectious disease, such as COVID-19 disease.