Sample support
Abstract
The sample support comprises at least one sample receiving chamber for a sample liquid, and a distributor channel for sample liquid connected to said at least one sample receiving chamber, with at least one such distributor channel extending from each sample receiving chamber. The sample support further comprises at least one reaction chamber entered by an inflow channel branched off said at least one distributor channel, and a venting opening for each reaction chamber. Each distributor channel and each inflow channel are dimensioned to have the liquid transport through the distributor and inflow channels effected by capillary forces. In each reaction chamber, the entrance region of the inflow channel is provided with a means for generating a capillary force causing the sample liquid to flow from the inflow channel into the reaction chamber.
Claims
exact text as granted — not AI-modified1 . A sample support comprising
at least one sample receiving chamber for a sample liquid, a distributor channel for sample liquid, connected to said at least one sample receiving chamber, with at least one such distributor channel extending from said at least one sample receiving chamber, a plurality of reaction chambers each comprising a cavity which is delimited by surfaces and is entered by an inflow channel branched off said at least one distributor channel, and a venting opening for each reaction chamber, wherein each venting opening of each reaction chamber has a connecting channel extending therefrom and wherein a plurality of such connecting channels are arranged to enter respectively one venting collecting channel comprising a venting collecting opening, wherein each distributor channel and each inflow channel is dimensioned to have the liquid transport through the distributor and inflow channels effected by capillary forces, and wherein, in each reaction chamber, said surfaces in the entrance region of the inflow channel which are provided for delimiting said cavity are configured as a means for generating a capillary force causing the sample liquid to flow from the inflow channel into the reaction chamber exclusively by capillary force.
2 . The sample support according to claim 1 , wherein each connecting channel and/or each venting opening includes a means for preventing a further flow of sample liquid effected by capillary forces.
3 . The sample support according to claim 2 , wherein said capillary-force prevention means are arranged in the entrance regions of the connecting channels into the venting collecting channels.
4 . The sample support according to claim 2 , wherein each of said capillary-force prevention means is provided as a widened portion of a connecting channel or venting opening, which widened portion respectively comprises a side surface with a connecting channel entering thereinto, and that the entrance region of the portion of the connecting channel extending from the reaction chamber is not delimited in the widened portion by any corner regions or only by such a small number of corner regions with rounding radii generating a capillary force that the flow of the sample liquid in the entrance region is prevented.
5 . The sample support according to claim 4 , wherein each venting collecting channel is arranged to extend from a reagent receiving chamber for receiving a reagent liquid, with the flow of the reagent liquid performed via the venting collecting channels by capillary forces generated within the venting collecting channels, and that, within the entrance region of each venting collecting channel into the widened portions and/or within the entrance regions where the portions of the connecting channels extending from the venting collecting channels enter the widened portions, a means is arranged for generating a capillary force for filling the widened portions.
6 . The sample support according to claim 5 , wherein each reagent receiving chamber comprises a bottom surface and side surfaces extending at an angular orientation thereto, and that the venting collecting channel assigned to a reagent receiving chamber is arranged to enter the reagent receiving chamber above said bottom surface, and that a means for generating a capillary force to cause reagent liquid to flow from the reagent receiving chamber into the venting collecting channel is arranged between said entrance and said bottom surface.
7 . The sample support according to claim 6 , wherein said capillary-force generating means is formed as an outflow groove having a cross-sectional area and shape suited to generate a flow of the reagent liquid by capillary force.
8 . The sample support according to claim 7 , wherein said outflow groove is provided as a trough formed in a side surface.
9 . The sample support according to claim 7 , wherein said outflow groove is provided as a transition region between two adjacent and mutually angled side surfaces, the transition region having a rounding radius sufficiently small to generate capillary forces causing a flow of the reagent liquid.
10 . The sample support according to claim 4 , wherein each venting collecting channel is arranged to extend from a reagent receiving chamber for receiving a reagent liquid, and that, within the entrance region of each venting collecting channel into the widened portions and/or within the entrance regions where the portions of the connecting channels extending from the venting collecting channels enter the widened portions, a means is arranged for generating a capillary force for filling the widened portions.Cited by (0)
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