Abstract: A vaginal ring applicator having a polymeric barrel and at least one friction reducing agent, wherein the barrel is a flattened cylinder having two slightly curved and opposing sides connected by two arcs, wherein the barrel extends between an insertion end and a plunger end; and a plunger extending between distal and proximal ends, wherein the distal end of the plunger engages the plunger end of the barrel and wherein the plunger fits telescopically within the barrel.

Abstract: Described herein is a vaginal ring applicator comprising a barrel comprising a polymer and at least one friction reducing agent, wherein the barrel is a flattened cylinder having two slightly curved and opposing sides connected by two arcs, wherein the barrel extends between an insertion end and a plunger end; and a plunger extending between distal and proximal ends, wherein the distal end of the plunger engages the plunger end of the barrel and wherein the plunger fits telescopically within the barrel.

Abstract: A wind turbine rotor blade defined by a tip point, a shoulder, a maximum chord interval which is defined as the radial interval over which the blade chord is no less that 95% of the shoulder chord and which extends over at least 15% of the entire blade length, and an outer blade interval extending from the maximum chord interval to the tip point, wherein the outer blade interval has a concave hyperbolic chord distribution from the maximum chord interval towards the tip point. Further a method for optimizing the chord distribution of a wind turbine blade layout is provided, wherein the chord distribution is optimized by optimizing the chord distribution in the maximum chord interval by maximizing the ratio of the annual energy production to the loads acting on the blade and in the outer blade interval with respect to the annual energy production alone.

Abstract: A wind turbine rotor blade with an airfoil profile having an upwind side, a downwind side is provided. A stall inducing device is located at the upwind side of the airfoil profile.

Abstract: The inventions relates to compositions and method for determining the absolute counts of cells per unit volume of a sample. Such a method comprises: (a) providing a container containing (i) a predetermined quantity of microparticles; and (ii) a cell-binding agent; in which the microparticles are disposed in or on a matrix which adheres to at least one wall of the container such that substantially all the microparticles are thereby attached to the container; (b) adding a known volume of sample to the container; (c) determining the ratio of microparticles to cells by counting microparticles and cells in a volume of the sample; and (d) determining the absolute count of cells by multiplying the number of cells per microparticle by the concentration of microparticles in the sample.

Abstract: A wind turbine rotor blade defined by a tip point, a shoulder, a maximum chord interval which is defined as the radial interval over which the blade chord is no less that 95% of the shoulder chord and which extends over at least 15% of the entire blade length, and an outer blade interval extending from the maximum chord interval to the tip point, wherein the outer blade interval has a concave hyperbolic chord distribution from the maximum chord interval towards the tip point. Further a method for optimizing the chord distribution of a wind turbine blade layout is provided, wherein the chord distribution is optimized by optimizing the chord distribution in the maximum chord interval by maximizing the ratio of the annual energy production to the loads acting on the blade and in the outer blade interval with respect to the annual energy production alone.

Abstract: A blade for a wind turbine is provided. The blade includes a blade surface and a pressure gauge device for providing a pressure value being used for stall detection. The pressure gauge device is located at the blade surface such that a pressure of a fluid flowing along the blade surface is measured by the pressure gauge device.

Abstract: A method for analyzing a pathological deviation of at least one white blood cell population from a normal level in an un-lysed blood sample, comprising the steps of counting, with a flow cytometer, a number, n1, of white blood cells expressing a first marker; a number, n2, of white blood cells expressing a second marker, and a number, n3, of white blood cells expressing a third marker but not the first marker; and comparing the sum (n1+n2+n3) with a reference value. The sum (n1+n2+n3) may represent the number of lymphocytes. The first, second and third markers may be chosen from the group consisting of CD56, CD3 and CD19.

Abstract: The present invention discloses novel methods and compositions for identifying particular cell types in whole blood samples and defining either the concentration or ‘absolute count’ of these cells per unit volume of the sample. More specifically, the invention relates to methods for quantifying the antigen-specific T cells or defining the relative percentage of said cells in un-lysed whole blood. Further, the invention relates to kits for the preparation of whole blood samples for high-speed quantification of particular cell types, e.g. antigen specific T-cells, in said whole blood samples by flow cytometry.

Abstract: A wind turbine rotor blade with an airfoil profile having an upwind side, a downwind side is provided. A stall inducing device is located at the upwind side of the airfoil profile.

Abstract: The inventions relates to compositions and method for determining the absolute counts of cells per unit volume of a sample. Such a method comprises: (a) providing a container containing: (i) a predetermined quantity of microparticles; and (ii) a cell-binding agent; in which the microparticles are disposed in or on a matrix which adheres to at least one wall of the container such that substantially all the microparticles are thereby attached to the container; (b) adding a known volume of sample to the container; (c) determining the ratio of microparticles to cells by counting microparticles and cells in a volume of the sample; and (d) determining the absolute count of cells by multiplying the number of cells per microparticle by the concentration of microparticles in the sample.