System for manipulating samples in liquid droplets

What is claimed is: 1. A system ( 40 ) for liquid droplet manipulation, the liquid droplet manipulation system ( 40 ) comprising: i) a substrate ( 42 ) with at least one electrode array ( 20 ) and ii) a central control unit ( 43 ) configured to control the selection of individual electrodes ( 44 ) of said at least one electrode array ( 20 ) and for providing the electrodes ( 44 ) with individual voltage pulses for manipulating liquid droplets ( 23 ) by electrowetting, wherein the liquid droplet manipulation system ( 40 ) is configured to receive on top of the electrodes ( 44 ) a working film ( 10 ) for manipulating samples in liquid droplets ( 23 ) with the electrode array(s) ( 20 ) when the working film ( 10 ) is placed on said at least one electrode array ( 20 ), wherein the liquid droplet manipulation system ( 40 ) further comprises: iii) at least one disposable cartridge ( 1 ) that is removably placed on said at least one electrode array ( 20 ) of the liquid droplet manipulation system ( 40 ), wherein the at least one disposable cartridge ( 1 ) comprises: a) a body ( 2 , 2 ′, 2 ″) that comprises an upper surface ( 3 ), a lower surface ( 4 ), and a number of wells ( 5 ) configured to hold therein reagents ( 6 ) or samples ( 6 ′); b) a flexibly deformable top structure ( 7 ) impermeable to liquids and configured to seal a top side of the wells ( 5 ); c) a piercable bottom structure ( 8 ) impermeable to liquids and configured to seal a bottom side of the wells ( 5 ); d) a working film ( 10 ) located below the lower surface ( 4 ) of the body ( 2 , 2 ′, 2 ″), the working film ( 10 ) being impermeable to liquids and comprising a hydrophobic upper surface ( 11 ); e) a peripheral spacer ( 9 , 9 ′, 9 ″) located below the lower surface ( 4 ) of the body ( 2 , 2 ′, 2 ″) and connecting the working film ( 10 ) to the body ( 2 , 2 ′, 21 ″); f) a gap ( 12 ) between the lower surface ( 4 ) of the body ( 2 , 2 ′, 2 ″) and the hydrophobic upper surface ( 11 ) of the working film ( 10 ), the gap ( 12 ) being defined by the peripheral spacer ( 9 , 9 ′, 9 ″); and g) a number of piercing elements ( 13 ) located below piercable bottom structures ( 8 ) and configured to pierce the piercable bottom structures ( 8 ) for releasing reagents or samples ( 6 , 6 ′) from the wells ( 5 ) into the gap ( 12 ), wherein at least one selected individual electrode ( 44 ) of said at least one electrode array ( 20 ) of the liquid droplet manipulation system ( 40 ) is configured to be penetrated by light of an optical detection system for the optical inspection or analysis of samples in liquid droplets ( 23 ) that are located on the working film ( 10 ) of the disposable cartridge, and wherein the at least one selected individual electrode ( 44 ) is configured as an optical via electrode ( 61 ) that comprises a through hole ( 62 ). 2. The liquid droplet manipulation system ( 40 ) of claim 1 , wherein the working film ( 10 ) of the cartridge ( 1 ) is configured as a monolayer of electrically non-conductive material, the upper surface ( 11 ) of the working film ( 10 ) being treated to be hydrophobic. 3. The liquid droplet manipulation system ( 40 ) of claim 1 , wherein the optical via electrode ( 61 ) is located in place of an individual electrode ( 44 ) in an electrode path ( 65 ) or within a grid-like electrode array ( 66 ) and is configured to be addressed by an electrode selection unit ( 64 ) of the central control unit ( 43 ). 4. The liquid droplet manipulation system ( 40 ) of claim 1 , wherein the substrate ( 42 ) comprises at least one optical fiber ( 21 ) for bringing light to a through hole ( 62 ) of an optical via electrode ( 61 ) and thus to a droplet ( 23 ) on the working film ( 10 ) that is placed on said electrode array ( 20 ). 5. The liquid droplet manipulation system ( 40 ) of claim 4 , wherein the at least one optical fiber ( 21 ) belongs to an optical bottom reading system and a detector connected to the latter, the optical bottom reading system being configured to send excitation light to the sample and to receive and detect fluorescence emitted by a sample in a liquid droplet ( 23 ) that is located on the working film ( 10 ). 6. The liquid droplet manipulation system ( 40 ) of claim 4 , wherein the optical fiber ( 21 ) is integrated into the substrate ( 42 ) of the electrode array ( 20 ) of the system ( 40 ) for the manipulation of droplets. 7. The liquid droplet manipulation system ( 40 ) of claim 1 , wherein the substrate ( 42 ) comprises electrical lines that link the individual electrodes ( 44 ) with an electrode selection unit ( 64 ) of the central control unit ( 43 ) of the liquid droplet manipulation system ( 40 ). 8. The liquid droplet manipulation system ( 40 ) of claim 7 , wherein the optical fiber ( 21 ) is integrated into the substrate ( 42 ) of the electrode array ( 20 ) of the system ( 40 ) for the manipulation of droplets. 9. The liquid droplet manipulation system ( 40 ) of claim 1 , wherein the working film ( 10 ) is optically transparent and configured as a monolayer of a hydrophobic material. 10. The liquid droplet manipulation system ( 40 ) of claim 1 , wherein the working film ( 10 ) is optically transparent and configured as a laminate of a hydrophobic upper layer and a dielectric lower layer. 11. A system ( 40 ) for liquid droplet manipulation, the liquid droplet manipulation system ( 40 ) comprising: a) a substrate ( 42 ) with at least one electrode array ( 20 ) and b) a central control unit ( 43 ) configured to control the selection of individual electrodes ( 44 ) of said at least one electrode array ( 20 ) and for providing the electrodes ( 44 ) with individual voltage pulses for manipulating liquid droplets ( 23 ) by electrowetting, wherein the liquid droplet manipulation system ( 40 ) is configured to receive on top of the electrodes ( 44 ) a working film ( 10 ) for manipulating samples in liquid droplets ( 23 ) with the electrode array(s) ( 20 ) when the working film ( 10 ) is placed on said at least one electrode array ( 20 ), wherein the liquid droplet manipulation system ( 40 ) further comprises: c) a working film ( 10 ) for manipulating samples in liquid droplets ( 23 ) with said at least one electrode array ( 20 ), the working film ( 10 ) being placed on said at least one electrode array ( 20 ) and being comprised by a disposable cartridge ( 1 ) that is removably placed on said at least one electrode array ( 20 ) of the liquid droplet manipulation system ( 40 ), wherein at least one selected individual electrode ( 44 ) of said at least one electrode array ( 20 ) of the liquid droplet manipulation system ( 40 ) is configured to be penetrated by light of an optical detection system for the optical inspection or analysis of samples in liquid droplets ( 23 ) that are located on the working film ( 10 ) of the disposable cartridge, wherein the at least one selected individual electrode ( 44 ) is configured as an optical via electrode ( 61 ) that comprises a through hole ( 62 ) wherein said optical via electrode ( 61 ) has a first area and the through hole ( 62 ) of said optical via electrode ( 61 ) has a second area, and wherein an area ratio (optical via electrode ( 61 ):through hole ( 62 )) is from 1.8 to 2.8. 12. The liquid droplet manipulation system ( 40 ) of claim 11 , wherein the area ratio (optical via electrode ( 61 ):through hole ( 62 )) is 2.4. 13. The liquid droplet manipulation system ( 40 ) of claim 11 , wherein the optical via electrode ( 61 ) is divided into two partial electrodes, each of which comprising a part of the through hole ( 62 ). 14. The liquid droplet m