Abstract: A bio-processing system (100) for wirelessly powering one or more sensors (116-128, 400) is presented. The system (100) includes bio-processing units (106-110), process supporting devices (112-114), energy sources (146-148), and sensors (116-128, 400) including an energy harvesting unit (402) and an energy storage unit (404). The system (100) includes a power management subsystem (104, 200) wirelessly coupled to the sensors (116-128, 400) and including a processor (202) configured to wirelessly monitor energy consumption of the sensors (116-128, 400) and a level of energy stored in corresponding energy storage units (404), select at least one sensor (116-128, 400) based on the energy consumption of the sensors (116-128, 400) and corresponding levels of energy stored in the energy storage units (404), and identify at least one active energy source (146-148) as a power source, where the identified power source is configured to wirelessly transfer power to the selected sensor (116-128, 400).

Abstract: The present disclosure relates to a system and method (10) for monitoring a set-up for manufacture and/or setting up for manufacture and/or tearing down after manufacture of a biopharmaceutical product. The method comprises: processing (S2, S3, S4) at least one image of a scene comprising the set-up for manufacture of the biopharmaceutical product. The processing of the at least one image comprises performing (S2) a first process on the at least one image for classifying first objects in the image, said first objects being devices such as clamps, pumps, valves and/or sensors and/or any other bio processing equipment. The first process comprising identifying, localizing and classifying the first objects in the image. A second process is performed (S3) on the at least one image for identifying and localizing connections in the images.

Abstract: Disclosed is an automated method (54) which includes directing rays from a source (34) to a tube (38) disposed between relatively movable first and second sealing plates (20, 32), capturing an image (70) of at least a portion of the tube (38) by an image capturing device (26), and transferring the captured image (70) to a processing device (24). The method (54) also includes determining a plurality of tube parameters by the processing device (24) based on the captured image (70), using an image processing technique and determining a plurality of sealing parameters from a database (44) by the processing device (24) based on the determined plurality of tube parameters. Additionally, the method (54) includes controlling the drive unit (22) and a heater (36) by the processing device (24) influenced by the determined plurality of sealing parameters, to respectively compress the tube (36) and perform heat sealing of the tube (38).

Abstract: Disclosed is an automated method (54) which includes directing rays from a source (34) to a tube (38) disposed between relatively movable first and second sealing plates (20, 32), capturing an image (70) of at least a portion of the tube (38) by an image capturing device (26), and transferring the captured image (70) to a processing device (24). The method (54) also includes determining a plurality of 26 tube parameters by the processing device (24) based on the captured image (70), using an image processing technique and determining a plurality of sealing parameters from a database (44) by the processing device (24) based on the determined plurality of tube parameters. Additionally, the method (54) includes controlling the drive unit (22) and a heater (36) by the processing device (24) influenced by the determined plurality of sealing parameters, to respectively compress the tube (36)and perform heat sealing of the tube (38).

Abstract: The present disclosure relates to a system and method (10) for monitoring a set-up for manufacture and/or setting up for manufacture and/or tearing down after manufacture of a biopharmaceutical product. The method comprises: processing (S2, S3, S4) at least one image of a scene comprising the set-up for manufacture of the biopharmaceutical product. The processing of the at least one image comprises performing (S2) a first process on the at least one image for classifying first objects in the image, said first objects being devices such as clamps, pumps, valves and/or sensors and/or any other bio processing equipment. The first process comprising identifying, localizing and classifying the first objects in the image. A second process is performed (S3) on the at least one image for identifying and localizing connections in the images.

Abstract: A monitoring system comprises a manufacture system with capability to manufacture a plurality of biopharmaceutical products, at least one image capture device arranged to capture a scene comprising the manufacture system, and a processing element connected to said at least one image capture device and arranged to process images captured by said at least one image capture device to track operator interactions and/or a result of operator interactions within the scene. The processing element is further is arranged to compare a predefined workflow process scheme relating to the selected biopharmaceutical product to at least a part of the tracked operator interactions with the manufacture system and/or to at least a part of the result of the tracked operator interactions with the manufacture system, and determine whether at least one pre-set criterion set by the workflow process scheme is fulfilled based on the comparison.

Abstract: A system for enabling a wireless single use sensing sub-system by optimizing electrical power is presented. The system includes the sensing sub-system configured to be employed in a bio process environment. Further, the sensing sub-system includes a sensing unit configured to measure at least one parameter of the bio process environment. Also, the sensing sub-system includes a power source electrically coupled to the sensing unit and configured to transmit an electrical power to the sensing unit. Furthermore, the sensing sub-system includes a switch configured to electrically couple or decouple the sensing unit from the power source. In addition, the system includes a control sub-system including a first controller configured to determine at least one power control parameter based on a user-input data and a sensing sub-system data, and optimize consumption of the electrical power in the sensing sub-system, based on the power control parameter.

Abstract: A bio-processing system (100) is presented. The bio-processing system (100) includes one or more bio-processing units (110-114), one or more process supporting devices (116, 118), one or more sensors (120-132), and a bio-processing workflow controller (104) wirelessly coupled to at least one of the one or more bio-processing units (110-114), the one or more process supporting devices (116, 118), and the one or more sensors (120-132). The bio-processing workflow controller (104) includes a processor (202) configured to create a reconfigurable bio-processing workflow, and where the reconfigurable bio-processing workflow is representative of an arrangement of one or more of the one or more bio-processing units (110-114), the one or more process supporting devices (116, 118), and the one or more sensors (120-32) to perform at least one bio-processing operation.

Abstract: A bio-processing system (100) for wirelessly powering one or more sensors (116-128, 400) is presented. The system (100) includes bio-processing units (106-110), process supporting devices (112-114), energy sources (146-148), and sensors (116-128, 400) including an energy harvesting unit (402) and an energy storage unit (404). The system (100) includes a power management subsystem (104, 200) wirelessly coupled to the sensors (116-128, 400) and including a processor (202) configured to wirelessly monitor energy consumption of the sensors (116-128, 400) and a level of energy stored in corresponding energy storage units (404), select at least one sensor (116-128, 400) based on the energy consumption of the sensors (116-128, 400) and corresponding levels of energy stored in the energy storage units (404), and identify at least one active energy source (146-148) as a power source, where the identified power source is configured to wirelessly transfer power to the selected sensor (116-128, 400).