Abstract: The invention provides a method for the production of a 3D printed object (100), wherein the method comprises (i) a 3D printing stage, the 3D printing stage comprising 3D printing a 3D printable material (110) to provide the 3D printed object (100) of printed material (120), wherein the 3D printing stage further comprises forming during 3D printing a channel (200) in the 3D printed object (100) under construction, wherein the method further comprises (ii) a filling stage comprising filling the channel (200) with a curable material (140) and curing the curable material (140) to provide the channel (200) with cured material (150), wherein the cured material (150) has a lower stiffness than the surrounding printed material (120).

Abstract: A system (10) for configuring operation settings of a medical device (16) in a state of interaction with a patient (14), and determining features or options of a patient treatment, is based on use of co-operative feedback between digital models (34, 32) for the medical device (16) on the one hand and at least a portion of the anatomy with which the medical device is interaction on the other. A feedback loop is implemented between outputs (46, 48) and inputs (42, 44) of the two models, so that outputs of each model form at least part of the input provided to the other of the models. This way a decision outcome regarding optimum operation settings for the medical device, for balancing both medical aims and also operational efficiency aims for the medical device, can effectively be arrived at iteratively through recursive circular feedback between the two models. The decision outcome may be refined though this process of back and forth feedback.

Abstract: A system for monitoring the interaction of a mask with a patient's face in real-time during a pressure therapy treatment session and providing recommendations for improving such interaction. A sensing arrangement obtains real-time relative position data regarding the relative position of the mask relative to face of the patient and a computing arrangement in communication with the sensing arrangement for receiving the real-time relative position data from the sensing arrangement. The computing arrangement includes a computational model that uses the real-time relative position data to determine information regarding the interaction between the mask and the face of the patient, and an interpretation and analysis unit that: relates the information regarding the interaction between the mask and the face of the patient to functional parameters, determines actionable information and/or insights to improve the interaction, and provides as output the actionable information and/or insights.

Abstract: The invention provides a method for the production of a 3D printed object (100), wherein the method comprises (i) a 3D printing stage, the 3D printing stage comprising 3D printing a 3D printable material (110) to provide the 3D printed object (100) of printed material (120), wherein the 3D printing stage further comprises forming during 3D printing a channel (200) in the 3D printed object (100) under construction, wherein the method further comprises (ii) a filling stage comprising filling the channel (200) with a curable material (140) and curing the curable material (140) to provide the channel (200) with cured material (150), wherein the cured material (150) has a lower stiffness than the surrounding printed material (120).

Abstract: Disclosed is a computer system (20) comprising a processor arrangement (22) communicatively coupled to a data storage arrangement (30) storing a virtual model of a patient, said virtual model comprising at least one of a digital representation of at least a part of the anatomy of the patient and a physiological model of a bodily process of the patient; and a communication module (24) communicatively coupled to said processor arrangement and arranged to receive sensor data from one or more sensors (12, 14, 16) arranged to monitor said patient, wherein the processor arrangement is arranged to retrieve (103) said virtual model from the data storage arrangement; receive (105) said sensor data from the communication module; evaluate said sensor data with said virtual model; generate (111, 121) an instruction for altering a mode of operation of at least one sensor of the one or more sensors in response to said evaluation or in response to a user request; and transmit said instruction to the at least one sensor or t

Abstract: Method for the production of a 3D printed object (100), wherein the method comprises (i) a 3D printing stage, the 3D printing stage comprising 3D printing a 3D printable material (110) to provide the 3D printed object (100) of printed material (120), wherein the 3D printing stage further comprises forming during 3D printing a channel (200) in the 3D printed object (100) under construction, wherein the method further comprises (ii) a filling stage comprising filling the channel (200) with a curable material (140) and curing the curable material (140) to provide the channel (200) with cured material (150), wherein the cured material (150) has a lower stiffness than the surrounding printed material (120).

Abstract: A device comprises a surface mount component on a substrate, in which the surface mount component is attached by a set of discrete mechanical coupling parts and by a bonding layer. This enables the mechanical coupling properties and the electrical/thermal properties to be optimized separately.

Abstract: Method for the production of a 3D printed object (100), wherein the method comprises (i) a 3D printing stage, the 3D printing stage comprising 3D printing a 3D printable material (110) to provide the 3D printed object (100) of printed material (120), wherein the 3D printing stage further comprises forming during 3D printing a channel (200) in the 3D printed object (100) under construction, wherein the method further comprises (ii) a filling stage comprising filling the channel (200) with a curable material (140) and curing the curable material (140) to provide the channel (200) with cured material (150), wherein the cured material (150) has a lower stiffness than the surrounding printed material (120).