Patents by Inventor Valentin Thorey
Valentin Thorey has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Publication number: 20260105608Abstract: Systems and methods are provided for processing image data generated by a medical imaging system such as an ultrasound or echocardiogram system using artificial intelligence and machine learning to determine a presence of one or more congenital heart defects (CHDs) and/or other cardiovascular anomalies in the image data in a manner that is agnostic to the type of imaging system, software, and/or hardware. Image data from various types imaging systems, software, and/or hardware, having various styles of imaging data generated may be processed to determine image styles. Input image data for analysis may then be processed together with representative styles of image data to generate styled input images for each style. The styled input images may be processed by an image analyzer to detect one or more cardiovascular anomalies in the styled image data, for example. Alternatively, training data may be styled and used to train the image analyzer.Type: ApplicationFiled: December 4, 2025Publication date: April 16, 2026Applicant: BrightHeart SASInventors: Christophe GARDELLA, Valentin THOREY, Eric ASKINAZI
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Publication number: 20260094276Abstract: Systems and methods are provided for processing image data generated by a medical imaging device such as an ultrasound or echocardiogram device and processing the image data using artificial intelligence and machine learning to determine a presence of one or more congenital heart defects (CHDs) and/or other cardiovascular anomalies in the image data, to identify anatomy, detect and/or identify motion, and/or to determine key-point and/or contour detection. The image processing system may be used to detect CHDs and/or other cardiovascular anomalies in a fetus. The image data may be processed using a spatiotemporal convolutional neural network (CNN). The spatiotemporal CNN may include a spatial CNN for image recognition and a temporal CNN for processing optical flow data and/or image data. The outputs of the spatial CNN and the temporal CNN may be fused (e.g., using late fusion) and/or may be processed by a spatiotemporal CNN.Type: ApplicationFiled: December 8, 2025Publication date: April 2, 2026Applicant: BrightHeart SASInventors: Christophe GARDELLA, Valentin THOREY, Eric ASKINAZI, Cécile DUPONT
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Patent number: 12493962Abstract: Systems and methods are provided for processing image data generated by a medical imaging device such as an ultrasound or echocardiogram device and processing the image data using artificial intelligence and machine learning to determine a presence of one or more congenital heart defects (CHDs) and/or other cardiovascular anomalies in the image data, to identify anatomy, detect and/or identify motion, and/or to determine key-point and/or contour detection. The image processing system may be used to detect CHDs and/or other cardiovascular anomalies in a fetus. The image data may be processed using a spatiotemporal convolutional neural network (CNN). The spatiotemporal CNN may include a spatial CNN for image recognition and a temporal CNN for processing optical flow data and/or image data. The outputs of the spatial CNN and the temporal CNN may be fused (e.g., using late fusion) and/or may be processed by a spatiotemporal CNN.Type: GrantFiled: November 18, 2024Date of Patent: December 9, 2025Assignee: BrightHeart SASInventors: Christophe Gardella, Valentin Thorey, Eric Askinazi, Cécile Dupont
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Publication number: 20250261926Abstract: Systems and methods are provided for aiding the detection and diagnosis of critical heart defects during fetal ultrasound examinations, in which image data (e.g., motion video clips and/or image frames) is analyzed with machine learning algorithms to detect and identify morphological and/or flow abnormalities indicative of critical CHDs. The results of the analyses are presented for review to the clinician, optionally with an overlay, for the selected image frames that identifies the abnormalities with graphical or textual indicia. The overlay further may be annotated by the clinician and stored to create documentary record of the fetal ultrasound examination.Type: ApplicationFiled: May 5, 2025Publication date: August 21, 2025Applicant: BrightHeart SASInventors: Christophe GARDELLA, Valentin THOREY, Eric ASKINAZI, Olivier TRANZER, Marilyne LEVY, Bertrand STOS, Cécile DUPONT
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Patent number: 12343197Abstract: Systems and methods are provided for aiding the detection and diagnosis of critical heart defects during fetal ultrasound examinations, in which image data (e.g., motion video clips and/or image frames) is analyzed with machine learning algorithms to detect and identify morphological and/or flow abnormalities indicative of critical CHDs. The results of the analyses are presented for review to the clinician, optionally with an overlay, for the selected image frames that identifies the abnormalities with graphical or textual indicia. The overlay further may be annotated by the clinician and stored to create documentary record of the fetal ultrasound examination.Type: GrantFiled: September 9, 2024Date of Patent: July 1, 2025Assignee: BrightHeart SASInventors: Christophe Gardella, Valentin Thorey, Eric Askinazi, Olivier Tranzer, Marilyne Levy, Bertrand Stos, Cécile Dupont
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Publication number: 20250078278Abstract: Systems and methods are provided for processing image data generated by a medical imaging device such as an ultrasound or echocardiogram device and processing the image data using artificial intelligence and machine learning to determine a presence of one or more congenital heart defects (CHDs) and/or other cardiovascular anomalies in the image data, to identify anatomy, detect and/or identify motion, and/or to determine key-point and/or contour detection. The image processing system may be used to detect CHDs and/or other cardiovascular anomalies in a fetus. The image data may be processed using a spatiotemporal convolutional neural network (CNN). The spatiotemporal CNN may include a spatial CNN for image recognition and a temporal CNN for processing optical flow data and/or image data. The outputs of the spatial CNN and the temporal CNN may be fused (e.g., using late fusion) and/or may be processed by a spatiotemporal CNN.Type: ApplicationFiled: November 18, 2024Publication date: March 6, 2025Applicant: BrightHeart SASInventors: Christophe GARDELLA, Valentin THOREY, Eric ASKINAZI, Cécile DUPONT
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Publication number: 20240423583Abstract: Systems and methods are provided for aiding the detection and diagnosis of critical heart defects during fetal ultrasound examinations, in which image data (e.g., motion video clips and/or image frames) is analyzed with machine learning algorithms to detect and identify morphological and/or flow abnormalities indicative of critical CHDs. The results of the analyses are presented for review to the clinician, optionally with an overlay, for the selected image frames that identifies the abnormalities with graphical or textual indicia. The overlay further may be annotated by the clinician and stored to create documentary record of the fetal ultrasound examination.Type: ApplicationFiled: September 9, 2024Publication date: December 26, 2024Applicant: BrightHeart SASInventors: Christophe GARDELLA, Valentin THOREY, Eric ASKINAZI, Olivier TRANZER, Marilyne LEVY, Bertrand STOS, Cécile DUPONT
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Patent number: 12148162Abstract: Systems and methods are provided for processing image data generated by a medical imaging device such as an ultrasound or echocardiogram device and processing the image data using artificial intelligence and machine learning to determine a presence of one or more congenital heart defects (CHDs) and/or other cardiovascular anomalies in the image data and/or to determine key-point and/or contour detection. The image processing system may be used to detect CHDs and/or other cardiovascular anomalies in a fetus. The image data may be processed using a spatiotemporal convolutional neural network (CNN). The spatiotemporal CNN may include a spatial CNN for image recognition and a temporal CNN for processing optical flow data based on the image data. The outputs of the spatial CNN and the temporal CNN may be fused (e.g., using late fusion) to generate a likelihood of CHDs and/or other cardiovascular anomalies.Type: GrantFiled: January 12, 2024Date of Patent: November 19, 2024Assignee: BrightHeart SASInventors: Christophe Gardella, Valentin Thorey, Eric Askinazi, Cécile Dupont
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Patent number: 12082969Abstract: Systems and methods are provided for aiding the detection and diagnosis of critical heart defects during fetal ultrasound examinations, in which image data (e.g., motion video clips and/or image frames) are analyzed with machine learning algorithms to identify and select image frames within the image data that correspond to standard views recommended by fetal ultrasound guidelines, and selected image frames are analyzed with machine learning algorithms to detecting and identify morphological abnormalities indicative of critical CHDs associated with the standard views. The results of the analyses are presented for review to the clinician with an overlay for the selected image frames that identifies the abnormalities with graphical or textual indicia. The overlay further may be annotated by the clinician and stored to create documentary record of the fetal ultrasound examination.Type: GrantFiled: January 8, 2024Date of Patent: September 10, 2024Assignee: BrightHeart SASInventors: Christophe Gardella, Valentin Thorey, Eric Askinazi, Olivier Tranzer, Marilyne Levy, Bertrand Stos, Cécile Dupont
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Publication number: 20240277312Abstract: Systems and methods are provided for aiding the detection and diagnosis of critical heart defects during fetal ultrasound examinations, in which image data (e.g., motion video clips and/or image frames) are analyzed with machine learning algorithms to identify and select image frames within the image data that correspond to standard views recommended by fetal ultrasound guidelines, and selected image frames are analyzed with machine learning algorithms to detecting and identify morphological abnormalities indicative of critical CHDs associated with the standard views. The results of the analyses are presented for review to the clinician with an overlay for the selected image frames that identifies the abnormalities with graphical or textual indicia. The overlay further may be annotated by the clinician and stored to create documentary record of the fetal ultrasound examination.Type: ApplicationFiled: January 8, 2024Publication date: August 22, 2024Applicant: BrightHeart SASInventors: Christophe GARDELLA, Valentin THOREY, Eric ASKINAZI, Olivier TRANZER, Marilyne LEVY, Bertrand STOS, Cécile DUPONT
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Publication number: 20240281971Abstract: Systems and methods are provided for processing image data generated by a medical imaging device such as an ultrasound or echocardiogram device and processing the image data using artificial intelligence and machine learning to determine a presence of one or more congenital heart defects (CHDs) and/or other cardiovascular anomalies in the image data and/or to determine key-point and/or contour detection. The image processing system may be used to detect CHDs and/or other cardiovascular anomalies in a fetus. The image data may be processed using a spatiotemporal convolutional neural network (CNN). The spatiotemporal CNN may include a spatial CNN for image recognition and a temporal CNN for processing optical flow data based on the image data. The outputs of the spatial CNN and the temporal CNN may be fused (e.g., using late fusion) to generate a likelihood of CHDs and/or other cardiovascular anomalies.Type: ApplicationFiled: January 12, 2024Publication date: August 22, 2024Applicant: BrightHeart SASInventors: Christophe GARDELLA, Valentin THOREY, Eric ASKINAZI, Cécile DUPONT
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Patent number: 11861838Abstract: Systems and methods are provided for processing image data generated by a medical imaging system such as an ultrasound or echocardiogram system using artificial intelligence and machine learning to determine a presence of one or more congenital heart defects (CHDs) and/or other cardiovascular anomalies in the image data in a manner that is agnostic to the type of imaging system, software, and/or hardware. Image data from various types imaging systems, software, and/or hardware, having various styles of imaging data generated may be processed to determine image styles. Input image data for analysis may then be processed together with representative styles of image data to generate styled input images for each style. The styled input images may be processed by an image analyzer to detect one or more cardiovascular anomalies in the styled image data, for example. Alternatively, training data may be styled and used to train the image analyzer.Type: GrantFiled: June 7, 2023Date of Patent: January 2, 2024Assignee: BrightHeart SASInventors: Christophe Gardella, Valentin Thorey, Eric Askinazi
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Publication number: 20210407646Abstract: A method, implemented by computer, for predicting an effect of an acoustic stimulation of the brain waves of an individual, the method including: acquisition of at least one measurement signal representative of a physiological signal of the individual, by a device for acoustic stimulation of brain waves that is suitable for being worn by the individual; analysis of the measurement signal by an artificial intelligence trained to predict the effect of an acoustic stimulation; and determination of whether an acoustic stimulation is to be performed by the device.Type: ApplicationFiled: October 16, 2019Publication date: December 30, 2021Inventors: Valentin THOREY, Clémence PINAUD
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Publication number: 20190298212Abstract: Disclosed is a method and device for determining a robust synthetic signal indicative of a bioelectrical activity of an individual. Two measurement signals representative of physiological electrical signals of an individual are continuously acquired by electrodes. Two time series of confidence indices associated with the measurement signals are constructed. A synthetic signal is determined from the measurement signals and from the time series of confidence indices.Type: ApplicationFiled: December 5, 2017Publication date: October 3, 2019Inventors: Quentin SOULET DE BRUGIÈRE, Hugo MERCIER, Valentin THOREY, Mathieu GALTIER, Jérôme KALIFA
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Publication number: 20180236232Abstract: A method and system for personalized acoustic brain wave stimulation of a person. The system comprises an acoustic stimulation device and a remote server. The device comprises a memory able to store operating parameters, acquisition element of a measured signal analysis element in order to assess whether the person is in a state susceptible to stimulation and emission element designed for emitting an acoustic signal. The acquisition element, analysis element and/or emission element operate depending on operating parameters. The device and the remote server comprise means of data transmission for transmitting operating data from the device to the server and transmitting second operating parameters from the server to the device. The remote server comprises means of processing operating data for determining second operating parameters.Type: ApplicationFiled: August 4, 2016Publication date: August 23, 2018Applicant: RYTHMInventors: Quentin Soulet De Brugiere, Hugo Mercier, Valentin Thorey, Oliver Tranzer