System and method for vascular image coregistration
A neural network trained on co-registered vascular imaging data predicts hemodynamic values, addressing the co-registration challenge in vascular imaging systems, enhancing vascular health assessment.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- BOSTON SCIENTIFIC SCIMED INC
- Filing Date
- 2026-03-05
- Publication Date
- 2026-06-23
AI Technical Summary
Existing medical imaging systems for vascular structures lack effective methods for co-registration of intravascular and extravascular imaging data, limiting the comprehensive assessment of hemodynamic parameters.
A neural network is trained using co-registered intravascular and extravascular image datasets, along with hemodynamic data, to predict hemodynamic values from intravascular images, enabling accurate hemodynamic data prediction during intravascular imaging procedures.
Enables simultaneous display of intravascular images with predicted hemodynamic values, providing a comprehensive and accurate assessment of vascular health without additional pullback operations.
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Figure 2026102691000001_ABST
Abstract
Description
Technical Field
[0001] The present disclosure relates to medical imaging, and systems and methods for medical imaging. More particularly, the present disclosure relates to systems and methods for vascular imaging, including intravascular imaging, extravascular imaging, and co-registration.
Background Art
[0002] For medical applications, such as for imaging of vascular anatomical structures, a wide variety of medical imaging systems and methods have been developed. Some of these systems and methods include intravascular imaging modalities and extravascular imaging modalities for imaging vascular structures. These systems and methods include various configurations and can operate or be used according to any one of a variety of methods. Each of the known vascular imaging systems and methods has specific advantages and disadvantages. Accordingly, there is a continuing need to provide alternative systems and methods for vascular imaging and evaluation, as well as co-registration of imaging.
Summary of the Invention
[0003] This disclosure provides alternative medical imaging systems and methods. One example includes a method for evaluating patient hemodynamic data. The method includes training a neural network, then acquiring intravascular images of the patient, and using the trained neural network to evaluate the corresponding hemodynamic data. Training the neural network includes providing the neural network with multiple extravascular image datasets and providing the neural network with multiple intravascular image datasets. Each intravascular image dataset contains intravascular image data showing a portion of a vessel from a start to an end position, and each intravascular image dataset is colregistrated with a corresponding extravascular image dataset from the multiple extravascular image datasets. Training the neural network also includes providing the neural network with multiple hemodynamic datasets, each hemodynamic dataset being colregistrated with a corresponding extravascular image dataset from the multiple extravascular image datasets. A neural network using multiple provided intravascular image datasets and multiple provided hemodynamic datasets, each correlated with its corresponding extravascular image dataset, learns which hemodynamic data are expected for a given intravascular image dataset, thereby creating a trained neural network. Using the trained neural network with subsequent patients involves performing an intravascular imaging action (event) in which an intravascular imaging element is moved from a start position to an end position within the patient's blood vessel to generate one or more intravascular images. The trained neural network uses its training to predict hemodynamic values corresponding to one or more intravascular images from the intravascular imaging action, and the one or more intravascular images are output in combination with the predicted hemodynamic values.
[0004] Alternatively or additionally, at least some of the multiple intravascular image datasets provided during the neural network training process may include intravascular ultrasound data.
[0005] Alternatively or additionally, at least some of the multiple intravascular image datasets provided during the neural network training process may include optical coherence tomography (OCT) data.
[0006] Alternatively or additionally, at least some of the extravascular image datasets provided during the training of the neural network may include fluorescence fluoroscopy image data. Alternatively or additionally, at least some of the extravascular image datasets provided during the neural network training may include angiographic image data.
[0007] Alternatively or additionally, the angiography data may include two-dimensional angiography image data. Alternatively or additionally, the angiography data may include three-dimensional angiography image data. Alternatively or additionally, angiography data may include 3D CTA (3D computed tomography angiography).
[0008] Alternatively or additionally, at least some of the multiple hemodynamic datasets provided during the training of the neural network may include blood pressure data obtained by any congestion index or decongestion index.
[0009] Alternatively or additionally, at least some of multiple intravascular imaging datasets and at least some of the corresponding hemodynamic datasets may be co-registered using their corresponding points in 2D or 3D space on the corresponding extravascular imaging datasets.
[0010] Alternatively or additionally, a neural network may include an ensemble of neural networks. Alternatively or additionally, neural networks may include CNNs (Convolutional Neural Networks) that have transformers.
[0011] Alternatively or additionally, the neural network may include a multi-layer neural network. Alternatively or additionally, multilayer neural networks may include a hemodynamic term in their loss function.
[0012] Alternatively or additionally, at least some of the multiple intravascular image datasets provided during the training of the neural network may include quantitative data such as luminal boundaries, vascular boundaries, side branch boundaries, blood speckle density, and cardiac cycle parameters, which may be used when training the neural network.
[0013] Alternatively or additionally, one or more intravascular images from an intravascular imaging operation may include anatomical landmarks, and predicted hemodynamic values may include predicted blood pressure values adjacent to the anatomical landmarks.
[0014] Alternatively or additionally, outputting one or more intravascular images in combination with predicted hemodynamic values may include displaying one or more intravascular images and predicted hemodynamic values on the graphical user interface of the signal processing unit.
[0015] Alternatively or additionally, displaying one or more intravascular images and predicted hemodynamic values on the graphical user interface of the signal processing unit may include displaying complete and correlated predicted hemodynamic values together with the intravascular images.
[0016] Alternatively or additionally, displaying one or more intravascular images and predicted hemodynamic values on the graphical user interface of the signal processing unit may include displaying a fully tri-registered representation of the predicted hemodynamic values together with the intravascular image and the corresponding extravascular image.
[0017] Another example involves a method for processing image data. This method involves providing a neural network with multiple intravascular image datasets, each containing intravascular image data representing a portion of a blood vessel, colregistered with an extravascular image from a corresponding extravascular image dataset, from a start to an end position. Multiple hemodynamic datasets are provided to the neural network, each containing hemodynamic data from a corresponding portion of a blood vessel, colregistered with an extravascular image from a corresponding extravascular image dataset, from a start to an end position, as represented by one of the multiple intravascular image datasets. Using the provided intravascular image datasets and the corresponding provided hemodynamic datasets, derived from the colregistration of each dataset to the same extravascular image, the neural network learns which hemodynamic data is expected for a given intravascular image dataset, thereby training the neural network. An intravascular imaging operation is performed on a new patient, in which an imaging element is moved within a blood vessel from a start to an end position to generate one or more intravascular images. The neural network uses its training to predict hemodynamic values corresponding to one or more intravascular images from intravascular imaging operations. The one or more intravascular images are output in combination with the predicted hemodynamic values.
[0018] Alternatively or additionally, at least some of the multiple intravascular imaging datasets may include intravascular ultrasound data. Alternatively or additionally, at least some of the multiple intravascular imaging datasets may include optical coherence tomography (OCT) data.
[0019] Alternatively or additionally, at least some of the multiple extravascular imaging datasets may include fluorescence fluoroscopy image data. Alternatively or additionally, at least some of the extravascular image datasets may include angiographic image data.
[0020] Alternatively or additionally, at least some of the multiple hemodynamic datasets may include blood pressure data obtained by any congestion index or non-congestion index. Another example includes a method for processing patient image data. This method includes acquiring intravascular image data from an intravascular imaging device, the acquisition including imaging operations in the course of a kinetic procedure in which an imaging element is moved within a blood vessel from a start position to an end position, and the intravascular image data includes one or more intravascular images. To determine a predicted blood pressure measurement for each of the one or more intravascular images, the one or more intravascular images are input into a trained neural network. A series of intravascular blood pressure values corresponding to the intravascular position of each of the one or more extravascular images is calculated, and a blood pressure ratio is calculated based on the series of blood pressure values.
[0021] Alternatively or additionally, the method may further include outputting intravascular image data and calculated blood pressure corresponding to points within the blood vessel. Alternatively or additionally, the method may further include acquiring extravascular image data, which includes one or more extravascular images, and colregistrating the intravascular image data with the extravascular image data to determine the intravascular location of each of the one or more extravascular images.
[0022] Alternatively or additionally, the method may further include outputting correlated extravascular image data in combination with intravascular image data and calculated blood pressure points corresponding to intravascular points.
[0023] Alternatively or additionally, acquiring extravascular imaging data may include acquiring extravascular imaging data corresponding to the vessel from the starting point to the ending point. Alternatively or additionally, the intravascular image data may include intravascular ultrasound data.
[0024] Alternatively or additionally, the intravascular image data may include optical coherence tomography data. Alternatively or additionally, the extravascular image data may include fluoroscopic image data. Alternatively or additionally, the extravascular image data set may include angiographic image data.
[0025] Another example includes a method for processing image data. The method includes encoding physical features from a plurality of IVUS frames generated during an IVUS pullback execution. Physiology resting index (PRI) pullback data is collected. Angiographic image data is collected and coregistered with the PRI pullback data. The IVUS frames are coregistered with the angiographic image data to coregister the PRI pullback data with the IVUS frames. The coregistered IVUS frames, angiographic image data, and PRI pullback data are used to train a neural network on how to predict PRI data based on subsequent IVUS pullback executions. Thereafter, a new IVUS pullback execution is performed to provide new IVUS pullback execution data including a plurality of IVUS frames to the neural network so that the neural network can calculate the predicted PRI value for each IVUS frame.
[0026] Alternatively or additionally, the method may further include coregistering the new IVUS pullback execution data with a corresponding angiography execution. The above summary of some embodiments is not intended to describe each disclosed embodiment or every implementation of the present disclosure. The following drawings and "Detailed Description of the Invention" illustrate these embodiments more specifically.
[0027] This disclosure can be better understood by considering the following "Modes for Carrying Out the Invention" in relation to the attached drawings. [Brief explanation of the drawing]
[0028] [Figure 1] A schematic diagram illustrating the training and use of a neural network to predict hemodynamic values based on intravascular imaging data. [Figure 2A] A flowchart illustrating an exemplary method for evaluating patient hemodynamic data. [Figure 2B] A flowchart illustrating an exemplary method for training a neural network as part of the method shown in Figure 2A. [Figure 2C] A flowchart illustrating an exemplary method for using a trained neural network as part of the method shown in Figure 2A. [Figure 3] A flowchart illustrating an exemplary method for processing image data. [Figure 4] A flowchart illustrating an exemplary method for processing patient image data. [Figure 5] A flowchart illustrating an exemplary method for processing image data. [Figure 6] A schematic diagram of an exemplary model. [Figure 7] A schematic diagram of an exemplary model. [Figure 8] A schematic diagram of an exemplary model. [Figure 9] A schematic diagram of an exemplary system for use in vascular imaging coregistration. [Figure 10] A schematic diagram of an exemplary intravascular imaging catheter, shown in a partial cross-sectional view. [Figure 11] A schematic diagram of the distal portion of an exemplary intravascular imaging catheter shown in cross-section in Figure 10. [Modes for carrying out the invention]
[0029] This disclosure is applicable to various modifications and alternative forms, the details of which are illustrated by example in the drawings and described in detail. However, it should be understood that the intent is not to limit the invention to the specific embodiments described. On the contrary, the invention encompasses all modifications, equivalents, and alternative forms that fall within the spirit and scope of this disclosure.
[0030] The terms defined below shall apply unless otherwise given in the claims or elsewhere in this specification. All numerical values herein are assumed to be modified by the term “approximately,” whether expressly indicated or not. The term “approximately” generally refers to a range of numbers that a person skilled in the art could consider equivalent to (e.g., having the same function or result as) the listed values. In many cases, the term “approximately” may include numbers rounded to the nearest significant figure.
[0031] Numerical ranges specified by endpoints include all numbers within that range (for example, 1-5 includes 1, 1.5, 2, 2.75, 3, 3.80, 4, and 5). When used herein and in the appended claims, the singular forms “a,” “an,” and “the” refer to multiple subjects unless the context clearly indicates otherwise. When used herein and in the appended claims, the term “or” is used generally to mean “or” unless the context clearly indicates otherwise.
[0032] Please note that references in this specification to “one embodiment,” “several embodiments,” and “other embodiments” indicate that the embodiments described may include one or more specific features, structures, or characteristics. However, such descriptions do not necessarily mean that all embodiments include a particular feature, structure, or characteristic. In addition, if a particular feature, structure, or characteristic is described in relation to one embodiment, please understand that such feature, structure, or characteristic may also be used in relation to other embodiments, whether explicitly described or not, unless otherwise specified.
[0033] The following detailed description should be read with reference to the drawings, where similar elements in different drawings are numbered the same. The drawings are not necessarily to scale and illustrate exemplary embodiments; they are not intended to limit the scope of the invention.
[0034] Several different medical imaging modalities may be used to evaluate or treat blood vessels. Two common types of imaging modalities include extravascular imaging modalities and intravascular imaging modalities. This disclosure relates to the use and coregistration of these modalities.
[0035] Extravascular imaging modalities, such as various forms of radiographic imaging, provide extravascular image data of a portion of a blood vessel. Some examples include angiography or fluoroscopy imaging modalities such as two-dimensional angiography / fluoroscopy, three-dimensional angiography / fluoroscopy, or computed tomography angiography / fluoroscopy. Angiography typically involves rendering radiographic images of one or more blood vessels, often using radiopaque contrast agents. Angiographic images can also be viewed in real time by fluoroscopy. Generally, fluoroscopy uses less radiation than angiography and is often used to guide medical devices containing radiopaque markers within or passing through blood vessels. Extravascular image data of blood vessels can provide useful information about the location or positioning of blood vessels, anatomical structures, or devices within blood vessels or anatomical structures. For example, extravascular imaging data (e.g., angiography) can provide a comprehensive overall image or a series of images or videos of the target vessel(s), and can provide a “roadmap” with good temporal resolution for a general assessment of the vessel(s) or for navigation of intravascular devices.
[0036] Intravascular imaging modalities provide intravascular imaging data of a portion of a blood vessel. Some examples of intravascular imaging modalities include intravascular ultrasound (IVUS) and optical coherence tomography (OCT). These modalities typically involve imaging the blood vessel itself using an instrument-mounted intravascular probe containing an imaging element placed inside the blood vessel. Several types of instrument systems are designed to track through vascular structures to provide intravascular imaging data. These may include, but are not limited to, intravascular ultrasound (IVUS) and optical coherence tomography (OCT) instruments (e.g., catheters, guidewires, etc.). During operation, the intravascular instrument-mounted probe containing the imaging element is moved along the blood vessel in the area where imaging is desired. As the probe passes through the region of interest, a set of intravascular imaging data corresponding to a series of "slices" or cross-sections of the blood vessel, lumen, and surrounding tissue is obtained. These instruments may include radiopaque material or markers. Such markers are generally positioned near the distal tip, or near or on the probe. Therefore, the approximate location of the imaging probe or imaging element can be identified by observing the procedure in either a fluoroscopy or angiography image(s). Typically, such an imaging device is connected to a dedicated processing unit or control module, which includes processing hardware and software, as well as a display. Raw image data is received by a console, processed to render an image containing features of interest, and rendered on a display device. Intravascular image data of a vessel can provide useful information about the vessel, different from, or in addition to, the information provided by extravascular image data. For example, intravascular image data may provide data on the cross-section of the lumen, the thickness of deposits on the vessel wall, the diameter of the non-affected portion of the vessel, the length of the affected section, the composition of deposits or plaque on the vessel wall, an assessment of plaque load, or an assessment of stent deployment.
[0037] These two common types of imaging modalities provide different image data and can therefore be complementary to each other. Thus, in certain situations, it may be desirable to provide or use both common types of medical imaging modalities to evaluate or treat blood vessels. In addition, it may be useful to correlate the location of acquired intravascular image data / images with their locations on a vascular roadmap obtained by extravascular image data / images. It may be useful to align or "register" (e.g., co-registration) image data rendered by two different modalities. It may also be useful to display the co-registered extravascular and intravascular image data together, for example, on a common display monitor. Several exemplary embodiments disclosed herein may include or relate to some or all of these embodiments.
[0038] According to some embodiments of the present disclosure, exemplary methods(s), systems(s), devices(s), or software are described herein. These examples include image acquisition devices and data / image processors, as well as associated software, for acquiring and registering (e.g., co-registration) image data rendered by two separate imaging modalities (e.g., extravascular image data and intravascular image data). Additionally or alternatively, exemplary methods(s), systems(s), or software may generate images on a single display that simultaneously provide extravascular images with positional information associated with an imaging probe (e.g., an IVUS or OCT probe) attached to an intravascular device and intravascular images.
[0039] Hemodynamic data can be useful in assessing a patient's health. In some cases, hemodynamic information, including but not limited to blood pressure data, can be helpful in assessing the health of a patient's vascular system. Various systems can be used to acquire hemodynamic data. These systems for acquiring hemodynamic data may require one or more pullback operations to obtain the data. In some cases, it may be useful to provide hemodynamic data without requiring any additional pullback operations or any other processes or techniques for acquiring blood pressure information and / or other hemodynamic data.
[0040] Figure 1 provides a schematic diagram of an exemplary system 10 in which a neural network 12 can be trained to provide evaluated hemodynamic values corresponding to specific intravascular images. The neural network 12 can be any of several different types of neural networks. In some cases, the neural network 12 may represent a single neural network or multiple neural networks. In some cases, the neural network 12 may be explicitly located, for example, in a cloud-based server. The neural network 12 may represent a CNN (Convolutional Neural Network) with one or more transformers. In some cases, the neural network 12 may include a multilayer neural network. These are merely examples.
[0041] The neural network 12 can be adapted to learn. In some cases, the neural network 12 can be considered to include AI (artificial intelligence) and, optionally, to be capable of ML (machine learning). To train the neural network 12, the neural network 12 can be provided with existing data that the neural network 12 can learn from. In some cases, the neural network 12 can be trained on how to associate specific hemodynamic characteristics or values with corresponding intravascular images. The neural network 12 can be provided with multiple intravascular image datasets from various different imaging modalities, such as but not limited to intravascular ultrasound and optical coherence tomography data, as illustrated with respect to Figures 9 to 11. The neural network 12 can be provided with multiple extravascular image datasets 16. The extravascular image datasets 16 may include fluoroscopy image data and / or angiography image data. Examples of angiographic image data include, but are not limited to, 2D (two-dimensional) angiographic data, 3D (three-dimensional) angiographic data, and 3D CTA (three-dimensional computed tomography angiography).
[0042] Each of the multiple extravascular image datasets 16 provided to the neural network 12 can be co-registered with a corresponding one of the multiple intravascular image datasets 14, for example, if a particular intravascular image dataset 14 corresponds to a particular intravascular image acquisition session (such as an imaging pullback execution) of a particular portion of a blood vessel from a particular start point to a particular end point in a patient, and the corresponding extravascular image dataset 16 corresponds to extravascular image data from the same portion of the same blood vessel in the same patient, from the same start point to the same end point. In some cases, the portion of the patient's anatomical structure represented by a particular intravascular image dataset 14 may not exactly match the portion of the patient's anatomical structure represented by a particular extravascular image dataset 16, but they may overlap. In any operation, each intravascular image dataset 14 can be co-registered with the corresponding extravascular image dataset 16, as shown in block 18. The method for co-registering the intravascular image datasets 14 and extravascular image datasets 16 is described in detail with respect to Figures 9 to 11 and then explained.
[0043] The neural network 12 may be provided with existing hemodynamic datasets 20. In some cases, a particular hemodynamic dataset represents hemodynamic data such as, but not limited to, blood pressure data of a particular patient. In some cases, each hemodynamic dataset 20 corresponds to one or more blood pressure measurements taken at a specific location within a specific blood vessel of a particular patient. In some cases, one or more blood pressure measurements correspond to a specific location within a specific blood vessel that matches an anatomical structure represented by a particular extravascular image dataset 16. In other words, as shown in block 22, each hemodynamic dataset 20 can be colregistrated with a corresponding extravascular image dataset 16.
[0044] It will be understood that by colregistrating each of the intravascular image datasets 14 with a corresponding one of the extravascular image datasets 16, and by colregistrating each of the hemodynamic datasets 20 with a corresponding one of the extravascular image datasets 16, the neural network 12 can verify the correlation between intravascular image data and extravascular image data and hemodynamic data. As a result, by processing several intravascular image datasets 14, several corresponding extravascular image sets 16, and several corresponding hemodynamic datasets 20, and by being given or otherwise determining the colregistration between intravascular data and extravascular data, colregistration between extravascular data and hemodynamic data, and thus between intravascular data and hemodynamic data, the neural network 12 can learn how to evaluate or predict hemodynamic data, such as blood pressure measurements, as a result of what the neural network 12 is seeing in a particular intravascular image(s) image.
[0045] At least some of the intravascular imaging datasets 14, at least some of the extravascular imaging datasets 16, and at least some of the hemodynamic datasets 20 may represent previously acquired and stored historical data. At least some of the intravascular imaging datasets 14, at least some of the extravascular imaging datasets 16, and at least some of the hemodynamic datasets 20 may represent data acquired from volunteers undergoing these imaging processes to contribute to useful data for training the neural network 12. At least some of the intravascular imaging datasets 14, at least some of the extravascular imaging datasets 16, and at least some of the hemodynamic datasets 20 may represent patient data that can be independently acquired for research purposes when patients undergo intravascular imaging, extravascular imaging, and hemodynamic measurements for any of a variety of different clinical purposes.
[0046] As a result of training, the neural network 12 can be considered to have evolved into the trained neural network 24. Here, the distinction between the neural network 12 and the trained neural network 24 does not necessarily have to be binary; that is, the neural network 12 transforms into the trained neural network 24 once sufficient training is complete. In some cases, training may continue indefinitely. The neural network considered to be trained may be tested periodically, for example, by providing the neural network 24 with intravascular data, while hemodynamic data obtained essentially simultaneously from the same patient and from the same anatomical structure can be used as a check against the evaluated hemodynamic measurements provided by the trained neural network 24. If the actual hemodynamic measurements are close to the predicted hemodynamic measurements, this can be interpreted as indicating that the trained neural network 24 is indeed well-trained. However, if there is a discrepancy, or even a substantial discrepancy, between the actual hemodynamic measurements and the predicted hemodynamic measurements, this can be interpreted as indicating that the trained neural network 24 may benefit from further training.
[0047] Once the neural network 12 is trained into a neural network 24, the trained neural network 24 can be used to provide evaluated hemodynamic values in response to intravascular pullback operations, such as IVUS (intravascular ultrasound) pullback operations, but is not limited to these. Performing intravascular pullback operations can provide a source of intravascular images 26. Feeding the intravascular images 26 to the trained neural network 24 can yield predicted hemodynamic values 28. Through training, the trained neural network 24 learns what hemodynamic values 28 have historically resulted from a specific set of parameters that define the intravascular images. For example, a specific type and size of intravascular occlusion historically leads to a specific change in blood pressure measurements. Once the trained neural network 24 has determined the evaluated hemodynamic values, the intravascular images and the corresponding predicted hemodynamic values can be output to any available screen, as shown in block 30. In some cases, for example, the output of intravascular images and corresponding predicted hemodynamic values may be via a computer system / subsystem 130, as described with respect to Figure 9, but may be a computer, and is not limited to this.
[0048] Figures 2A, 2B, and 2C are flowcharts that provide an exemplary method 32 for evaluating patient hemodynamic data. Figures 2B and 2C provide details not outlined in Figure 2A. Method 32 includes training a neural network (e.g., neural network 12) as shown in block 34, and using the trained neural network (e.g., trained neural network 24) with subsequent patients as shown in block 26.
[0049] In some cases, a neural network can include an ensemble of neural networks. A neural network can include a CNN (Convolutional Neural Network) with transformers. In some cases, a neural network can include a multilayer neural network. A multilayer neural network can, for example, include a hemodynamic term in its loss function.
[0050] Figure 2B shows details of method 34 for training the neural network. Multiple extravascular image datasets are provided to the neural network as shown in block 34a. Multiple intravascular image datasets are provided to the neural network as shown in block 34b, each intravascular image dataset containing intravascular image data showing a portion of a vessel from a start to an end position, and each intravascular image dataset is colregistrated with a corresponding extravascular image dataset from the multiple extravascular image datasets. At least some of the multiple intravascular image datasets provided during the training of the neural network include intravascular ultrasound data. At least some of the multiple intravascular image datasets provided during the training of the neural network include optical coherence tomography data.
[0051] As shown in block 34c, multiple hemodynamic datasets are provided to the neural network, and each hemodynamic dataset is colregistrated with a corresponding extravascular image dataset from among multiple extravascular image datasets. As shown in block 34d, the neural network uses the provided multiple intravascular image datasets and multiple provided hemodynamic datasets to learn which hemodynamic data are expected for a given intravascular image dataset, each colregistrated with a corresponding extravascular image dataset, thereby creating a trained neural network. In some cases, at least some of the multiple hemodynamic datasets provided during the training of the neural network consist of blood pressure data obtained by an arbitrary congestion index or non-congestion index.
[0052] In some cases, at least some of the extravascular image datasets provided during the training of the neural network include fluorescence fluoroscopy image data. At least some of the extravascular image datasets provided during the training of the neural network may include angiography image data. The angiography data may include, for example, two-dimensional angiography image data and / or three-dimensional angiography image data. In some cases, at least some of the angiography data may be 3D This may include CTA (3D computed tomography angiography).
[0053] In some cases, at least some of multiple intravascular image datasets and at least some of the corresponding hemodynamic datasets can be co-registered using their corresponding points in 2D or 3D space on the corresponding extravascular image datasets. In some cases, at least some of the multiple intravascular image datasets provided during the training of a neural network include quantitative data such as luminal boundaries, vascular boundaries, side branch boundaries, blood speckle density, and cardiac cycle parameters, which are used when training the neural network.
[0054] Figure 2C provides details of a method 36 for using a trained neural network (e.g., trained neural network 24) with subsequent patients. As shown in block 36a, an intravascular imaging operation is performed in which an intravascular imaging element is moved from a start position to an end position within the patient's blood vessel to generate one or more intravascular images. As shown in block 36b, the trained neural network uses its training to predict hemodynamic values corresponding to one or more intravascular images from the intravascular imaging operation. As shown in block 36c, one or more intravascular images are output in combination with the predicted hemodynamic values.
[0055] In some cases, one or more intravascular images from an intravascular imaging operation include anatomical landmarks, and the predicted hemodynamic values include predicted blood pressure values adjacent to these anatomical landmarks. In some cases, multiple intravascular image datasets (used to train a neural network) may include indications of important arterial locations such as proximal reference, minimum lumen, and distal reference, and one or more intravascular images from an intravascular imaging operation include these important locations. In some cases, the predicted blood pressure values include predicted blood pressure values adjacent to these important locations.
[0056] In some cases, outputting one or more intravascular images in combination with predicted hemodynamic values may include displaying one or more intravascular images and predicted hemodynamic values on the graphical user interface of the signal processing unit. Displaying one or more intravascular images and predicted hemodynamic values on the graphical user interface of the signal processing unit may include displaying a fully triregistered display of predicted hemodynamic values together with the intravascular images. In some cases, displaying one or more intravascular images and predicted hemodynamic values on the graphical user interface of the signal processing unit may include displaying a fully triregistered display of predicted hemodynamic values together with the intravascular images and corresponding extravascular images.
[0057] Figure 3 is a flowchart illustrating an exemplary method 38 for processing image data. Method 38 includes providing a plurality of intravascular image datasets to a neural network (such as neural network 12), each intravascular image dataset containing intravascular image data showing a portion of a vessel, colregistered with extravascular image data from a corresponding extravascular image dataset, from a start position to an end position, as shown in block 40. At least some of the plurality of intravascular image datasets may include intravascular ultrasound data. At least some of the plurality of intravascular image datasets may include optical coherence tomography data. At least some of the plurality of extravascular image datasets may include fluorescence fluoroscopy image data. At least some of the plurality of extravascular image datasets may include angiography image data.
[0058] Multiple hemodynamic datasets are provided to the neural network, each hemodynamic dataset containing hemodynamic data from a corresponding portion of a vessel, colregistered with the corresponding extravascular image from the corresponding extravascular image dataset, from a start position to an end position, as represented by one of the multiple intravascular image datasets, as shown in Block 42. At least some of the multiple hemodynamic datasets may contain blood pressure data obtained by any congestion index or decongestion index. As shown in Block 44, the neural network is trained by using the provided intravascular image datasets and the corresponding provided hemodynamic datasets to learn which hemodynamic data is expected for a given intravascular image dataset from the colregistration of each dataset to the same extravascular image.
[0059] Method 38 includes performing an intravascular imaging operation on a new patient, as shown in block 46, in which an imaging element is moved within a blood vessel from a starting position to an ending position to generate one or more intravascular images. As shown in block 48, a neural network uses its training to predict hemodynamic values corresponding to one or more intravascular images from the intravascular imaging operation. As shown in block 50, one or more intravascular images are output in combination with the predicted hemodynamic values.
[0060] Figure 4 is a flowchart illustrating an exemplary method 52 for processing patient image data. Method 52, as shown in block 54, involves acquiring intravascular image data from an intravascular imaging device, which includes imaging operations in the course of a kinetic procedure in which an imaging element is moved within a blood vessel from a start position to an end position, and the intravascular image data includes one or more intravascular images. As shown in block 56, one or more intravascular images are input into a trained neural network (e.g., trained neural network 24) to determine a predicted blood pressure measurement for each of the one or more intravascular images. As shown in block 58, a series of intravascular blood pressure values corresponding to the intravascular position of each of the one or more extravascular images are calculated. As shown in block 60, a blood pressure ratio is calculated based on the series of blood pressure values.
[0061] In some cases, method 52 may further include outputting intravascular image data and calculated blood pressure corresponding to intravascular points, as shown in block 62. In some cases, method 52 may further include acquiring extravascular image data including one or more extravascular images, as shown in block 64, and colregistrating the intravascular image data with the extravascular image data to determine the intravascular location of each of the one or more extravascular images. For example, acquiring extravascular image data may include acquiring extravascular image data corresponding to a vessel from a start position to an end position. In some cases, method 52 may further include outputting colregistrated extravascular image data in combination with the intravascular image data and calculated blood pressure points corresponding to intravascular points, as shown in block 66.
[0062] In some cases, intravascular imaging data includes intravascular ultrasound data. In some cases, intravascular imaging data includes optical coherence tomography data. Extravascular imaging data may include fluorescence fluoroscopy data, for example, or angiography data.
[0063] Figure 5 is a flowchart illustrating an exemplary method 68 for processing image data. Method 68 includes encoding physical features from IVUS frames from an IVUS pullback run that generates multiple IVUS frames, as shown in block 70. Physiology Resting Index (PRI) pullback data is collected, as shown in block 72. Image data from angiography acquisitions is collected, as shown in block 74. Angiography images are colregistrated with PRI pullback data, as shown in block 76. IVUS frames are colregistrated with angiography image data to colregistrate PRI pullback data with IVUS frames, as shown in block 78. A neural network is trained using the colregistrated IVUS frames, angiography image data, and PRI pullback data to predict PRI data based on subsequent IVUS pullback runs, as shown in block 80. New IVUS pullback run data, including multiple IVUS frames, is then provided to the neural network to calculate the predicted PRI measurement for each IVUS frame, as shown in block 82. In some cases, method 68 may further include co-registrating new IVUS pullback run data with the corresponding angiography run, as shown in block 84.
[0064] Figures 6-8 provide schematic diagrams of exemplary models that may be used when training the neural network 12. Figure 6 is a schematic diagram of model 86 that may be implemented within the neural network 12. Model 86 includes several inputs 86a, including but not limited to luminal boundaries, vascular boundaries, side branches, and blood speckle density. Inputs 86a are provided to the neural network block 86c via Nx1 86b. The neural network 86c outputs an iFR prediction 86d. Model 86 uses a loss function 86e. Model 86 integrates a PRI hemodynamic model as an additional term in the loss function to improve the accuracy of the PRI prediction unit. Model 86 accepts input as feature vectors such as derived luminal boundaries, vascular boundaries, side branches, blood speckle density, and cardiac cycle. The input feature vectors represent the variables of the hemodynamic PRI equation.
[0065] Figure 7 is a schematic diagram of a model 88 that can be implemented within the neural network 12. An IVUS (intravascular ultrasound) image 88a is provided to a CNN block 88b. An embedded patch is provided to a transformer block 88c. From there, the signal is passed to an MLP head 88e, yielding an IFR prediction 88f. Model 88 directly processes the IVUS image using a CNN and / or ViT to predict the PRI value.
[0066] Figure 8 schematically shows Model 90, which is a combination of Model 86 and Model 88. The outputs from Model 86 and Model 88 are provided to the averaging block 92. The output from the averaging block 92 is the final PRI 94. Model 90 provides a specific, accurate, efficient, real-time AI (artificial intelligence) model.
[0067] Figure 9 is a schematic diagram of an exemplary system 102 that may be used in connection with performing embodiments of the present disclosure by acquiring and co-registering extravascular image data (e.g., angiography / fluoroscopy) and intravascular image data (e.g., IVUS or OCT images). System 102 may include an extravascular imaging system / subsystem 104 (e.g., an angiography / fluoroscopy system) for acquiring / generating extravascular image data. System 102 may also include an intravascular imaging system / subsystem 106 (e.g., IVUS or OCT) for acquiring / generating intravascular image data. System 102 may include a computer system / subsystem 130 including one or more controllers or processors, memory and / or software configured to perform methods for vascular imaging registration of acquired extravascular image data and acquired intravascular image data.
[0068] Extravascular image data may be radiographic image data acquired by angiography / fluoroscopy system 104. Such angiography / fluoroscopy systems are generally well known in the art. The angiography / fluoroscopy system 104 may include an angiography table 110 which can be positioned to provide sufficient space for positioning an angiography / fluoroscopy unit C-arm 114 in an operating position relative to a patient 100 on the angiography table 110. Raw radiographic image data acquired by the angiography / fluoroscopy C-arm 114 may be passed to an extravascular data input port 118 via a transmission cable 116. The input port 118 may be a separate component or may be integrated into or part of a computer system / subsystem 130. The angiography / fluoroscopy input port 118 may include a processor that converts the raw radiographic image data received therefrom into extravascular image data (e.g., angiography / fluoroscopy image data) in the form of, for example, live video, DICOM, or a series of individual images. Extravascular image data may first be stored in memory within the input port 118, or it may be stored in the computer 130. If the input port 118 is a separate component from the computer 130, the extravascular image data may be transferred to the computer 130 via cable 117 and input into an input port in the computer 130. In some alternative configurations, communication between devices or processors may be performed via wireless communication rather than cable.
[0069] Intravascular imaging data may be, for example, IVUS data or OCT data acquired by an intravascular imaging system / subsystem 106 (e.g., an IVUS or OCT system). Such IVUS and OCT systems are generally well known in the art. The intravascular subsystem 106 may include an intravascular imaging device such as an imaging catheter 120, e.g., an IVUS or OCT catheter. The imaging device 120 is configured to be inserted into a patient 100 such that its distal end, including a diagnostic assembly or probe 122 (e.g., an IVUS or OCT probe), is near a desired imaging location in the blood vessel. A radiopaque material, i.e., a marker 123, located on or near the probe 122 may provide a mark of the current position of the probe 122 in the radiographic image.
[0070] For example, in the case of IVUS intravascular imaging, the diagnostic probe 122 generates ultrasound and receives ultrasound echoes representing a region adjacent to the diagnostic probe 122. The probe 122 or catheter 120 can convert the ultrasound echoes into corresponding signals, such as electrical or optical signals. The corresponding signals are transmitted along the length of the imaging catheter 120 to the proximal connector 124. The proximal connector 124 of the catheter 120 is communicatively coupled to a processing unit or control module 126. The IVUS version of the probe 122 can have various configurations, including single and multiple transducer element arrays. In the context of IVUS, it should be understood that transducers can be considered imaging elements. In the case of multiple transducer element arrays, the array of transducers may be arranged linearly along the longitudinal axis of the imaging catheter 120, curvilinearly around the longitudinal axis of the catheter 120, circumferentially around the longitudinal axis, etc.
[0071] An example of an IVUS intravascular imaging catheter 120 is shown in Figures 10 and 11. The imaging catheter 120 may include an elongated shaft 170 having a proximal end portion 172 and a distal end portion 174. A proximal hub or connector 124 may be coupled to the proximal end portion 172 or otherwise positioned adjacent to the proximal end portion 172. A tip member 176 may be coupled to the distal end portion 174 or otherwise positioned adjacent to the distal end portion 174. The tip member 176 may include a guidewire lumen, a non-traumatic distal end, one or more radiopaque markers, or other features. An imaging assembly 177 may be located within the shaft 170. Generally, the imaging assembly 177 (which may include an imaging probe 122 containing an imaging element 182) may be used to capture / generate images of blood vessels. In some cases, the medical device may include devices or features similar to those disclosed in U.S. Patent Application Publication No. 2012 / 0059241 and U.S. Patent Application Publication No. 2017 / 0164925, the entire disclosure of which is incorporated herein by reference. In at least some cases, the medical device 120 may include features similar to, or similar to, the OPTICROSS® imaging catheter commercially available from Boston Scientific (Marlborough, MA).
[0072] As shown in Figure 11, the imaging assembly 177 may include a drive cable or shaft 178 and an imaging probe 122 or transducer 182 including a housing 180 and an imaging element. The imaging probe 122 or housing 180 may be coupled to the drive cable 178. The transducer 182 may be rotatable or axially movable relative to the shaft 170. For example, the drive cable 178 may be rotated or moved to rotate or move the transducer 182. The probe 122 or housing 180 may include, or be made of, a radiopaque material or marker 123, and may provide a mark of the current position of the probe 122 in the radiographic image.
[0073] Referring back to Figure 9, as another example, the device 120 could be an OCT catheter used to collect OCT intravascular data. The OCT catheter 120 may include a diagnostic probe 122 that generates or propagates a beam of light directed towards the tissue, a portion of which is collected from subsurface features and represents a region adjacent to the diagnostic probe 122. In OCT, the diagnostic probe 122 includes an optical imaging device for light delivery and collection. It should be understood that in the context of OCT, the optical imaging device within the probe 122 can be considered an imaging element. Using a technique called interferometry, the optical path length of the received photons can be recorded, and most photons that scatter multiple times before detection can be removed. Thus, OCT can construct an image of a thick sample by collecting light directly reflected from the surface of the sample while removing background signals. The probe 122 or catheter 120 can transmit optical or optical signals along its shaft, or convert optical signals into corresponding signals such as electrical or optical signals that can be transmitted along the length of the imaging catheter 120 to a proximal connector 124. The proximal connector 124 of the catheter 120 is communicatively coupled to a processing unit or control module 126. The probe 122 or housing 180 may include or be made of radiopaque material or a marker 123, and may provide a mark of the current position of the probe 122 in a radiographic image.
[0074] Raw intravascular image data (e.g., raw IVUS or OCT data) may be acquired by the imaging catheter 120 and passed to the control module 126, for example, via the connector 124. The control module 126 may be a separate component, or it may be integrated into or part of the computer system / subsystem 130. The control module 126 may include a processor that converts, or is configured to convert, the raw intravascular image data received via the catheter 120 into intravascular image data (e.g., IVUS or OCT image data) in the form of, for example, live video, DICOM, or a series of individual images. The intravascular image data may include cross-sectional images of vascular segments. In addition, the intravascular image data may include longitudinal cross-sectional images corresponding to slices of vascular tissue taken along the length of the vessel. The control module 126 may be considered an input port for the computer system / subsystem 130, or it may be considered to be connected to an input port of the computer 130, for example, via cable 119 or wireless connection. Intravascular image data can first be stored in the memory of the control module 126, or in the memory of the computer system / subsystem 130. If the control module 126 is a separate component from the computer system / subsystem 130, the intravascular image data can be transferred to the computer 130, for example, via cable 119, and then transferred into an input port within the computer 130. Alternatively, communication between devices or processors can be performed via wireless communication instead of cable 119.
[0075] The control module 126 may also include one or more components that can be configured to operate the imaging device 120 or to control the acquisition of intravascular imaging data. For example, in an IVUS system, the control module 126 may include one or more of a processor, memory, pulse generator, motor drive unit, or display. As another example, in an OCT system, the control module 126 may include one or more of a processor, memory, light source, interferometer, optical system, motor drive unit, or display. In some cases, the control module 126 may be or may include a motor drive unit configured to control the movement of the imaging catheter 120. Such a motor drive unit may control the rotation or movement of the imaging catheter 120 or its components. In some cases, the control module 126 or motor drive unit may include an automated movement system that can be configured to move the imaging catheter 120 within a controlled / measured object in a patient 100. Such an automated movement system may be used during the movement procedure to move the imaging catheter 120 (including the imaging element) within the blood vessel from a starting position to an ending position at a constant or known speed. (For example, the imaging catheter 120 is moved at a specific speed over a known amount of time.) In other embodiments, the movement may be performed manually. The movement procedure may be, for example, a “pull-back” procedure (the catheter 120 is pulled through the blood vessel) or a “push-through” procedure (the catheter 120 is pushed through the blood vessel). The control module 126 may also consist of, or include, hardware and software configured to control intravascular imaging and data acquisition. For example, the control module 126 may include control features for turning imaging to / from the catheter 120 or data acquisition to the catheter 120 on / off.
[0076] The computer system / subsystem 130 may include one or more controllers or processors, one or more memories, one or more input ports, one or more output ports, and / or one or more user interfaces. The computer 130 is configured to acquire intravascular image data from or through the intravascular imaging system / subsystem 106 (e.g., IVUS or OCT) and extravascular image data from or through the extravascular imaging system / subsystem 104 (e.g., angiography / fluoroscopy system). The computer 130 or its components may include software and hardware designed to be integrated into standard catheterization procedures and to automatically acquire both extravascular image data (e.g., angiography / fluoroscopy) and intravascular image data (e.g., IVUS or OCT) by image or video acquisition.
[0077] The computer system / subsystem 130 or its components may include software or hardware configured to perform a method for vascular imaging coregistration of acquired extravascular and intravascular image data. In that context, the computer 130 may include computer-readable instructions or software for performing a method for vascular imaging coregistration as disclosed herein. For example, in some respects, the computer may include a processor or memory containing software that includes program code causing the computer to perform a method for vascular imaging coregistration as disclosed herein. For example, the computer / computing device may include a processor or memory containing instructions that can be executed by the processor to perform a method for vascular imaging coregistration as disclosed herein. In that context, computer-readable media storing program code in a non-temporary state for use by the computer / computing device 130 is also disclosed herein, and it should be understood that the program code causes the computing device 130 to perform a method for vascular imaging coregistration as disclosed herein. In addition, the computer / computing device 130 may be part of, or include, a system for intravascular imaging registration, which includes one or more input ports for receiving image data, one or more output ports, and a controller that communicates with the input ports and output ports and is configured to perform a method for intravascular imaging registration as disclosed herein.
[0078] The computer system / subsystem 130 may also include software and hardware configured to render or display imaging, including, for example, extravascular or intravascular imaging derived from received image data or a coregistration method. In some cases, the computer 130 or software may be configured to render both extravascular and intravascular imaging on a single display. In this regard, the system may include a display 150 configured to simultaneously display extravascular and intravascular image data rendered by the computer 130. The display 150 may be part of the computer system 130, or it may be a separate component that communicates with the computer system 130, for example, via an output port on the computer 130 and a transmission cable 121. However, in some other cases, communication via the output port may be wireless rather than via cable. In some cases, the computer 130 or the display 150 may be configured to simultaneously provide angiographic images, IVUS cross-sectional images, and IVUS longitudinal images, all of which may or may not be simultaneously and coregistrated. In other examples, the display may be configured to simultaneously provide angiographic images, OCT cross-sectional images, and OCT longitudinal images, which may or may not be simultaneously and col-registrated.
[0079] The computer system / subsystem 130 may also include one or more additional output ports for transferring data to other devices. For example, the computer may include output ports for transferring data to a data archive or memory 131. The computer system / subsystem 130 may also include a user interface which may include software and hardware configured to allow an operator to use or interact with the system.
[0080] The components of system 102 may be used collaboratively during a vascular imaging method or procedure involving the acquisition of extravascular and intravascular image data during a mobile procedure. In situations where such a procedure is performed and the necessary image data is acquired, exemplary methods for intravascular imaging registration may be performed.
[0081] For example, patient 100 may be positioned on a table 110 for extravascular imaging of a portion of a vessel of interest. Patient 100 or the table may be arranged or adjusted to provide a desired view of the vessel of interest in preparation for the acquisition of extravascular imaging data. In addition, an intravascular imaging catheter 120 may be introduced into a portion of the vessel of interest in preparation for a transfer procedure to acquire intravascular imaging data. The intravascular imaging catheter 120 may be navigated and positioned within the vessel (often under fluoroscopy) so that the imaging element is positioned at a desired starting position for the transfer procedure. A guide catheter may be used to assist navigation. Once positioned appropriately, the transfer procedure may be performed or carried out. The necessary extravascular and intravascular imaging data can be obtained before or during the transfer procedure. In this situation, or as part of this process, exemplary methods for vascular imaging coregistration or registration may be performed or carried out.
[0082] Further details relating to coregistration of intravascular image data with extravascular image data can be found in U.S. Patent Application No. 63 / 157,427, filed on 5 March 2021, which is incorporated herein by reference in its entirety.
[0083] In some cases, hemodynamic data may include blood pressure data. For example, fractional flow reserve (FFR) data can be obtained, comparing blood pressure measured in the aorta to blood pressure measured elsewhere, such as in the coronary arteries. If there is no obstruction or other obstruction to blood flow through the coronary arteries, blood pressure measured in the coronary arteries is expected to be the same as blood pressure measured in the aorta. FFR can be considered the ratio of the two blood pressure values. If the ratio is less than 1, this means that the blood pressure in the coronary artery currently being examined is lower than the aortic pressure. This may indicate an obstruction or other impairment to blood flow in that particular coronary artery. In some cases, hemodynamic data, such as FFR (fractional flow reserve) data, can be colregistrated with extravascular imaging data, such as angiography data. Intravascular imaging data, such as IVUS (intravascular ultrasound), can be colregistrated with the same extravascular imaging data to obtain both hemodynamic and intravascular imaging data for each location of interest within the extravascular imaging data.
[0084] It should be understood that this disclosure is illustrative in many respects. Modifications can be made in detail, particularly with respect to shape, size, and process configuration, without exceeding the scope of this disclosure. This may include, to a suitable extent, using any feature of one exemplary embodiment in other embodiments. The scope of the invention is, of course, defined in the language in which the appended claims are expressed.
Claims
1. The process includes training a neural network, and training the neural network involves Providing multiple extravascular image datasets to the neural network, The method involves providing the neural network with multiple intravascular image datasets, each intravascular image dataset containing intravascular image data showing a portion of a blood vessel from a starting position to an ending position, and each intravascular image dataset being correlated with a corresponding extravascular image dataset from the multiple extravascular image datasets. The method involves providing the neural network with multiple hemodynamic datasets, wherein each hemodynamic dataset is correlated with the corresponding extravascular image dataset among the multiple extravascular image datasets. The neural network, using the provided plurality of intravascular image datasets and the provided plurality of hemodynamic datasets, each correlated with the corresponding extravascular image dataset, learns which hemodynamic data are expected for a given intravascular image dataset and thereby creates a trained neural network. This method comprises using the trained neural network with subsequent patients, and using the trained neural network with subsequent patients is To generate one or more intravascular images, an intravascular imaging operation is performed in which an intravascular imaging element is moved from a starting position to an ending position within the patient's blood vessel, The trained neural network uses its training to predict hemodynamic values corresponding to one or more intravascular images from the intravascular imaging operation. Outputting one or more intravascular images in combination with the predicted hemodynamic values, A method for evaluating patient hemodynamic data, comprising the following features.
2. The method according to claim 1, wherein at least some of the plurality of hemodynamic datasets provided in the process of training the neural network consist of blood pressure data obtained by any congestion index or non-congestion index.
3. The method according to claim 1 or 2, wherein at least some of the plurality of intravascular image datasets and at least some of the corresponding hemodynamic datasets are co-registered using their corresponding points in a 2D or 3D space on the corresponding extravascular image dataset.
4. The method according to any one of claims 1 to 3, wherein the neural network comprises one or more of the following: an ensemble of neural networks, a CNN (convolutional neural network) having transformers, or a multilayer neural network.
5. At least some of the multiple intravascular image datasets provided during the training of the neural network include quantitative data such as luminal boundaries, vascular boundaries, side branch boundaries, blood speckle density, and cardiac cycle parameters. The aforementioned quantitative data is used when training the neural network. The method according to any one of claims 1 to 4.
6. The one or more intravascular images from the intravascular imaging operation include anatomical landmarks. The predicted hemodynamic values include predicted blood pressure values close to the anatomical landmarks. The method according to any one of claims 1 to 5.
7. The method according to any one of claims 1 to 6, wherein outputting one or more intravascular images in combination with predicted hemodynamic values is further comprising displaying the one or more intravascular images and the predicted hemodynamic values on the graphical user interface of the signal processing unit.
8. The method according to claim 7, wherein displaying one or more intravascular images and predicted hemodynamic values on the graphical user interface of a signal processing unit is further comprising displaying a fully correlated and predicted hemodynamic value together with the intravascular image.
9. The method according to claim 7, wherein displaying one or more intravascular images and predicted hemodynamic values on the graphical user interface of a signal processing unit includes displaying a fully tri-registered display of the predicted hemodynamic values together with the intravascular images and corresponding extravascular images.
10. The system provides multiple intravascular image datasets to a neural network, each intravascular image dataset containing intravascular image data representing a portion of a blood vessel, correlated with extravascular images from the corresponding extravascular image dataset, from a start position to an end position. The method comprises providing the neural network with multiple hemodynamic datasets, each hemodynamic dataset including hemodynamic data from a corresponding portion of the blood vessel, correlated with a corresponding extravascular image from the corresponding extravascular image dataset, from a start position to an end position, as represented by one of the multiple intravascular image datasets. The neural network, using a provided intravascular image dataset and the corresponding provided hemodynamic dataset derived from the coregistration of each dataset for the same extravascular image, learns which hemodynamic data are expected for a given intravascular image dataset, thereby training the neural network. The system includes performing an intravascular imaging operation on a new patient in which an imaging element is moved from a starting position to an ending position within a blood vessel in order to generate one or more intravascular images. The neural network comprises using its training to predict hemodynamic values corresponding to one or more intravascular images from the intravascular imaging operation, The system includes outputting one or more intravascular images in combination with the predicted hemodynamic values. A method for processing image data.
11. The system includes acquiring intravascular image data from an intravascular imaging device, the acquisition including imaging operations during a procedure in which the intravascular imaging element is moved from a starting position to an ending position within a blood vessel, and the intravascular image data includes one or more intravascular images. The method comprises inputting the one or more intravascular images into a trained neural network in order to determine a predicted blood pressure measurement for each of the one or more intravascular images, The system includes calculating a series of intravascular blood pressure values corresponding to the intravascular position of each of the one or more extravascular images. The system includes calculating a blood pressure ratio based on the aforementioned series of blood pressure values. A method for processing patient image data.
12. The intravascular image data and, Calculated blood pressure corresponding to a point in the blood vessel and The method according to claim 11, further comprising outputting
13. Acquiring extravascular image data, including one or more extravascular images, In order to determine the intravascular position of each of the one or more extravascular images, the intravascular image data is correlated with the extravascular image data. The method according to either claim 11 or 12, further comprising:
14. The method according to claim 13, further comprising outputting the coregistrated extravascular image data in combination with the intravascular image data and the calculated blood pressure points corresponding to the points within the blood vessel.
15. The method according to any one of claims 11 to 14, wherein acquiring extravascular image data includes acquiring extravascular image data corresponding to the blood vessel from the starting position to the ending position.