Patent Description:
The present invention relates to a method and system for selecting a two- or three-dimensional region of interest in an image, of particular but by no means exclusive application in applying artificial intelligence to the analysis of medical images, such as for morphometric measurement. The region of interest may be a 2D region or 3D volume in such medical images. Possible medical imaging applications include Computed Tomography (CT), Magnetic Resonance (MR), Ultrasound, and Pathology Scanner imaging.

A region of interest (ROI) relates to a definition of the borders of an object or part of an object under consideration, typically as that object (or part object) appears in an image, and is a concept commonly used in medical imaging applications. The ROI in a medical image is selected or identified for analysis or assessment. For example, the boundaries of a tumour may be defined on a mammography scan as the ROI, such as to measure the tumour's size; the endocardial border may be identified on a coronary CT calcium scan as the ROI, perhaps during different phases of the cardiac cycle, for example, end-systole and end-diastole, for the purpose of assessing cardiac function; the femur neck may be identified as the ROI on a hip DXA scan for calculating the bone mineral density; the distal radius bone ROI may be selected on a wrist CT scan for assessing bone microstructure.

The selection of the ROI is important in medical image analysis, so that the clinically relevant region is identified for clinical analysis. For example, the distal region of a radius bone may be selected for bone microstructure assessment; inappropriate region selection can lead to an invalid assessment of bone microstructure. If a ROI is selected that is too proximal, the region will include too little trabecular tissue; if a ROI is selected that is too distal, the region will include too thin a cortex.

Also, in some diagnostic analyses, quantitative analysis of selected ROI needs to be compared to the reference values, which are calculated from large data samples. Inaccurate ROI selection makes such a comparison invalid. Precise region of interest selection in medical imaging is required for monitoring a disease or a treatment. If the ROI's selection is not precise and reproducible, different ROIs of the same patient during different visits will be analysed and compared, and the efficacy of a treatment regime may be compromised.

A ROI may be selected manually or semi-manually. The manual methods require the operators to draw contours of a ROI based on predefined rules. For example, <CIT> describes a method of selecting a femoral neck from hip images in bone densitometry. That patent discloses a femoral neck box, with a width and length of <NUM> × <NUM>, centred on a new coordinate system with its width (<NUM>) parallel to an x-axis (or femoral midline). The user may move the femoral neck box along and perpendicular to the femoral midline and is instructed to place the corner of the femoral neck box against the bone edge of the greater trochanter. Further, the user is instructed to reduce the width of the femoral neck box if the femoral neck is very short.

Some known systems include semi-manual ROI selection. Such semi-manual methods usually require the operator to give some initial input, based on which the ROI is identified and selected. For example, XtremeCT (TM) (a high resolution peripheral quantitative computed tomography system provided by Scanco Medical AG, of Brüttisellen, Switzerland) requires operators to select a ROI to be scanned. The operator first acquires a 2D anterior-posterior projection of the proximal limb. On the 2D projection image, the operator visually identifies an anatomic landmark and manually intersects it with a horizontal reference line. From the reference line, the anatomic volume to be scanned is offset by a standard distance.

However, both manual and semi-manual methods are labour intensive and tedious, and ROI selection varies within and between operators. The variability in ROI selection is of great concern in cross-sectional or observational multicentre studies, and when pooling cross-sectional datasets for retrospective analyses (where multiple operators may have been involved in data collection). Moreover, selecting an ROI based on heuristic rules is another problem: ROI selection for assessment should include consideration of clinical implications, but heuristic rules-based selection may produce inferior clinical easement. For example, as described above, the femoral neck is defined as a fixed size box and the volume of the wrist to be scanned is selected based on a fixed distance. Either femoral neck or distal wrist volume selection is used to characterize an individual patient's skeletal status. Human femur bones vary in size, hence so do femoral necks. A fixed-size box can include other musculoskeletal material, such as muscle or adipose tissue, in patients with small femur bones, while covering only part of the femoral neck for patients with big femur bones. The wrist volume to be scanned is selected by a fixed distance from an anatomic landmark. However, bone morphology can vary markedly along the bone axis. Hence, in these techniques, comparisons between the microstructure assessments of patients with different bone length will commonly lead to no clinically helpful conclusion.

Another existing method of ROI selection involves co-registration. For example, one voxel-based morphometry method of brain MRI data involves firstly spatially normalizing all the subjects' scans to the same stereotactic space. This includes registering each of the images of the same template image by minimizing the residual sum of squared differences between them. The grey matter (corresponding to the ROI) is then selected from the normalized images; smoothing is applied, and finally a statistical analysis is performed to localize the group differences. This method selects a ROI with a consideration of brain morphometry. However, this method is mainly used in the group comparison studies; it is rarely used for single subjects, because registering every brain scan to the same template will remove the differences in brain anatomy among people.

Registration is also used to improve the ROI selection prevision during patient monitoring. The analysis of identical ROIs between repeated CT scans is important in monitoring changes in bone microarchitecture. In longitudinal studies, 3D registration is used to select the same ROI; this involves rotating and translating follow-up scans (such as second and third scans) to the coordinates of the first scan (or reference image). The registration procedure can select the ROIs of baseline and follow-up scans precisely for the same subject. However, in most diagnostic analysis, the measurement of the patient is compared to reference data calculated from a large population. The registration method cannot solve the problem of sub-optimal ROI selection between different subjects.

<CIT>) discloses a method of predicting bone or articular disease in a subject includes determining one or more micro-structural parameters, one or more macroanatomical parameters or biomechanical parameters of a joint in the subject and combining at least two of the parameters to predict the risk of bone or articular disease.

<CIT> discloses a method of adapting a presentation of ultrasonographic images during an ultrasonographic foetal evaluation, and comprises analysing ultrasonographic images captured during an evaluation of a foetus, identifying the location of an anatomical landmark of a reference organ, tissue or body fluid of the foetus in the images based on the outcome of the analysis, localizing a region of interest in at least some of the images by using a predefined locational anatomical property of the anatomical landmark, and concealing the ROI in a presentation of the images during the evaluation. At least one anatomical landmark is imaged in the presentation and not concealed by the ROI.

<NPL>), disclose the use of high-resolution peripheral quantitative computed tomography to assess bone microstructure at the distal radius in growing children and adolescents. The authors examined forearm radiographs from children to locate the position of the ulnar and radial growth plates, and HR-pQCT to assess bone microstructure in a region of interest at the distal radius that excluded the growth plate (as determined from the radiographs) in the children.

<NPL>), disclose a 3D computed tomography (CT) scanning and image analysis method for measuring trabecular and integral bone mineral density (SMD) and geometry in automatically determined femoral-neck and trochanteric subregions of the proximal femur. The authors measured the correlation of the density and geometry variables to femoral strength assessed in vitro under loading simulating a single-limb condition and a fall to the side.

<CIT> discloses the preparation of templates for observing microstructural features of bones in order to assess bone quality. In some implementations, the microstructural site can be a femoral neck or a greater trochanter.

According to a first aspect of the invention, there is provided a computer-implemented method for selecting one or more regions of interest (ROIs) in an image, as claimed in claim <NUM>.

In an embodiment, performing the reference morphometrics further comprises measuring basic morphometrics on the objects by reference to the detected landmarks and determining the reference morphometrics based on the measured basic morphometrics. For example, determining the reference morphometrics may comprise employing one or more trained deep learning reference morphometric models.

In an embodiment, the selecting of the one or more ROIs from the objects according to the reference morphometries further comprises determining the shape and size of the ROIs.

In an embodiment, the method further comprises segmenting the objects from the image.

In an example, segmenting the objects comprises generating masks of the respective segmented objects. Segmenting the objects may employ one or more trained machine learning segmentation models. In an example, the method comprises performing a plurality of segmentations.

In an embodiment, the method further comprises preparing the image for segmentation by pre-processing the image. For example, pre-processing the image may comprise applying a Gaussian blur function to the image to reduce noise, and/or applying histogram equalization to enhance contrast of the image.

In an embodiment, the method further comprises normalizing the objects before performing the morphometrics on the objects. For example, normalizing the objects may comprise coordinate transformation.

In an embodiment, the method may further comprise determining density of one or more of the selected ROIs using attenuation of a referent material (comprising, for example, an adjacent tissue such as muscle or fat, or a calibration phantom).

According to a second aspect of the invention, there is provided a system for selecting one or more regions of interest (ROIs) in an image, as claimed in claim <NUM>.

In an embodiment, the morphometer is configured to perform the reference morphometrics by measuring basic morphometrics on the objects by reference to the detected landmarks and to determine the reference morphometrics based on the measured basic morphometrics. For example, the morphometer may be further configured to determine the reference morphometrics by employing one or more trained deep learning reference morphometric models.

In an embodiment, the region selector is further configured to determine the shape and size of the ROIs relative to the reference morphometries.

In an embodiment, the system further comprises a segmenter configured to segment the objects from the image. In an example, the segmenter is further configured generate masks of the respective segmented objects. The segmenter may employ one or more trained machine learning segmentation models to segment the objects.

In an embodiment, the system further comprises an image pre-processor configured to prepare the image for segmentation by pre-processing the image. In an example, the pre-processor is configured to reduce noise by applying a Gaussian blur function to the image, and/or to enhance contrast of the image by applying histogram equalization to the image.

In an embodiment, the system further comprises a normalizer configured to normalize the objects before morphometrics are performed on the objects. In one example, the normalizer normalizes the objects by coordinate transformation.

In an embodiment, the system further comprises a density determiner configured to determine density of one or more of the selected ROIs using attenuation of a referent material.

According to a third aspect of the invention, there is provided a computer program, comprising program code configured to, when executed by one or more processors, implement the method for selecting a region of interest (ROI) in an image of the first aspect. This aspect also provides a computer-readable medium, comprising such a computer program.

It should be noted that any of the various individual features of each of the above aspects of the invention, and any of the various individual features of the embodiments described herein including in the claims, can be combined as suitable and desired.

In order that the invention may be more clearly ascertained, embodiments will now be described by way of example with reference to the following drawing, in which:.

<FIG> is a schematic view of a segmentation system <NUM> according to an embodiment of the present invention.

Referring to <FIG>, system <NUM> comprises an ROI ('region of interest') selection controller <NUM> and a user interface <NUM> (including a GUI <NUM>). User interface <NUM> typically comprises one or more displays (on one or more of which may be displayed the GUI <NUM>), a keyboard and a mouse, and optionally a printer. ROI selection controller <NUM> includes at least one processor <NUM> and a memory <NUM>. System <NUM> may be implemented, for example, as a combination of software and hardware on a computer (such as a personal computer or mobile computing device), or as a dedicated ROI selection system. System <NUM> may optionally be distributed; for example, some or all of the components of memory <NUM> may be located remotely from processor <NUM>; user interface <NUM> may be located remotely from memory <NUM> and/or from processor <NUM>.

Memory <NUM> is in data communication with processor <NUM>, and typically comprises both volatile and non-volatile memory (and may include more than one of each type of memory), including RAM (Random Access Memory), ROM and one or more mass storage devices.

As is discussed in greater detail below, processor <NUM> includes an image processor <NUM>, a segmenter <NUM>, an object and anatomical landmarks identifier <NUM>, a normalizer <NUM>, a morphometer <NUM> (which includes a reference morphometric determiner <NUM>), an ROI (region of interest) selector <NUM>, an optional index determiner <NUM>, an optional density determiner <NUM>, an I/O interface <NUM> and a results output <NUM>. Memory <NUM> includes program code <NUM>, image store <NUM>, trained segmentation model <NUM>, object and anatomical landmark identification models <NUM>, morphometrics settings <NUM>, reference morphometric models <NUM>, and ROI selection settings <NUM>. ROI selection controller <NUM> is implemented, at least in part, by processor <NUM> executing program code <NUM> from memory <NUM>.

In broad terms, I/O interface <NUM> is configured to read medical images into image store <NUM> of memory <NUM> for processing. Once system <NUM> has completed processing, I/O interface <NUM> outputs the result to, for example, results output <NUM> and/or to GUI <NUM>. For example, I/O interface <NUM> may read CT scans in DICOM format into image store <NUM>. After processor <NUM> has processed the scans, the selected ROI or ROIs may be outputted, such as by being presented to a user, stored, or used for further analysis (or a combination of any of these).

Image processor <NUM> of processor <NUM> is configured to process images before segmentation. For example, processor <NUM> can remove noise in the input images or enhance the contrast of the input images. Processor <NUM> can also process images after segmentation. For example, processor <NUM> can process segmented objects to make subsequent morphometrics easier.

Segmenter <NUM> performs segmentation using trained segmentation model <NUM> which, in this embodiment, employs artificial intelligence-that is, machine learning algorithms such as a deep learning neural network. For different applications, different models are trained. For example, for segmenting a brain image from one or more MRI scans, segmentation model <NUM> may have been trained using deep convolutional neural networks with MRI scans as training data. Such training would involve experts annotating the brains on the scans; for segmenting radius bone from wrist CT scans, segmentation model <NUM> may have been trained using deep convolutional neural networks with annotated wrist CT scans as training data.

Morphometer <NUM> measures the objects according to morphometrics settings <NUM>. For different objects, different morphometrics are measured-the appropriate settings in each case being stored as morphometrics settings <NUM>. For example, the required morphometrics measurements of radius bone are different from those required for measurements of the femur bone. For the same object but a different ROI selection, different morphometrics measurements are required. For example, for femoral torch region selection from the hip DXA scan, only the neck axis and shaft axis need be measured; for femoral neck selection, femoral head centre and the femoral head tangent plane may also need to be measured.

ROI selector <NUM> selects an ROI from the segmented objects according to the morphometrics measurements and ROI selection settings <NUM>. For example, for selecting the femoral neck from a hip DXA scan, femoral neck box height may be defined as various percentages of the hip axis length for different study purposes.

<FIG> depicts schematically the general workflow <NUM> of system <NUM>. Referring to <FIG>, in step <NUM>, original images (such as in DICOM, TIFF or PNG format) are read into memory <NUM> of system <NUM>. Memory <NUM> is preferably configured to allow high-speed access of data by system <NUM>. For example, if system <NUM> is implemented as a combination of software and hardware on a computer (such as a personal computer), and the images may be read into RAM of memory <NUM>.

At step <NUM>, image processor <NUM> pre-processes the loaded images if required or desired. This prepares the images for the segmentation, so as to improve the results of segmentation (including to make those results satisfy a desired quality threshold). For example, the pre-processing may include applying a Gaussian blur function to an image to reduce noise, or include applying histogram equalization to enhance image contrast, or both.

At step <NUM>, segmenter <NUM> segments objects of interest from the images, including-if desired-generating a mask of the segmented object. In this embodiment, segmentation model <NUM> is generally used for segmentation. For different objects, different machine learning models are trained. For example, different models are trained for segmenting brain from MRI scan and segmenting radius bone from wrist CT scan, respectively. Machine learning such as deep learning models are used to achieve accurate segmentation. However, in other embodiments, objects of interest are alternatively segmented using more conventional image processing algorithms, such as contour detection or blob detection, which in some applications may be acceptably accurate.

Furthermore, this step may include more than one segmentation (such as segmenting bone material from surrounding soft tissue, then segmenting one or more particular bones from the bone material). In such instances, different segmentation techniques may be employed in each segmentation, such as a pre-trained segmentation model <NUM> in the first segmentation and more conventional image processing method in the second segmentation (or vice versa), or two pre-trained segmentation models (one for each of the segmentation steps).

At step <NUM>, the object or objects of interest, obtained by segmentation, and then relevant anatomical landmarks of the objects, are recognized and identified by object and anatomical landmarks identifier <NUM>. For example, if segmenter <NUM> has segmented-from surrounding material in the image-the radius and ulna at this step the radius bone will be recognized and identified, then-for example-the radial head, styloid process, and ulnar notch will be recognized and identified. The identified anatomical landmarks will be later used for morphometric measurement.

The objects and anatomical landmarks are identified by pre-trained deep learning models, stored in object and anatomical landmark identification models <NUM>.

At step <NUM> (which is optional in this embodiment), normalizer <NUM> normalizes segmented objects to facilitate subsequent morphometrics. Normalization typically comprises coordinate transformation, especially for 3D scans. Objects are segmented from images that are presented in an image coordinate system, while morphometrics are performed with respect to-for example-the anatomy. Thus, in the example of anatomy, transforming objects in the image coordinate system into the anatomical coordinate system simplifies morphometrics.

Next, the morphometrics themselves are conducted, as the automatic ROI selection is performed by referring to one or more clinically relevant morphometrics-referred to herein as reference morphometrics. While in some other cases the reference morphometrics can be measured directly, generally they are measured after segmentation and landmark detection.

For example, in a DXA hip scan, the hip length constitutes one reference morphometric, calculated from some basic morphometrics, which themselves are determined by referring to the detected landmarks. The calculation itself can be performed by any suitable (including conventional) image processing algorithm.

In another example, radius length is the reference morphometric, to which the ROI selector refers to select a bone volume for bone microstructure analysis. The radius length cannot be measured directly, as scanning the whole forearm is generally not feasible (owing to what would be an excessive radiation dose). Therefore, the basic morphometrics, such as the distal breadth, the diameter of mid-shaft, maximum distal head diameter and minimum distal head diameter, are first measured. In this embodiment, a deep learning model-pre-trained to predict the radius length on the basis of the aforementioned basic morphometrics-determines the radius length.

Thus, at step <NUM>, morphometer <NUM> determines basic morphometrics for the one or more segmented and identified objects, according to morphometrics settings <NUM>. For different objects and different requirements of ROI selection, different basic morphometrics are determined. Morphometer <NUM> is configured to implement image processing so as to make such measurements. Morphometer <NUM> measures the desired basic morphometrics, such as of tangent line of femoral head, the neck axis, and the hip end line, by reference to the anatomical landmarks that were identified in step <NUM> by object and anatomical landmarks identifier <NUM>. For example, for femoral neck ROI selection from a hip DXA image, morphometer <NUM> would employ anatomical landmarks such as the femoral head tangent, femoral head centre, neck axis and shaft axis.

Some reference morphometrics may, in some applications, be measured directly. For example, if the radius distal breadth is chosen as the reference morphometric, it may be measured directly by referring to detected landmarks. In such situations, morphometer <NUM> measures the required one or more reference morphometrics, without requiring the use of reference morphometric determiner. That is, the reference morphometric are the basic morphometrics.

However, this is generally not so, so in most cases the reference morphometrics are calculated based on the basic morphometrics by reference morphometric determiner <NUM>. This is done at step <NUM>. For example, in a hip DXA scan, reference morphometric determiner <NUM> may calculate the hip length by constructing a line between the vertex point of the femoral head and centre point of the last slice of shaft bone (both points having been identified in step <NUM>), then calculating the line's length. The line construction may be performed using any suitable image processing algorithm.

Reference morphometric determiner <NUM> of this embodiment, however, has the ability to determine reference morphometrics using one or more pre-trained deep learning reference morphometric models <NUM>. As discussed above, a deep learning reference morphometric model may be trained to predict (in this example) the radius bone length based on the measurements of distal breadth, diameter of mid-shaft, maximum distal head diameter and minimum distal head diameter (being basic morphometrics measured in step <NUM>). Hence, reference morphometric determiner <NUM> of this embodiment can determine the radius bone length (the reference morphometric in that example) using this deep learning reference morphometric model <NUM>, based on an analysis of the distal portion only of the subject's forearm.

Next, ROI selector <NUM> selects one or more ROIs from the objects for respective purposes, according to the ROI selection settings <NUM> and the reference morphometrics calculated at step <NUM>. ROI selector <NUM> performs ROI selection in two steps: at step <NUM>, ROI selector <NUM> identifies the location of each respective ROI, and at step <NUM>, ROI selector <NUM> determines the shape and size of the respective ROIs (whether in two- or three-dimensions). For example, for distal radius region selection, ROI selector <NUM> first identifies the location of the ROI as a percentage of the radius bone length from the radius distal tip, and ROI selector <NUM> then defines the thickness of the selected volume as another percentage of the radius bone length.

At step <NUM>, the results, comprising the selected ROI or ROIs, are outputted. This may entail passing these results to results output <NUM> for outputting to, for example, a user (for presentation to the user via, for example, a monitor of user interface <NUM>). Alternatively, this may entail passing these results to another system (such as via I/O interface <NUM>). In still a further alternative, this entails using the results as the input of further analysis, such as by the optional index determiner <NUM> or density determiner <NUM> (or both). Combinations of any of these are also envisaged.

Index determiner <NUM> is configured to use segmenter to segment the selected ROI(s) into different structures, and to calculate characterizing indices that characterize these structures. For example, after the selection of a bone volume ROI from a CT wrist scan, index determiner <NUM> might control segmenter <NUM> to further segment the selected ROI into cortex, transitional region, and trabecular region, then calculate indices (such as trabecular architecture and porosity) that characterize the segments. The segmentation and/or index determination may be performed using, for example, the approach described in <CIT> entitled "Method and system for image analysis of selected tissue structures".

Density determiner <NUM> is configured to determine the density of the selected ROI using the attenuation of a second material (such as muscle tissue or other adjacent material, or a calibration phantom of known density) as a referent, again using the approach described in <CIT>. The second material may be scanned by the same scanner to establish a formula for converting attenuation values to density values.

<FIG> and <FIG> illustrate the application of system <NUM> to the selection of an ROI in the form of a femoral neck region from a hip DXA image. <FIG> illustrates the morphometrics performed on the femur bone. <FIG> illustrate the intermediate results generated by system <NUM> at various steps of workflow <NUM>.

As shown generally at <NUM> in <FIG>, the tangent line (L1) of femoral head <NUM> is identified (after the femoral head and vertex point of the femoral head are recognized and identified during step <NUM>); the neck axis (L2) is identified that is the central line across the femoral neck; the shaft axis (L3) is identified that is the central line across the shaft bone; the minimum cross sectional line (L4) is identified that is the shortest line parallel to L1 and transverse the femoral neck; the hip end line (L5) is identified that passes through the intersection point between L2 and shaft bone and is parallel to L1; the axis intersection point(P1) is identified that is the intersection of the neck axis(L2) and the shaft axis(L3); the femoral head central point(P2) is identified;.

Based on the identified reference lines and points, the following morphometrics are measured by reference morphometric determiner <NUM>: the hip axis length (D1) is calculated as the distance between L1 and L5; the distance between the axis intersection point (P1) and the femoral head central point (P2) is calculated as D2; the distance between the femoral head central point (P2) and the minimum cross-sectional line (L4) is calculated as D3.

<FIG> is an original image <NUM> in the form of a hip DXA scan inputted into system <NUM> (cf. step <NUM>); <FIG> is an inverted version <NUM>' of image <NUM> (provided to assist naked-eye inspection and interpretation of <FIG> shows the result of the application of pre-trained (preferably deep learning) segmentation model <NUM> (cf. step <NUM>) by segmenter <NUM> to segment the femur bone from the image, and to generate a segmented mask <NUM> of the segmented object (in this example, the femur bone).

<FIG> shows the result of the morphometrics performed on the segmented femur bone (cf. step <NUM>). <FIG> shows at <NUM> the result of the selection of the femoral neck ROI by ROI selector34 (cf. steps <NUM> & <NUM>). The minimum cross-sectional line (L4 in <FIG>) is the central line of the region and the region width is selected as a percentage (in this example, <NUM>%) of the hip axis length (cf. D1 in <FIG>). (This percentage is configurable, and is stored in ROI selection settings <NUM>. ) The ROI selection may vary for different purposes or studies.

<FIG> shows at <NUM> the width of ROI selected to be <NUM>% of D2 (cf.

<FIG> and <FIG> illustrate the application of system <NUM> in selecting an ROI, in the form of a distal radius region, from a wrist CT image. <FIG> illustrates morphometrics performed on a radius bone. <FIG> illustrate the intermediate results generated at various steps of the ROI selection workflow <NUM>. (<FIG>, <FIG>, <FIG>, <FIG>, <FIG>, <FIG> are inverted versions of <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, respectively, and are again provided to assist naked-eye inspection and interpretation of <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, <FIG>.

As shown at <NUM> in <FIG>, radius distal breath (RDB) is measured as the distance from the most medial point of the ulnar notch to the most lateral point of the styloid process; radius length (RL) is measured as the distance from the most proximal end on the radial head to the tip of the styloid process.

<FIG> is an original image in the form of a wrist CT scan. <FIG> shows bones segmented by segmenter <NUM> (using pre-trained deep learning segmentation model <NUM>) from the surrounding tissues (cf. step <NUM>). <FIG> shows the radius bone as segmented by segmenter <NUM> (in this instance using a conventional connected component detection algorithm) from the other bones (cf. step <NUM>). <FIG> shows the segmented radius bone, transformed by normalizer <NUM> from the image coordinates to the radius anatomy coordinates (cf. step <NUM>). <FIG> shows the radius distal breath (the double arrow line) is measured. <FIG> shows the region of interest (dash line box) is selected. The selected ROI starts at a distance of RDB from the tip of the distal radius. The height of the region is selected as half of RDB. <FIG> is an image of the selected distal radius bone.

It is to be understood that, if any prior art is referred to herein, such reference does not constitute an admission that the prior art forms a part of the common general knowledge in the art in any country.

Claim 1:
A computer-implemented method for selecting one or more regions of interest in an image, the method comprising:
identifying (<NUM>) one or more objects of interest that have been segmented from the image (<NUM>); then
identifying (<NUM>) predefined landmarks of the objects; then
determining (<NUM>, <NUM>) reference morphometrics pertaining to the objects by performing morphometrics on the objects by reference to the landmarks; then
selecting (<NUM>, <NUM>) one or more regions of interest of the objects according to the reference morphometrics, comprising identifying the respective locations of the regions of interest relative to the reference morphometrics; and then
outputting (<NUM>) the selected one or more regions of interest;
characterized in that
- the image is a hip DXA image, the one or more objects of interest comprise a femur, the one or more regions of interest comprise a femoral neck region or a femoral trochanter region, and determining (<NUM>, <NUM>) reference morphometrics pertaining to the objects by performing morphometrics on the objects by reference to the landmarks comprises measuring the femoral neck axis and femoral shaft axis; or
- the one or more objects of interest comprise a radius bone, the one or more regions of interest comprise a distal radius region, and identifying the respective locations of the regions of interest relative to the reference morphometrics comprises identifying the location of a respective region of interest as a percentage of the radius bone length from the radius distal tip and then defining the thickness of a volume as a percentage of the radius bone length.