Patent Description:
The present application relates to the technical field of magnetic resonance imaging, and in particular to a superconducting magnetic resonance imaging system for extremity.

Magnetic resonance apparatus are currently core apparatus in the field of global medical imaging diagnosis. Most of the commonly used magnetic resonance apparatus on the market are whole-body <NUM>. 5T and <NUM>. 0T magnetic resonance apparatus. The whole-body magnetic resonance apparatus generally has disadvantages of large volume, heavy weight, large occupied area, high cost, and high maintenance cost. For example, the <NUM>. 0T apparatus weighs about <NUM> and occupies an area of about <NUM> square meters. In terms of imaging, limited by hardware performance, the imaging of small joints is not clear and the imaging speed is slow. In terms of the comfort level, it requires the whole body of the subject to enter the examination hole, which may cause claustrophobia, and the apparatus is noisy.

Therefore, a technical problem to be solved by those skilled in the art is to provide a magnetic resonance apparatus which occupies a small space and provides a high comfort level. <CIT> discloses a magnetic resonance imaging system with an insertable head and neck coil, where multiple primary magnetic coils generate a magnetic field along a longitudinal or z-axis of a central bore. A whole body gradient coil assembly includes coils mounted along the bore for generating gradient magnetic fields. A whole body radio frequency coil is mounted inside the gradient coil assembly. A whole body radio frequency shield is mounted between the whole body RF coil and the gradient coil assembly. An insertable radio frequency coil is removably mounted in the bore in an examination region defined around an isocenter of the magnet. A sequence controller controls gradient amplifiers connected with the gradient coil assembly for causing the generation of the gradient magnetic fields at appropriate times during the selected gradient sequence and a digital transmitter which causes a selected one of the whole body and insertable radio frequency coils to generate radio frequency field pulses at times appropriate to the selected sequence. <CIT> discloses an MRI coil base apparatus that is configured for use with interchangeable coils that are attachable and detachable to and from the MRI coil base apparatus. An interchangeable coil may be attached to the base for an MRI procedure and then may be removed and replaced by a different interchangeable coil for a subsequent MRI procedure. An example coil may be used with an example base that is configured for use with interchangeable attachable and detachable coils. Connector may mechanically or electrically connect coil to the MRI coil base apparatus. The MRI coil is configured to be mechanically and electrically coupled to the base. The coil may be a member of a set of different MRI coils that can be attached to and detached from base.

<CIT> discloses an extremity MRI system with a body coil and a surface coil and a connection device which enables to mount the surface coil within the body coil.

In view of this, an object of the present application is to provide a superconducting magnetic resonance imaging system for an extremity which occupies a small space and provides a high comfort level during examination.

In order to achieve the above object, the following technical solutions are provided according to the present application.

A superconducting magnetic resonance imaging system for an extremity includes a magnetic system, a radio frequency system and a console, the magnetic system includes a loop-shaped main housing, the radio frequency system includes loop-shaped radio frequency coils, the radio frequency coils include an extremity coil and at least two types of extremity-part coils, the extremity coil is a transmit-receive coil, and each of the extremity-part coils is a receive-only coil configured for only receiving signals, the extremity coil is arranged on an inner loop-shaped surface of the main housing, each of the extremity-part coils is configured to be switchably connected to an inner loop-shaped surface of the extremity coil and the radio frequency coils are communicatively connected with the console in a detachable manner; where.

Preferably, a diameter of the inner loop-shaped surface of the extremity coil ranges from <NUM> to <NUM>, and a diameter of an inner diameter surface of the knee coil ranges from <NUM> to <NUM>.

Preferably, the extremity-part coils include at least one of an elbow coil for imaging of an elbow and an ankle coil for imaging of an ankle.

Preferably, the elbow coil includes a loop-shaped elbow coil main body and two elbow coil support boards arranged at two axial sides of the elbow coil main body.

Preferably, the ankle coil includes a loop-shaped ankle coil main body and a loop-shaped ankle coil support board, one port of the ankle coil main body is butted to one port of the ankle coil support board, and an included angle is formed between a centerline of the ankle coil main body and a centerline of the ankle coil support board.

Preferably, the superconducting magnetic resonance imaging system for the extremity further includes a scanning chair which is made of a non-magnetic material and is arranged outside the main housing, the scanning chair includes a seat plate, a footrest and a backrest which are arranged at two sides of the seat plate, and an angle of the foot rest and an angle of the backrest are adjustable relative to the seat plate.

Preferably, the magnetic system further includes a superconducting magnet arranged in the main housing, a magnetic field intensity of the superconducting magnet is <NUM>. 0T, and a <NUM>. 0T extremity-dedicated pulse sequence is built in a controller of the console.

Preferably, the magnetic system further includes a gradient system, the gradient system includes a gradient coil, the gradient coil has an annular structure with a length less than or equal to <NUM>, an outer diameter less than or equal to <NUM> and an inner diameter greater than or equal to <NUM>.

During examination, a suitable extremity-part coil is selected and is mounted in the extremity coil, so as to perform examination to the corresponding extremity part. The extremity coil transmits a signal to the extremity part to be examined but does not receive an external signal, a return signal is received by the extremity-part coil, and then data analysis and imaging are performed by the console. In addition, due to the difference in body shape of the examination subject, for an overweight examination subject, the extremity-part coil may not be mounted in the extremity coil, instead, the extremity coil may be directly used for examination. For example, a knee of the examination object extends into the extremity coil, the extremity coil transmits and receives signals, and then the console performs data analysis and imaging.

It can be seen that during imaging, only the extremity part to be examined is required to be placed into the corresponding radio frequency coil, while other parts of the body are still outside the magnet, which avoids the disadvantages of whole-body magnetic resonance such as causing claustrophobia, difficulty in placing the upper extremity part to be examined in the center of the imaging area and high noise, and has a high comfort level. In addition, since the apparatus does not need to accommodate the whole human body, the occupied space is small, and the manufacturing cost of the apparatus is reduced due to the decrease of the size.

For more clearly illustrating embodiments of the present application or the technical solutions in the conventional technology, drawings to be used in the description of the embodiments or the conventional technology will be briefly described hereinafter. Apparently, the drawings in the following description are only embodiments of the present application, for those skilled in the art, other drawings may be obtained based on the provided drawings without any creative work.

Technical solutions in the embodiments of the present application are clearly and completely described hereinafter in conjunction with the drawings in the embodiments of the present application. Apparently, the embodiments described in the following are only some embodiments of the present application, rather than all embodiments. Based on the embodiments in the present application, all of the other embodiments encompassed by the claims fall within the protection scope of the present invention.

A core according to the present application is to provide a superconducting magnetic resonance imaging system for an extremity, which occupies a small space and provides a high comfort level during examination.

The superconducting magnetic resonance imaging system for the extremity according to a specific embodiment of the present application, referring to <FIG>, includes a magnetic system <NUM>, a radio frequency system and a console <NUM>.

The magnetic system <NUM> includes a loop-shaped main housing <NUM>, referring to <FIG>, an inner loop-shaped surface of the main housing <NUM> forms an examination hole, and a diameter of the hole is greater than or equal to <NUM>. In addition, an outer loop-shaped surface of the main housing <NUM> has an outer diameter less than or equal to <NUM> and a length less than or equal to <NUM>, which has a compact structure, and can meet requirements of sizes of hands, feet, elbows, knees and positioning of extremities during examination. A superconducting magnet is arranged in the main housing <NUM>, which specifically is a superconducting coil structure with a magnetic field intensity reaching <NUM>. 0T, an imaging area greater than <NUM>, a magnetic field uniformity less than <NUM> ppm, a magnetic field stability less than <NUM> ppm, liquid helium consumption less than or equal to <NUM>, and no volatilization of liquid helium, which has high imaging resolution, high signal-to-noise ratio and good image quality.

The radio frequency system includes at least two types of loop-shaped radio frequency coils, which specifically includes an extremity coil <NUM> and at least two types of extremity-part coils. The extremity coil <NUM> is a transmit-receive coil, which can receive and transmit signals. The extremity-part coils are receiver coils which only receive signals. The extremity coil <NUM> is arranged on an inner loop-shaped surface of the main housing <NUM>.

Each extremity-part coil is configured to be switchably connected to an inner loop-shaped surface of the extremity coil <NUM>, that is, each extremity-part coil is detachably connected to the extremity coil <NUM>, and when switching is required, the currently used extremity-part coil is detached and replaced by another type of extremity-part coil. The extremity-part coils are configured for examination of corresponding different extremity parts, for example, for examination of corresponding hands, elbows, ankles and other parts respectively.

During examination, a suitable extremity-part coil is selected and is mounted in the extremity coil <NUM>, so as to perform examination to the corresponding extremity part. The extremity coil <NUM> transmits a signal to the extremity part to be examined but does not receive an external signal, a return signal is received by the extremity-part coil, and then data analysis and imaging are performed by the console <NUM>. In addition, due to the difference in body shape of the examination subject, for an overweight examination subject, the extremity-part coil may not be mounted in the extremity coil <NUM>, instead, the extremity coil <NUM> may be directly used for examination. For example, a knee of the examination object extends into the extremity coil <NUM>, the extremity coil <NUM> transmits and receives signals, and then the console <NUM> performs data analysis and imaging.

It can be seen that in this embodiment, during imaging, only the extremity-part to be examined is required to be placed into the corresponding radio frequency coil, while other parts of the body are still outside the magnet, which avoids the disadvantages of whole-body magnetic resonance such as causing claustrophobia, difficulty in placing the upper extremity-part to be examined in the center of the imaging area and high noise, and has a high comfort level. In addition, since the apparatus does not need to accommodate the whole human body, the occupied space is small, and the manufacturing cost of the apparatus is reduced due to the decrease of the size.

Furthermore, the radio frequency coils further include a knee coil <NUM>, and the knee coil <NUM> is a transmit-receive coil. The extremity coil <NUM> and the knee coil <NUM> are switchably connected to the inner loop-shaped surface of the main housing <NUM>, that is, the extremity coil <NUM> and the knee coil <NUM> are detachably connected to the main housing <NUM>, and when one of the extremity coil <NUM> and the knee coil <NUM> is detached, the other one can be connected.

An inner loop-shaped surface of the knee coil <NUM> and an inner loop-shaped surface of the extremity coil <NUM> are both cylindrical surfaces, and an inner diameter of the knee coil <NUM> is smaller than an inner diameter of the extremity coil <NUM>. Optionally, a diameter of the inner loop-shaped surface of the extremity coil <NUM> ranges from <NUM> to <NUM>, which is specifically <NUM>, and a diameter of an inner diameter surface of the knee coil <NUM> ranges from <NUM> to <NUM>, which is specifically <NUM>. In addition, other positioning structures may also be provided on the inner loop-shaped surfaces of the knee coil <NUM> and the extremity coil <NUM>, so as to position extremity parts or be connected to other coils.

In this embodiment, during the knee examination, if the examination subject is overweight, the extremity coil <NUM> may be used for knee examination; if the examination subject is thin and the leg can extend into the knee coil <NUM>, the extremity coil <NUM> may be removed from the main housing <NUM>, and the knee coil <NUM> may be mounted in the main housing <NUM> for examination. Thus, knee imaging may be adaptively realized in consideration of the body shape of the examination subject, which has high applicability.

Further, the extremity-part coils include a hand coil <NUM> and may further include an elbow coil <NUM> and an ankle coil <NUM>. Preferably, the hand coil <NUM>, the elbow coil <NUM> and the ankle coil <NUM> are provided in a manner of simulating shapes of the hands, elbows and ankles respectively, which can further improve the adaptability to the extremity part to be examined. During examination, the extremity-part coil can be closer to the extremity surface, a better signal-to-noise ratio is obtained, and thus the imaging is clearer.

Further, referring to <FIG> and <FIG>, the hand coil <NUM> includes a loop-shaped hand coil main body <NUM> and a hand coil support board <NUM> arranged at one axial side of the hand coil main body <NUM>, an inner loop-shaped surface of the hand coil main body <NUM> is formed by a C-shaped surface and a main body flat surface connected to an opening of the C-shaped surface, and the hand coil support board <NUM> is a flat surface and is arranged coplanar with the main body flat surface. During use, the hand coil support board <NUM> can support the arm, and the hand extends into the hand coil main body <NUM> for examination, which has a good comfort level during the examination, and can keep the arm stable.

Further, referring to <FIG>, the elbow coil <NUM> includes a loop-shaped elbow coil main body <NUM> and two elbow coil support boards <NUM> arranged at two axial sides of the elbow coil main body <NUM>. The two elbow coil support boards <NUM> can support the parts of the arm located at two sides of the elbow respectively, which can improve the stability of arm placement, and thereby avoiding arm soreness during the examination.

Further, referring to <FIG> and <FIG>, the ankle coil <NUM> includes a loop-shaped ankle coil main body <NUM> and a loop-shaped ankle coil support board <NUM>, one port of the ankle coil main body <NUM> is butted to one port of the ankle coil support board <NUM>, and an included angle is formed between a centerline of the ankle coil main body <NUM> and a centerline of the ankle coil support board <NUM>. During ankle examination, the centerline of the ankle coil support board <NUM> is substantially horizontal, the ankle coil main body <NUM> is gradually inclined upward from the joint with the ankle coil support board <NUM> toward the other end of the ankle coil main body <NUM>, the foot extends from the ankle coil support board <NUM> into the ankle coil main body <NUM>, the leg may rest on the ankle coil support board <NUM>, the foot may rest on a bottom of the inner loop-shaped surface of the ankle coil main body <NUM> which is inclined, and the ankle may be located at a junction between the ankle coil support board <NUM> and the ankle coil main body <NUM>, so that the leg has a high comfort level during the examination, and the ankle is positioned well during examination.

Further, referring to <FIG>, the imaging system further includes a scanning chair <NUM> which is made of a non-magnetic material and is arranged outside the main housing <NUM>, the scanning chair <NUM> includes a seat plate <NUM>, a footrest <NUM> and a backrest <NUM> which are arranged at two sides of the seat plate <NUM>, and an angle of the footrest <NUM> and an angle of the backrest <NUM> are adjustable relative to the seat plate <NUM>. Specifically, linkage adjustment of the backrest <NUM> and the seat plate <NUM> can be performed through an adjustment structure. By adjusting the angles of the backrest <NUM> and the footrest <NUM>, the scanning chair <NUM> can be in a seat state or a bed state, so that the examination subject can sit or lie on the scanning chair <NUM> for examination. When the scanning chair <NUM> is adjusted to the seat state, the examination subject can sit on the scanning chair <NUM> in a sitting posture for lower extremity scanning and imaging and when the scanning chair <NUM> is adjusted to the bed state, the examination subject can lie on the scanning chair <NUM> in a lying posture for upper extremity scanning and imaging. In addition, the scanning chair <NUM> further includes a bracket which is fixed under the seat plate <NUM> and a roller arranged under the bracket, so as to realize functions such as rotation and movement of the scanning chair <NUM>, which facilitates adjustment of the position of the scanning chair <NUM>.

Further, referring to <FIG>, a software of a controller of the console <NUM> employs a <NUM>. 0T extremity-dedicated imaging sequence, which, compared with the conventional imaging sequence, is optimized and adjusted in terms of gradient waveform, climbing time and pulse width, which further gives play to the hardware performance of the product, so that the imaging quality is better and the scanning speed is faster. In addition, the console <NUM> is specifically a dedicated magnetic resonance console with four channels for reception and two channels for transmission. In order to realize the specific imaging of joints and bone cortex, the time resolution reaches <NUM> ns and the phase accuracy reaches <NUM> degrees. The console <NUM> has a split structure, which is more convenient for future upgrades and saves the consumption of radio frequency signal lines.

Further, referring to <FIG>, the magnetic system <NUM> further includes a gradient system <NUM>, the gradient system <NUM> includes a gradient coil, which may be specifically arranged between the inner loop-shaped surface of the main housing <NUM> and the radio frequency coil. The gradient coil has an annular structure with a length less than or equal to <NUM>, an outer diameter less than or equal to <NUM>, and an inner diameter greater than or equal to <NUM>. The gradient coil is a small-diameter extremity gradient coil, which can just meet the size requirements of human extremities, so that the knee or elbow of the human can reach the center of the imaging area. In addition, the gradient coil is a high-performance gradient coil with high gradient field intensity, high switching rate and low eddy current value, where the gradient intensity is <NUM> mT/m, the switching rate is 500T/m/s, the nonlinearity is less than <NUM>%, the eddy current value is less than <NUM>%, and the gradient intensity and switching rate are respectively <NUM> to <NUM> times of the whole-body <NUM>. 0T apparatus, thus the gradient coil has better performance in efficiency, gradient field intensity and switching rate, which also has small operating current and low noise, and thereby the requirements of high-resolution imaging and fast imaging are well satisfied.

According to the imaging system of this embodiment, core components of each subsystem are provided according to the specialized requirements of extremity imaging, and the performance is greatly improved, which can not only meet the disease diagnosis requirements of high-resolution and fast imaging, but also meet the scientific research needs of the advanced imaging functions.

It should be noted that when an element is referred to as being "fixed" to another element, it may be directly fixed to the another element or an intermediate element may be provided. All technical and scientific terms used in the present application have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs, unless otherwise defined. The terms in the present application are used to describe specific embodiments, which are not intended to limit the present application.

The above embodiments are described in a progressive manner, each of the embodiments is mainly focused on describing its differences from other embodiments, and reference may be made among these embodiments with respect to the same or similar parts.

Claim 1:
A superconducting magnetic resonance imaging system for an extremity, comprising a magnetic system (<NUM>), a radio frequency system and a console (<NUM>), wherein the magnetic system (<NUM>) comprises a loop-shaped main housing (<NUM>), the radio frequency system comprises loop-shaped radio frequency coils, wherein
the radio frequency coils comprise an extremity coil (<NUM>) and at least two types of extremity-part coils, the extremity coil (<NUM>) is a transmit-receive coil, and each of the extremity-part coils is a receive-only coil configured for only receiving signals; the extremity coil (<NUM>) is arranged on an inner loop-shaped surface of the main housing (<NUM>), each of the extremity-part coils is configured to be switchably connected to an inner loop-shaped surface of the extremity coil (<NUM>), and the radio frequency coils are communicatively connected with the console (<NUM>) in a detachable manner; wherein
the radio frequency coils further comprise a knee coil (<NUM>) for imaging of a knee, the knee coil (<NUM>) is a transmit-receive coil, the extremity coil (<NUM>) and the knee coil (<NUM>) are configured to be switchably connected to the inner loop-shaped surface of the main housing (<NUM>), and an inner diameter of the knee coil (<NUM>) is smaller than an inner diameter of the extremity coil (<NUM>); and
the extremity-part coils comprise a hand coil (<NUM>) for imaging of a hand, the hand coil (<NUM>) comprises a loop-shaped hand coil main body (<NUM>) and a hand coil support board (<NUM>) which is arranged at one axial side of the hand coil main body (<NUM>), an inner loop-shaped surface of the hand coil main body (<NUM>) is formed by a C-shaped surface and a main body flat surface connected to an opening of the C-shaped surface, and the hand coil support board (<NUM>) is a flat surface and is arranged coplanar with the main body flat surface.