Susceptometers for foreign body detection

Abstract

Methods and apparatus for minimizing the effects of temperature drift in a magnetic susceptibility measurement instrument, such as an instrument used in pre-MRI screening for the presence of ferromagnetic foreign bodies. The magnetic field source and magnetic sensors can be combined into a single, rigid unit. The stability and sensitivity required in high quality magnetic susceptibility measurements can be achieved through symmetrical design of the source-sensor unit, minimization of thermal stresses, minimization of temperature variations, use of materials with low thermal expansion coefficients, or through appropriate combinations thereof. Use of patient eye movement where an eye is being screened, use of a water bag between the patient and the instrument, or use of telemedicine to facilitate performance of the necessary computations can also be incorporated.

Description

BACKGROUND OF THE INVENTION

[0003] 1. Field of the Invention

[0004] The present invention is in the field of magnetic susceptometers, especially those intended for use in ferromagnetic foreign body (FFB) detection as a safety measure prior to magnetic resonance imaging (MRI).

[0005] 2. Background Art

[0006] Ultra-sensitive magnetic susceptibility measurements are useful in a number of applications, including the measurement of iron concentrations in the liver and the detection of ferromagnetic foreign bodies in the eye and brain, and elsewhere in the body, prior to magnetic resonance imaging. In the magnetic susceptibility measurement, a magnetic field is applied to a specimen, and a magnetic sensor measures the change in magnetic field due to the magnetization induced in the specimen by the applied field. The main challenge in such measurements is not only that the magnetic field response of the sample is small in absolute terms, but that the response may be many orders of magnitude smaller than the magnetic field that is applied to the specimen. Measuring such a small response, in the presence of such a relatively large applied field, is especially difficult in a room-temperature instrument, because temperature fluctuations may distort the geometrical relationship between the magnets or coils that produce the applied magnetic field and the magnetic-field sensors that detect the response of the specimen. This geometrical distortion causes fluctuations in the measured magnetic field, which can mask the desired magnetic field response of the specimen. One way to minimize such temperature drifts is to modulate the distance or spatial relationship between the specimen and the instrument, modulating the magnetic susceptibility response of the specimen at a frequency that is relatively high compared with the typically slow time-scale of the temperature drifts.

[0007] An alternative approach in sensitive magnetic susceptibility measurements is to maintain a desired geometrical relationship between the magnetic-field source(s) and the magnetic-field sensors, so as to minimize fluctuations in the measured magnetic field. The required dimensional stability of the sensor unit is determined by the required resolution of the magnetic susceptibility measurement. Certain specific applications, such as detection of ferromagnetic foreign bodies prior to MRI imaging, require resolution of changes in magnetic field that are 107 or even 108 times smaller than the field applied to the specimen. In order to resolve signals 107 times smaller than the applied field, it would be necessary for all the relative dimensions of the sensor unit to remain constant to roughly one part in 107. Some existing magnetic susceptometers, based upon superconducting quantum interference devices (SQUIDs), achieve the required stability by placing the magnetic field source or sources and magnetic field sensor or sensors in a liquid helium bath. With this approach, thermal expansion is not a problem because temperature fluctuations are controlled by the liquid-helium bath, and because the thermal expansion of most materials is essentially frozen out at liquid-helium temperatures. This geometrical stability, and not any intrinsic property of superconductors, may in fact be the single greatest advantage of working at liquid-helium temperatures. Achieving similar stability at room temperature is a significant problem.

[0008] Even if the aforementioned problems can be solved, there are additional problems related to the use of magnetic susceptibility measurements in pre-MRI screening for FFBs, including masking of the magnetic susceptibility response of the FFB by magnetic susceptibility signals from tissues in the patient's head, and masking of the magnetic susceptibility response of the FFB by the very large response due to the magnetic susceptibility contrast between the body tissues and the surrounding air. Further, the computer equipment used in interpreting the signals measured by the magnetic susceptibility instrument can add to the cost of pre-MRI screening.

BRIEF SUMMARY OF THE INVENTION

[0009] The present disclosure describes several techniques which minimize the effects of temperature drift, without modulation of the sensor-sample distance, and without relying on phenomena or materials properties which occur only at cryogenic temperatures. A first step in maintaining this geometrical relationship is to combine the magnetic field source, or sources, and the magnetic sensor, or sensors, into a single, rigid unit, which will be called the source-sensor unit throughout the discussion below.

[0010] The present invention achieves the stability and sensitivity required in high quality magnetic susceptibility measurements, and makes the high quality magnetic susceptibility measurements widely available, specifically concerning such measurements for pre-MRI screening, by the following means:

[0011] 1. Exploiting symmetry;

[0012] 2. Minimizing thermal stresses;

[0013] 3. Minimizing temperature variations;

[0014] 4. Using materials with low thermal expansion coefficients;

[0015] 5. Using eye movement to enhance the sensitivity of the instrument;

[0016] 6. Using a bag of deformable material to enhance the sensitivity of the instrument; and

[0017] 7. Using telemedicine to make the enhanced measurements widely available and to facilitate quality control in the interpretation of test results.

[0018] The novel features of this invention, as well as the invention itself, will be best understood from the attached drawings, taken along with the following description, in which similar reference characters refer to similar parts, and in which:

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0019] FIG. 1 is a schematic view of a source-sensor unit according to the present invention, with symmetrically disposed sensor coils;

[0020] FIG. 2 is a schematic view of a source-sensor unit according to the present invention, with symmetrically disposed sensor coils and a symmetrically disposed heat sink;

[0021] FIG. 3 is a perspective view of a source-sensor unit according to the present invention, with sensors sandwiched between parallel circuit board field coils;

[0022] FIG. 4A is a perspective view of a source-sensor unit according to the present invention, with a solid cylindrical coil form;

[0023] FIG. 4B is a perspective view of a source-sensor unit according to the present invention, with a thick walled cylindrical coil form; and

[0024] FIG. 5 is a schematic view of the apparatus of the present invention, employing a water bag.

DETAILED DESCRIPTION OF THE INVENTION

[0025] The features of several exemplary embodiments of the apparatus and methods of the present invention will now be described.

[0026] Exploiting symmetry in source-sensor unit configuration. One way to minimize the effects of thermal drifts in sensitive magnetic susceptibility measurements is to arrange the applied-field generating elements and magnetic sensors in a manner that (1) the signal due to the applied field is cancelled out and (2) the entire source-sensor unit is symmetrical, in such a way that the cancellation of the applied-field signal is preserved if the entire structure expands and contracts uniformly.

[0027] One example of this concept is shown in FIG. 1. In this preferred embodiment, the source-sensor unit 10 consists of an applied-field coil 12 and two identical sensor coils 14, co-axially wound on a single coil form 16, with the applied-field coil 12 centered between the two sensor coils 14. The sensor coils 14 are connected in series opposition to form a first-order magnetic gradiometer. Since the sensor coils 14 are symmetrically disposed with respect to the applied-field coil 12, this gradiometer arrangement cancels the signal due to the applied field. This cancellation is maintained even if the source-sensor unit 10 expands or contracts, as long as the amount of expansion or contraction is the same throughout the structure, or is at least symmetrical with respect to the plane of mirror symmetry 18 of the coil set. As a result, the error due to an overall change in temperature, or a temperature change that is symmetrical with respect to the plane of mirror symmetry 18, is greatly reduced.

[0028] As an alternative, the applied field coil and sensor coils can be built in such a manner that the source-sensor unit configuration may not be geometrically symmetrical, but, if the thermal expansion or contraction of the structure is uniform throughout, then the applied field signal cancellation is still maintained.

[0029] In order to enhance the symmetry effect, it is desirable to maximize the thermal conductance between different parts of the structure, thus maintaining as much thermal uniformity as possible. It is also desirable to protect the source-sensor unit from ambient air currents, or to insulate it from ambient temperature changes, thus minimizing any thermal loads that may differ between different parts of the structure. It is desirable for any thermal links to the outside world, such as those required to remove the heat generated in the applied-field coil, to have the same symmetry as the source-sensor unit itself. An example of this concept is shown in the source-sensor unit 20 of FIG. 2, where, as before, an applied-field coil 12 and two identical sensor coils 14 are co-axially wound on a single coil form 16, with the applied-field coil 12 centered between the two sensor coils 14. In this embodiment, however, two thermally conductive links 24 to a heat sink 22 are placed symmetrically with respect to the plane of mirror symmetry 18 of the coil set. This symmetrical arrangement ensures that even if the temperature of the source-sensor unit 20 changes, the temperature distribution will remain symmetrical with respect to the plane of mirror symmetry 18 of the source-sensor unit 20. The source-sensor unit 20 can also be encased in a thermally insulating enclosure 26.

[0030] FIG. 3 shows another embodiment of a source-sensor unit 30 which also uses symmetry to maintain cancellation of the applied field. One or more magnetic sensors (not shown in this view) are sandwiched between two printed circuit boards 32, 34. The central region of each circuit board 32, 34 contains a number of parallel, evenly spaced traces 36, 38 which are connected in series and carry identical currents. This arrangement approximates the effect of a uniform sheet of current in a region near the center of each board 32, 34, with return paths completing the circuit along both edges. The two circuit boards 32, 34 are connected in series, so that the currents are identical in both boards, and flow in the same direction. With this configuration of currents, the magnetic fields from the two circuit boards 32, 34 reinforce each other in the region just outside either board, but cancel each other in the region between the two circuit boards.

[0031] With this coil system, the applied field at the magnetic sensors is nulled by balancing the fields from two identical structures such as the two circuit boards 32, 34 in FIG. 3, with identical thermal time constants, and identical ohmic heat loads. With this structure, although the overall temperature of the unit 30 may vary, the changes in temperature and the resulting thermal expansion or contraction will tend to be the same for both printed circuit boards 32, 34, so that the cancellation of the applied field at the magnetic sensors is preserved.

[0032] In such a structure, it is acceptable for the overall temperature to fluctuate somewhat, as long as the whole system expands and contracts uniformly. This means that geometrical relationships are kept constant. If the field at the sensors is 103 times smaller than that in the sensed region, an overall expansion of the coil system of one part in 105 still will allow detection of signals 108 times smaller than the field applied to the sensed region. In copper, this amount of expansion corresponds to a temperature fluctuation of one-half of a kelvin degree, which is an easy temperature range to maintain over the short time that the pre-MRI measurement will take.

[0033] The same principles of symmetry can be applied to various sensor designs, using a variety of geometries, using any type of magnetic sensor, whether the applied field is produced using permanent magnets, coils, or a combination of coils and magnetic materials.

[0034] A similar effect can be obtained by using other embodiments. For instance, two or more applied field coils which are symmetrical in their thermal properties can be symmetrically arranged so that thermal expansion or contraction of the structure preserves the symmetry that maintains the cancellation of the magnetic field in a desired location.

[0035] Minimizing thermal stresses. Differential expansion can create strains in the structure of the coil system. Such distortions can be minimized by balancing the thermal stresses. For example, if the field coils are put on printed circuit boards, it would be beneficial to put identical layers of metal, such as copper, on both sides of the board to balance out any stresses due to the differential expansion of the metal and the nonmetallic substrate, such as fiberglass, of the printed circuit boards.

[0036] In addition, thermal stresses may be minimized by making all parts of the coil structure, including the coils themselves and any supporting structures, of materials that have the same thermal expansion coefficients. For example, G-10 or FR-4 fiberglass and copper are materials with a reasonably good match of thermal expansion coefficients.

[0037] One configuration which minimizes both temperature non-uniformity and thermal stresses is an applied-field coil constructed almost entirely of bars of rigid metal, such as copper, with only small insulating spacers to separate the different conductors in the coil. In this configuration, the high thermal conductivity of the metal bars would minimize temperature imbalances within the structure. In addition, thermal stresses are minimized by constructing the coil almost entirely of the same material. As a result, the basic shape of the coil is preserved, even if the overall temperature of the structure varies. If the coil is configured to cancel the magnetic field at a particular location, this field cancellation would be insensitive to variations in temperature. A low-drift magnetic susceptometer is then created by placing a magnetic sensor at the location of field cancellation.

[0038] Minimizing temperature variations. In addition to making the source-sensor unit insensitive to temperature variations, one can also minimize thermal drifts by taking steps to minimize the temperature variations themselves. One method of minimizing temperature variations is to put the structure comprising the magnetic sensors and magnetic field sources into thermal contact with a sufficiently large thermal mass to ensure that any significant temperature variations occur on a time scale much longer than that required by the magnetic susceptibility measurement itself. The presence of a large thermal mass retards any temperature variations, so that they occur on a time-scale much slower than that of the desired magnetic susceptibility measurement. For example, in the type of sensor configuration shown in FIG. 1, one way to provide a large thermal mass is to make the coil form 16 of considerable mass as a solid cylinder, or, alternatively, as a thick-walled hollow cylinder, as shown in FIGS. 4A and 4B. In FIG. 4A, an applied field coil 12 and two sensor coils 14 are wound on a solid cylindrical coil form 16′. The applied field coil 12 and the sensor coils 14 can be copper wires set in grooves on the surface of the coil form 16′. In FIG. 4B, an applied field coil 12 and two sensor coils 14 are wound on a thick walled hollow cylindrical coil form 16″. Here again, the applied field coil 12 and the sensor coils 14 can be copper wires set in grooves on the surface of the coil form 16″.

[0039] In addition, temperature variations can be reduced by suitably insulating the source-sensor unit from ambient temperature variations and/or by shielding it from shifting air currents in the room. If the source-sensor unit is insulated in this manner, and if the applied magnetic field is produced using field coils, as opposed to a permanent magnet, it is necessary to remove the heat produced by ohmic losses in the field coils. One way to remove this heat, without introducing unwanted temperature variations, is to provide a thermal link to the outside world, and to provide a point external to the shield or insulation at which the temperature can be controlled, thereby minimizing temperature fluctuations in the source-sensor unit. Active feedback can be utilized to stabilize temperature fluctuations. Temperature stabilization can also be achieved by putting the thermal link in contact with a large thermal mass.

[0040] Another way to enhance temperature stability, and thereby to control the temperature, is to put the source-sensor unit in thermal contact with an appropriate temperature-stabilizing chemical system, such as ice in water. A number of other temperature-stabilizing materials are also available, using various chemical and/or physical phase transitions, such as butanol, or tertiary-butanol, or, alternatively, other materials, or mixtures of materials. A recirculation system with a constant temperature feedback can also be employed in these configurations.

[0041] Using low-expansion material. Thermal drifts in the geometry of the source-sensor unit can be minimized by using materials with low thermal expansion coefficients in the structures that define the shapes, dimensions, and geometrical relationships of the applied-field source and the magnetic sensors. One preferred low-expansion material is quartz, which has a thermal expansion coefficient close to zero. Other preferred low-expansion materials are machinable glass-ceramic, such as MACOR™ ceramic material by Coming Glass Co., marble, sapphire, granite, or other suitable non-magnetic, electrically nonconducting materials with a low thermal expansion coefficient. These, or other available low-expansion materials, can be used in coil forms for the applied-field and sensor coils. FIGS. 4A and 4B show two sensor design embodiments in which this strategy can be employed. Low-expansion materials can also be used in other structures, such as braces or struts defining the separation and relative positions of applied-field coils and magnetic sensors.

[0042] In conjunction with the use of low thermal expansion materials, it is advantageous to provide a large thermal mass, as described above, to minimize temperature variations in the source-sensor unit.

[0043] Certain low-expansion materials, including marble, are currently known as coil form materials for some magnetic susceptibility measurements. However, the use of any low thermal expansion material in constructing a source-sensor unit specifically for ferromagnetic foreign body detection as a pre-MRI screening instrument is not currently known.

[0044] If the applied-field coils and sensor coils are made of a good electrical conductor, such as copper, the conductor will typically have a much higher thermal expansion coefficient than the low expansion materials listed above. In this case, it will be desirable to bond the conductor to the non-conductive substrate firmly, using as rigid a bonding material as possible.

[0045] The design principles disclosed above can be used in combination with ac (alternating field) or dc (constant field) magnetic susceptibility measurements, using any combination of magnetic sensors, including, for example, induction coils, magnetoresistive sensors, giant magnetoresistance sensors, spin-dependent tunneling sensors, fluxgates, single-domain fluxgates, and generating the applied field using coils, permanent magnets or coils in combination with magnetically permeable material.

[0046] Enhancing sensitivity by employing eye movements. A potential problem in ferromagnetic foreign body detection of the eye and orbit area in pre-MRI screening is that tissues in the patient's head produce their own weak magnetic susceptibility signal, which can mask the magnetic susceptibility response of the FFB. Eye movement can therefore be employed in the practice of the present invention to enhance sensitivity. By having the patient rotate his or her eyes, either randomly or in a controlled manner, modulating the orientation and/or location of the ferromagnetic foreign body is achieved. This changing orientation or position will modulate the magnetic susceptibility signal from the FFB, without substantially changing the magnetic susceptibility response of the patient's body tissues. Since the globe of the eye is nearly spherical, eye rotation will not substantially change the magnetic susceptibility signal of the eye itself. The eye may be rotated in one or two axes, such as with an up and down eye movement and/or a left and right eye movement, or in all fields of gaze within these axes, thus providing enhanced information about the particle location and orientation. If desired, repeatable eye rotations can be produced by having the patient focus on each of a series of spots or targets in turn, or having the patient track a target moving in a specific pattern.

[0047] Using a water-bag to enhance sensitivity. One problem in sensitive magnetic susceptibility measurements on the human body is the very large response due to the magnetic susceptibility contrast between the body tissues and the surrounding air. This signal varies according to the shape of the body, and this variation can mask subtle changes in the magnetic susceptibility response due to variations in the magnetic susceptibility of the tissues, or, if applicable, the presence of small ferromagnetic foreign bodies. One method to reduce the magnetic susceptibility contrast problem is to insert a deformable water bag between the patient and the sensing apparatus.

[0048] In the traditional water bag method, as commonly employed with SQUID sensor apparati, the sensing instrument is initially pressed against the patient's body. The patient is then moved away from the sensing apparatus, and the water bag is continuously supplied with water, such that the space between the sensing apparatus and the patient is filled with water at all times. With this method, the patient's body is, in effect, replaced by water throughout the field of view of the instrument, and the resulting change in magnetic susceptibility signal is due only to the difference in magnetic susceptibility between the body and water. In essence, the traditional water bag method eliminates the magnetic susceptibility signal due to the large susceptibility contrast between the water-like tissues of the body and the surrounding air.

[0049] Use of the water bag 40 in the practice of the present invention, as shown in FIG. 5, does not eliminate this air-water magnetic susceptibility contrast, but rather replaces the varying shapes of the body surface with an air-water interface of constant shape defined by a rigid, fixed barrier 42, between the water bag 40 and the source-sensor unit 44. This water bag method is very useful as a preferred embodiment when the magnetic susceptometers described above are employed in pre-MRI screening of the eye, the orbit, or the brain. The bag 40 can contain water, a water solution, a gel, or another suitable deformable material.

[0050] Using telemedicine to implement the enhanced measurements. Telemedicine can also be employed in the practice of the present invention, specifically to centralize the computer equipment with the required computational capability, thereby making the enhanced measurements widely available and facilitating quality control in the interpretation of test results. The preferred vehicle for said telemedicine is the Internet. Artificial intelligence modalities, including neural net and other expert systems, can also be employed, providing instantaneous autointerpretation of test results. Provision is made for real-time interactive feedback between the remote test instrument and a central computer processing station, thereby helping to ensure patient cooperation and reliable data acquisition.

[0051] While the present invention is fully disclosed herein, it is to be understood that this disclosure is merely illustrative of the presently preferred embodiments of the invention and that no limitations are intended other than as described in the appended claims.

Claims

1. A source-sensor unit for a magnetic susceptibility measuring instrument, comprising: at least one applied-field generating element; and at least one magnetic sensor; wherein said at least one applied-field generating element and said at least one magnetic sensor are arranged such that the signal due to the applied field is canceled out; and wherein said entire source-sensor unit is constructed in such a way that said cancellation of the applied-field signal is preserved as the entire source-sensor unit expands and contracts uniformly.

2. The source-sensor unit recited in claim 1, wherein said source-sensor unit is symmetrically constructed.

3. The source-sensor unit recited in claim 2, further comprising a single coil form, and wherein: said at least one applied-field generating element comprises an applied-field coil; said at least one magnetic sensor comprises two identical sensor coils; said applied-field coil and said two sensor coils are co-axially wound on said single coil form with said applied-field coil centered between said two sensor coils; and said two sensor coils are connected in series opposition to form a first-order magnetic gradiometer.

4. The source-sensor unit recited in claim 3, further comprising: two thermally conductive links placed symmetrically with respect to the plane of mirror symmetry of said source-sensor unit; and a heat sink placed symmetrically with respect to the plane of mirror symmetry of said source-sensor unit; wherein said thermally conductive links connect said coil form to said heat sink.

5. The source-sensor unit recited in claim 4, further comprising a thermally insulating enclosure encasing said applied-field coil, said two sensor coils, and said coil form.

6. The source-sensor unit recited in claim 5, wherein said heat sink is outside said thermally insulating enclosure.

7. The source-sensor unit recited in claim 3, wherein said coil form is constructed to have significantly more mass than said applied-field coil and said sensor coils.

8. The source-sensor unit recited in claim 3, further comprising a large thermal mass in contact with said coil form, said applied-field coil, and said sensor coils.

9. The source-sensor unit recited in claim 8, wherein said coil form is constructed as a solid cylinder.

10. The source-sensor unit recited in claim 8, wherein said coil form is constructed as a thick-walled hollow cylinder.

11. The source-sensor unit recited in claim 1, wherein: said at least one applied-field generating element comprises a plurality of applied field coils configured to generate magnetic fields which cancel each other in a region between said plurality of applied field coils; and said at least one magnetic sensor is placed in said region of zero magnetic field between said plurality of applied field coils.

12. The source-sensor unit recited in claim 11, wherein: said plurality of applied field coils comprise a plurality of printed circuit boards; a central region of each said circuit board contains a number of parallel, evenly spaced traces; said parallel traces on each said circuit board are connected in series, so that said parallel traces carry identical currents, approximating the effect of a uniform sheet of current in a central region of each said circuit board, with return paths completing the circuit along at least two edges of each said circuit board; said plurality of circuit boards are connected in series, so that said currents are identical in all said circuit boards, and so that said currents flow in the same direction on said plurality of circuit boards; and said at least one magnetic sensor is positioned between said plurality of circuit boards in said region of zero magnetic field.

13. The source-sensor unit recited in claim 12, further comprising identical layers of metal on both sides of each said circuit board.

14. The source-sensor unit recited in claim 12, wherein said circuit board and said trace are constructed of materials having substantially the same thermal expansion coefficients.

15. The source-sensor unit recited in claim 14, wherein: said circuit board is constructed of fiberglass; and said trace is formed of copper.

16. The source-sensor unit recited in claim 15, wherein said fiberglass is G-10 fiberglass.

17. The source-sensor unit recited in claim 15, wherein said fiberglass is FR-4 fiberglass.

18. The source-sensor unit recited in claim 1, further comprising structures defining the shapes, dimensions, and geometrical relationships of said at least one applied-field generating element and said at least one magnetic sensor, said structures being constructed of materials with low thermal expansion coefficients.

19. The source-sensor unit recited in claim 18, wherein said structures are constructed of a material selected from the group consisting of quartz, machinable glass-ceramic, marble, sapphire, and granite.

20. The source-sensor unit recited in claim 18, wherein said structures include a coil form for winding at least one applied-field coil and at least one sensor coil.

21. A method for performing pre-MRI screening, comprising: providing a magnetic susceptibility measuring instrument having at least one applied-field generating element, and at least one magnetic sensor; constructing the structures which define the shapes, dimensions, and geometrical relationships of said instrument of materials with low thermal expansion coefficients; canceling the signal due to the applied field by arrangement of said applied-field generating element and said sensor; preserving said cancellation of the applied-field signal as the entire source-sensor unit expands and contracts uniformly; generating an applied magnetic field in a region of interest of a patient, with said source-sensor unit; and generating a magnetic susceptibility measurement relevant to the presence or absence of a ferromagnetic foreign body in said region of interest, with said source-sensor unit.

22. The method recited in claim 21, further comprising constructing said structures which define the shapes, dimensions, and geometrical relationships of said instrument of a material selected from the group consisting of quartz, machinable glass-ceramic, marble, sapphire, and granite.

23. A method for performing pre-MRI screening for ferromagnetic foreign bodies, comprising: providing a source-sensor unit including at least one applied-field generating element and at least one magnetic sensor; canceling the signal due to the applied magnetic field at the location of said at least one magnetic sensor by the relative arrangement of said at least one applied-field generating element and said at least one magnetic sensor in said source-sensor unit; preserving said cancellation of the applied-field signal as said entire source-sensor unit expands and contracts; generating an applied magnetic field in a region of interest of a patient, with said source-sensor unit; and generating a magnetic susceptibility measurement relevant to the presence or absence of a ferromagnetic foreign body in said region of interest, with said source-sensor unit.

24. The method recited in claim 23, further comprising preserving said cancellation of the applied-field signal by symmetrically constructing said entire source-sensor unit.

25. The method recited in claim 23, further comprising shielding said source-sensor unit from shifting air currents.

26. The method recited in claim 23, further comprising: generating said applied magnetic field using electrical field coils; providing a thermal link from said source-sensor unit to a point outside said shield to remove heat produced by ohmic losses in said field coils, via said thermal link; and controlling the temperature of said external point to minimize temperature fluctuation in said source-sensor unit.

27. The method recited in claim 26, further comprising controlling the temperature by putting said thermal link in thermal contact with a large thermal mass.

28. The method recited in claim 26, further comprising controlling the temperature by putting said thermal link in thermal contact with a temperature-stabilizing system.

29. The method recited in claim 28, wherein said temperature-stabilizing system includes a chemical or physical phase transition substance selected from the group consisting of ice in water, butanol, and tertiary-butanol.

30. The method recited in claim 23, wherein said region of interest comprises an eye of the patient, said method further comprising rotating said eye, thereby moving said ferromagnetic foreign body to modulate the magnetic susceptibility signal from any ferromagnetic foreign body which may be present, without substantially changing the magnetic susceptibility response of the patient's body tissues.

31. The method recited in claim 30, further comprising rotating said eye in a controlled manner.

32. The method recited in claim 23, further comprising: placing a bag of deformable material next to a body surface of the patient adjacent said region of interest; and placing a rigid, fixed barrier in contact with said deformable bag, between said deformable bag and said source-sensor unit, thereby replacing the varying shapes of said body surface with an air/deformable-material interface of constant shape defined by said barrier.

33. The method recited in claim 32, wherein said deformable material is selected from the group consisting of water, aqueous solution, gel, or other suitable materal.

34. The method recited in claim 23, further comprising: providing a plurality of said source-sensor units at a plurality of remote locations; providing a central computer processing station; transmitting a plurality of said magnetic susceptibility measurements generated by said remote source-sensor units to said central computer processing station via a communication system; and interpreting said magnetic susceptibility measurements with said central computer processing station.

35. The method recited in claim 34, further comprising transmitting said plurality of said magnetic susceptibility measurements to said central computer processing station via the Internet.

36. The method recited in claim 34, further comprising providing real-time interactive feedback between said remote source-sensor units and said central computer processing station.

37. The method recited in claim 34, further comprising performing instantaneous autointerpretation of said magnetic susceptibility measurements using artificial intelligence.

38. The method recited in claim 34, further comprising performing instantaneous autointerpretation of said magnetic susceptibility measurements using a neural network.