WO2002034131A1 - Magnet assembly with variable field directions and methods of magnetically navigating medical objects - Google Patents

Abstract

An adjustable field magnet assembly (20) comprising at least two magnets (22,24) rotatably mounted so that the rotation of at least one of the at least two rotatably mounted magnets (22,24) changes the magnetic field projected by magnet assembly (20). The magnet assembly (20) is particularly useful in providing a magnet field of variable direction for use in magnetically navigating medical objects in the body by rotating the magnets (22,24) comprising the assembly (20) and/or rotating the entire assembly (20).

Description

MAGNET ASSEMBLY WITH VARIABLE FIELD DIRECTIONS AND MET HODS OF MAGNETICALLY NAVIGATING MEDICAL OBJECTS

BACKGROUND OF TI IE INVENTION This invention lelates to magnets and in pai tiuilai to a magnet assembly that piovides a vanable magnetic held and to a method of navigating medical devices using such a magnet assembly

Pennanent magnets aie capable of pioviding stiong magnetic fields useful in many applications In some applications Such as in magnetic surgery, it is desirable fiom time to time to change the diiection of the magnetic field In the past this could only be accomplished by some 10 combination of ti anslations and lotations of the magnets In the case of magnetic sui geiy, this means that a lelatively large exclusion zone must be maintained aiound a patient This exclusion zone interfeies with the placement of othei medical equipment, including imaging equipment necessai y to monitoi the magnetic sui gei y and with access to the patient

SUMMARY OF THE INVENTION

I T The assembly of the piesent invention compπses at least two rotatably mounted magnets having magnetization directions such that iotation of at least one of the magnets changes the diiection of the magnetic field at an application point in the patient Thus by a simple iotation of the magnets within the assembly the diiection of the applied magnetic field can be changed, and the combination of l otdting the magnets and lotating the magnet assembly allows a magnet field in vutually any diiection 0 eliminating the need foi laige exclusion zones aiound the patient to accommodate ti anslation of the magnet needed ith pnoi ait magnets

BRIEF DESCRIPTION OF THE DRAWINGS

Fig 1 is a schematic diagram of a fust embodiment of a magnet assembly comprising two magnet cyl deis constructed accoiding to the pi incφles of this invention, 5 Fig 2a is a honzontal cioss-sectional view of the magnet assembly, taken along the plane of line 2 2 in Fig 1, lllusti ating the field diiection cieated in an operating region by the magnet cylmdeis in a fu st contigui ation

Fig 2b is a horizontal cross-sectional view of the magnet assembly, taken along the plane oi line 2-2 in Fig 1 lllusti ting the field diiection cieated in an operating legion by the magnet cylmdeis 10 in a second configuiation,

Fig 2c is a honzontal cioss-sectional view of the magnet assembly, taken along the plane of line 2-2 in Fig 1 illustrating the field diiection created in an opeiating legion by the magnet cylmdei s in a thu d contigui ation,

Tig 2d is a honzontal cioss-sectional v iew of the magnet assembly taken along the plane of ^ line 2-2 in Fig 1 lllustiating the field diiection cieated in an opei ating legion by the magnet cylmdei m a loui th conh»uι atιon, Fig 3 is a schematic diagiam of the magnet assembly of Fig 1 , rotated about an axis peψendiculai to the plane of the magnet cylinder s

Fig 4 is a schematic diagiam of a second embodiment of a magnet assembly compnsing thiee magnet cylmdei s consti ucted accoiding to the pnnciples of this invention, Fig 5a is a honzontal cioss-sectional view of the magnet assembly, taken along the plane ol line 5-5 in Fig 4, lllusti ating the field diiection cieated in an operating l egion by the magnet cylinders in a fu st configui ation,

Fig 5b is a honzontal cioss-sectional view of the magnet assembly, taken along the plane of line 5-5 in Fig 4 illustrating the field direction cieated in an opeiating region by the magnet cylmdeis in a second configuiation,

Fig 5c is a horizontal cross sectional view of the magnet assembly, taken along the plane of line 5-5 in Fig 4, illustrating the field diiection cieated in an opeiating region by the magnet cylinders in a thud configuration,

Fig 5d is a horizontal cioss-sectional view of the magnet assembly, taken along the plane of line 5 5 in Fig 4 lllusti ating the field diiection cieated in an operating region by the magnet cylmdei s in a fouith configuiation,

Fig 6 is a schematic diagiam of the magnet assembly of Fig 4, rotated about an axis peipendiculai to the plane of the magnet cylmdeis,

Fig 7 is a pei spective view of a stack of disk-shaped segments forming a magnet cylinder used in the magnet assemblies of the piesent invention,

Fig 8 is horizontal cross-sectional view through one of the lotatable cylinders

Fig 9a is a fiont elevation schematic diagram showing two assemblies configured to suπound a patient's head,

Fig 9b is a side elevation schematic diagram of the two assemblies shown in Fig 9, aftei iotation of the two assemblies relative to the patient,

Fig 9c is a top plan schematic diagiam showing two assemblies configuied to suiround a patient s chest,

Fig 9d is a top plan schematic diagi m showing two assemblies tilted to accommodate movement of an imaging C arm Fig 10 is a schematic diagiam of showing the aπangement of bi-planai imaging with two magnetic assemblies,

Fig 1 la is a front elevation schematic diagram of a third embodiment of a magnet assembly consti ucted accoiding to the pnnciples of this invention compnsing at least thiee non-coplanar magnet

L> lindus Fig 1 l b is a side elevation v iew ol the magnet assembly of the thud embodiment Fig 12 is a top plan view of a fourth embodiment of a magnet assembly consti ucted according to the principles of this invention, in which the magnetic lollei s are in a non-parallel, planar configur ation,

Fig 1 is a peispective View of the magnet assembly of the fourth embodiment, Fig 14 is a top plan view of a fifth embodiment of a magnet assembly constructed according to the pnnciples of this invention, in which the magnet lolleis aie in a non-parallel, planar configui ation,

Fig 15 is a perspective view of the magnet assembly of the fifth embodiment,

Fig 16a is top plan view of a six embodiment of a magnet assembly constructed according to the pnnciples of this invention with a patient disposed Within the magnet assembly,

Fig 16b is a top plan view of the magnet assembly of the sixth embodiment, wrthout the patient,

Fig 16c is an end elevation of the magnet assembly of the sixth embodiment, taken along the plane of line 16c- 16c in Fig 16b, Fig 16d is a side elevation view of the magnet assembly of the sixth embodiment, taken along the plane of line 16d-16d in Fig 16c,

Fig 17a is a top plan view of a seventh embodiment of a magnet assembly, compnsing four magnets, but with only the two magnets disposed below the patient shown for clarity,

Fig 17b is a ti ansvei se ci oss-sectional view of the magnetic assembly of the seventh embodrment,

Fig 18a is a top plan view of an eighth embodiment of a magnet assembly,

Fig 18b is a transverse cross sectional view of the magnet assembly of the eighth embodiment,

Fig 19a is a pei spective view of a ninth embodiment of a magnet assembly constiucted accoiding to the pnnciples of this invention having a single rotatable magnet,

Fig 19b is a peispective view of the ninth embodiment with the single rotatable magnet in a ditfeient onentation than in Fig 19a, and

Fig 19c is a perspective View of the ninth embodiment, with the single rotatable magnet in a different or ientation than in Figs 19a and 19b

Coπesponding reteience numeials indicate coπesponding parts throughout the seveial views of the di awings

DEI AILED DESCRIPTION OF THE INVENTION

A fust embodiment of a magnet assembly indicated geneially as 20, is shown schematically in Fig 1 The assembly 20 compnses two rotatably mounted geneially pai allel magnet cylinders 22 and 24 Each of the cylmdeis 22 and 24 is made fiom a pei manent magnetic material, such as NdBFe oi othei magnetic mater ial pieferably a high enei y pioducing matenal with high coercivity As descnbed below is pi etei ably jacketed in nonmagnetic stainless steel oi wrapped in high strength cai bon fibei oi othei stiong nonmagnetic matenal Each of the magnet cylmdei s 22 and 24 is lotatable about its longitudinal axis As shown and descnbed heiein the magnet cylmdeis 22 and 24 have a genei ally cuculai cioss-section which is piefened because of ease of consti uction and because the magnets can be closely spaced and rotated without mutual lntei feience Howevei the cylinders could have some other cross-sectional piofile Fuithei , each of the magnet cylinders 22 and 24 is pieferably umfoi mly magnetized in one direction peipendicular to its longitudinal axis Foi particularly applications, however it may be desirable to have legions with differing magnetization directions, foi example varying acioss the cioss section of the magnet cyhndei , oi varying along the length of the cylindei to increase the focused field effect of the assembly While the magnet assemblies shown and descnbed herein are particulaily useful foi magnetic medical procedures, such as navigation and aneur ysm filling the invention is not so limited, and the magnetic assemblies can be used in any application where a vanable focused field is needed

Together the magnet cylinders 22 and 24 create a magnetic field in the operating legion O sufficient to magnetically navigate a medical device inside the body The operating region O is pieferably a generally cubic legion at least about 3 inches by about 3 inches by about 3 inches, and more pieferably at least about 6 inches by about 6 inches by about 6 inches The operating regron O rs preferably at least about 7 inches from the magnet cylinders 22 and 24, and more preferably at least about 10 inches from the magnet cylinders so that the operating region can be used to magnetically navigate magnetic materials anywhere in the body

The magnetic field created by the magnet cylmdeis 22 and 24 rs pieferably at least 0 1 T in any diiection in the plane of the magnetization directions of the cylinders by rotating the cylinders This is lllustiated in Figs 2a 2b 2c and 2d, wherem the magnet cylrnders 22 and 24 are shown in Fig 2a in a configuration that creates a magnetic field generally toward the magnet assembly, in Fig 2b in a configuiation that creates a magnet field parallel to the plane of the cylmdeis in Fig 2c in a configuiation that cieates a magnet field away from the magnet assembly and in Fig 2d in a configuratron that creates a magnet field in a direction parallel to the plane of the magnets, but opposite fiom the diiection shown in Fig 2b The magnetization direction of the magnet cylinders is lepi esented by the ar row superimposed over the cylinder, and the magnetic field diiection is lepresented by the arrow supei imposed ovei the box lepiesenting the opeiating region Is to be undei stood that arrangements of the magnetization of indi vrdual magnets beyond those of Figs 2a, 2b 2c 2d and aie possible and necessai y in order to pi o vide all directions of magnetic field in a plane pai allel to the magnets but Within the operating region 0 In othei vvoids the two magnets in ordinary use Will not have their magnetizations parallel as shown in these figuies

By rotating the assembly 20 about an axis R that is pei pendicular to the plane of the cylinders 22 and 24 a magnetic field direction can be created in the operating region in any diiection This is illustrated by compai ing Fig 1 and Fig 3, wheie rotation of the magnet assembly 20 rotates the magnetic field diiection in a plane parallel to the plane of the magnet cylinders

Thus thi ough a combination of I otations of the magnet cylindei s 22 and 24 about then iespective axes and the iotation of the assembly 20 about axis R a magnetic field can be cieated in the por tion of the body containing the operating legion 0 in any diiection, Without the need to tianslate the assembly 20 This means that exclusion zone aiound the magnet assembly 20 is much smallei than with othei types of magnets which must accommodate translations in all directions in the plane of the magnet in oider to provide all directions of field lines Thus, the assembly 20 allows foi bettei access to the patient and better accommodates othei equipment in the opeiating room, including imaging equipment such as bi plane fluoioscopic imaging equipment

A second embodiment of a magnet assembly, indicated geneially as 40, is shown schematically in Fig 4 The assembly 40 comprises three rotatably mounted, parallel magnet cylmdei s 42, 44, and 46 The cylinders 42, 44, and 46 are pieferably ai ranged in a plane Each of the cylinders 42, 44 and 46 is made from a permanent magnetic material, such as NdBFe, which as described below is prefeiably jacketed in stainless steel, caibon fibeis oi other strong, nonmagnetic material As descnbed above with respect to assembly 20, the cylinders 42 44 and 46 may have a circular cioss section oi a cross section of some other shape Each of the magnet cylinders 42, 44, and 46 is lotatable about its longitudmal axis Further, each of the magnet cylinders 42, 44, and 46 is preferably umfoi mly magnetized in one drrectron, peipendicular to its longitudmal axis As described above With respect to assembly 20, the magnetization may vaiy thiough the cylinders

Together the magnet cylinders 42 44 and 46 cieate a magnetic field in the operating region O sufficient to magnetically navigate a magnetic object, such as a medical device inside the body The opeiating region O is pieferably a generally cubic legion at least about 3 inches by about 3 inches by about 3 inches and moie piefeiably at least about 6 inches by about 6 inches by about 6 inches The opeiating i egion O is preferably at least about 7 inches from the magnetic cylinders, and moie piefeiably at least about 10 inches from the magnet cylinders 42, 44 and 46 so that it can be used to magnetically navigate magnetic matenals anywheie in the body

The magnetic field created by the magnet cylinders 42, 44, and 46 is preferably at least 0 1 T in any diiection in the plane of the magnetization directions of the cylinders, by iotating the cylinders This is illustrated in Figs 5a, 5b 5c and 5d, wheiein the magnet cylinders 42, 44 and 46 are shown in Fig 5a in a configuration that cieates a magnetic field geneially tovvaid the magnet assembly in Fig 5b in a configuration that cieates a magnet field paiallel to the plane of the cylindei s in Fig 5c in a configuration that creates a magnet field away fiom the magnet assembly and in Fig 5d in a configuration that creates a magnet field in a direction parallel to the plane of the magnets but opposite fiom the diiection shown in Fig 5b Is to be understood that an angements of the magnetization of individual magnets beyond those of Figs 5a 5b 5c 5d and are possible and necessary in oider to provide all dnections of magnetic field in a plane paiallel to the magnets but within the operating iegion 0 In other woids the thiee magnets in ordinal y use Will not have their magnetizations pai allel as shown in these figures By rotating the assembly about an axis R that is perpendicular to the plane of the cylinders 42 44, and 46, a magnetic field diiection can be cieated in the operating region in any direction This is lllusti ated by compai ing Fig 4 and Fig 6, wheie rotation of the magnet assembly 40 rotates the magnetic field diiection in a plane pai allel to the plane of the magnet cylinders 42 44 and 46 Thus, thiough a combination of i otations of the magnet cylinders 42, 44 and 46 about then iespective axes and the iotation of the assembly about axis R, a magnetic field can be cieated in the poition of the body containing the opeiating iegion 0 in any direction, without the need to translate the assembly 40 This means that exclusion zone around the magnet assembly 40 is much smaller than With other types of magnets which must accommodate some translation of the magnet Thus, the assembly 40 allows for better access to the patient, and better accommodates other equipment in the opei ting room, including imagrng equrpment such as bi plane fluoroscopic equrpment

The detarls of the preferred construction of the cylinders of the assemblies 20 and 40 are lllustiated in Figs 7 and 8 Each of the cylmdeis is preferably made from a stack of generally disk shaped pei manent magnets 60 Each of the disks 60 has a diameter of between about 4 inches and about 6 inches, and is between about Vz and about 2 inches thick As best shown in Fig 8, the disks 60 aie stacked one upon the other, inside a cylindncal jacket 62, made of stainless steel oi carbon fibers Thejacket 62 protects the disks 60, and helps to maintain their lntegπty despite the large forces to which they are exposed as cylinders rotate relative to one another To maintain the proper configuration of the disks and prevent lelatrve movement, the disks preferably have a flat 64 one the exteπoi that engages an insert 66 msrde the jacket 62, to "key" the drsks to facrlrtate rotatron

The cylmdeis comprising the assemblies of this invention aie preferably rotatable about then longitudinal axis The magnetization direction of the cylinders is preferably, but not necessarily uniform and preferably, but not necessarily, perpendrcular to the longrtudmal axrs

The iotation of the cylinders in the assemblies, allows the magnet cylinders to create a magnetic field in the operating iegion in any direction from 0° to 360° in the plane of the magnetization dnections of the cylinders Fuithermoie, pa ticularly with lespect to magnet assembly 40, the magnet cylindei s 42 44 and 46 can be arranged so that they create a stiong magnetic field in front of the assembly and in particular in the operating region O In this configuration, there is very weak magnetic field behind the assembly However, through rotation of the cylinders 42, 44, and 46, this can be leveised so that the strong field is behind the cylinders and the weak field in fiont of the assembly in effect "turning off" the magnet assembly from the peispective of the patient in front of the assembly

In the preleired embodiment, the magnet assembly would be contained within a relatively compact enclosure The rotation of the cylinders compnsing the assembly and the rotation of the assembl} allow the assembly to create a magnetic field in the operating iegion in the patient in any direction The enclosure hides the movement of the magnet, and protects the patient and other people and equipment in the opei ting l oom, fiom the magnet Because a change of direction of the magnetic field can be quickly and easily effected by rotating the magnet cylinders and the assembly itself, the assembly is particularly amenable to automatic controls. Servo controls can be provided to rotate the individual cylinders about their respective axes and to rotate the assembly about axis R. A direction can be input into a control system by the physician, for example using a mouse on the two images of a bi-planar fluoroscopic imaging system, or using a joystick or keyboard. A computer can then calculate the best combination of rotational directions of the cylinder magnetizations and rotation of the assembly to achieve the desired direction. The computer can even account for a desired lead angle to ensure the proper navigation of a magnetic object in the body. An automatic advancer can also be provided and coordinated by the computer control, so that once the proper magnetic field is applied, the object is advanced in the desired direction. Thus the magnet assembly of the present invention facilitates automating surgical procedures, and even facilitates telemedical procedures, where a procedure is performed by a physician remotely from the patient.

As shown in Fig. 9a through 9d, a compound system with two planar magnetic assemblies and can be provided. As shown in Figs. 9a and 9b, a compound system 100 has two planar magnetic assemblies 102 and 104 arranged at an angle with respect to each other. Thus the magnetic assemblies 102 and 104 form a concavity for receiving a portion of the body, such as the head. The combination of the two planes of magnet cylinders allows a stronger magnetic field to be applied further from the magnet assemblies. As shown in Figs. 9c and 9d, a compound system 150 has two planar magnetic assemblies 152 and 154 arranged in generally parallel orientation on opposite sides of a patient's body, for example on opposite sides of a patient's chest for conducting a cardiac procedure. Because each magnet assembly 152 and 154 only has to project a magnetic field halfway through the patient, and because each magnet assembly only has to contribute half of the desired magnetic field, the combined weight of the two magnet assemblies on opposite sides of the patient can be less than the weight of a single magnet assembly on one side of the patient projecting the same magnetic field strength.

Fig. 10 shows a compound assembly 200, comprising two planar magnetic assemblies 202 and 204, arranged for bi-planar fluoroscopic imaging of the procedure site. Imaging plates 206 and 208, such as an amorphous silicon imaging plates (which are substantially unaffected by magnetic fields), are disposed in front of each of the magnetic assemblies 203 and 204, respectively. Imaging beam sources, such as x-ray sources 210 and 212 are disposed to project an imaging beam through the patient and onto the imaging plates 206 and 208. Thus magnetic navigation can be provided while allowing access for fluoroscopic imaging.

A third embodiment of a magnet assembly constructed according to the principles of this invention as indicated generally is 220 in Figs. 1 la and 1 l b. The assembly 220 comprises at least three parallel, rotatably mounted magnet cylinders 222, 224 and 226. Each of the magnet cylinders 222, 224 and 226 is preferably constructed as described above, with a magnetization direction generally perpendicular to the longitudinal axis of the cylinder. The cylinders are arranged so they are not coplanar but instead form a concave portion for receiving a portion of the patient's body. As shown in Figs. 1 la and 1 l b, the cylinders 222. 224 and 226 form a concavity for receiving the patient's head. Rotation of the cylmdeis 222, 224, and 226 and rotation of the assembly (compaie Figs 1 la and 1 lb) allows the creation of a magnetic field in any selected dn ection in an operating I egion in the pai t of the patient in the space between the cylmdei s 222, 224 and 226

A fourth embodiment oi a magnet assembly constructed according to the principles of this invention is indicated geneially as 250 in Figs 12 and 13 The assembly 250 compnses thiee magnet cylinders 252 254 and 256, whose longitudinal axes aie coplanar Each of the magnet cylinders is piefei ably consti ucted as descnbed above, with a magnetization direction generally peipendicular to the longitudinal axis In this airangement, rotation of the cylinders 252, 254, and 256 can project a magnetic field in an operating region spaced from the plane of the cylinders in any direction Thus the magnet assembly 250 can piovide a navigating magnetic field in any direction without any tianslation oi iotation of the assembly, but simply a iotation of the cylinders 252, 254, and 256 comprising the assembly

A fifth embodiment of a magnet assembly constiucted according to the principles of this invention is indicated generally as 300 in Figs 14 and 15 The assembly 300 comprises three magnet cylinders 302, 304, and 306, arranged geneially in a "Y" shaped configuration Each of the magnet cylinders is preferably constructed as descrrbed above, wrth a magnetrzation dπ ection generally peipendiculai to the longitudinal axis The magnet cylinders 302, 304, and 306 may be coplanar, oi as shown in Figs 14 and 15, the magnet cylinders may be arranged in a pyramid, with one end of each of magnet cylinders at the apex of the pyramid In this anangement, the cylinders form a concave space for leceiving a poition the patient's body The magnet assembly 300 can provide a navigating magnetic field in any direction without any translation or rotation of the assembly, but simply a rotation of the cylinders 302, 304, and 306

A sixth embodiment of a magnet assembly consti ucted accoi ding to the pi inciples of this invention is indicated generally as 350 in Figs 16a through 16d The magnet assembly comprises four magnet cylmdeis 352, 354, 356, and 358 The first magnet cylinder 352 extends generally transveisely acioss the top of the user's body, below the chest The second magnet cylinder 354 extends generally tiansversely below the patient's body, above the shoulders The third magnet cylinder 356, extend generally paiallel with the longitudinal of the patient, above the right side of the patient's chest The fourth magnet cylinder 358 extends generally paiallel With the longitudinal axis of the patient, below the l lght side of the patient's chest The left end of the cylindei 352 extends over the bottom end of the cylinder 356, and the cylinder slopes downwardly toward the right side The right end of the second magnet cylindei 354 is above the uppei end cylindei 358 and the cylinder slopes downwardly towaid the lelt side Each of the cylmdei s is piefeiably consti ucted as described above, with the magnetization diiection genei ally perpendiculai to the longitudinal axis of the cylinder The first and second cylinders 352 and 354 and the thud and fourth cylinders 356 and 358, are arranged on opposite sides of the heait while leaving the heart uncovei ed so that the heait can be imaged during the procedure Rotation of the cylmdei s 352, 354, 336 and 358 allows the ueation of a magnetic field in any selected diiection in the opei ating iegion (the heart in Figs 16a-16d) An eighth embodiment of a magnet assembly consti ucted according to the principles of this invention is indicated generally as 400 in Figs 17a and 17b The magnet assembly 400 compnses fi st and second cylinders 402 and 404 beneath the patient, the fust roller extending genei ally below the shouldei s at the top of the chest, and the second cylindei extending geneially below the nb cage at the bottom of the chest The cylinders aie consti ucted as described above, ith the magnetization diiection genei ally peipendicular to the longitudinal axis of the cylinder The magnet assembly 400 further compnses thud and fourth rollers 406 and 408 (shown only in Fig 17b), extending parallel to the longitudinal axis of the patient on eithei side of the patient, above the patient's arms The cylindei s 402 and 404 aie spaced such that an imaging beam source below the patient, and an imaging plate, such as an amorphous silicon imaging plate 410 above the patient, can image the heart H without inteifeience horn the cylinders Rotation of the cylinder s 402, 404, 406, 408 allows the creation of a magnetic field, in any selected diiection in the opeiating region (the heait in Figs 17a and 17b)

An eight embodiment of a magnet assembly constructed according to the pi inciples of this invention is indicated generally as 450 in Figs 18a and 18b The assembly 450 is similar in consti uction to assembly 400, compnsing first and second cylinders 452 and 454, extending geneially tiansveisely across the patient's body However, unlike assembly 400 wherein the first and second cylindei s 402 and 404 aie below the patient, cylinders 452 and 454 are above the patient The magnet assembly 450 also includes third and fourth magnet cylinders 456 and 458, which like cylinders 406 and 408 of assembly 400 extend parallel to the longitudinal axis of the patient, on eithei side of the patient above the patient's arms The cylinders 452 and 454 are spaced such that an imaging beam souice below the patient, and an imaging plate, such as an amorphous silicon imaging plate 460 above the patient, can image the heait without interference from the cylinders The assembly 450 is paiticularly adapted to be mounted on a ceilrng support, and lowered into position ovei the patrent, and rarsed away from the patrent after completion of the procedure Rotatron of the cylrnders 452, 454, 456 and 458 allow the creation of a magnetic field in any selected direction of the operating region (the heart in Figs 18a and 18b)

A ninth embodiment of a magnet assembly constiucted according to the principles of this invention is indicated generally as 500 in Figs 19a, 19b, and 19c As shown in Figs 19a through 19c the magnet assembly comprises at least two magnets, at least one of which is rotatable with respect to the other to change the direction and/oi intensity of the magnetic field in an operating region spaced from the face 510 of the assembly, preferably along a central peipendicular axis 508 In the preferred embodiment there aie thiee magnets 502, 504, and 506 As shown in Figs 19a through 19c the magnets 502 and 504 are stationery and magnet 506 is mounted tor rotation relative to the magnets 502 and 504 As shown in the Figures, the magnets 502 and 504 are formed in one piece, with an opening for receiving the magnet 506, but the invention is not so limited, and magnets 502 and 504 can be made in separate pieces The magnet 502 is prefei ably magnetized parallel to the axis 508, and perpendiculai to the face 510 of the assembly The magnet 504 is likewise preferably magnetized pai allel to the axis 508, and peipendicular to the face 510 of the assembly but in a direction opposite to magnet 502 As shown in Figs 19a through 19c the magnet 506 i preferably cylindrical (although it could be some other shape), and mounted for rotation about its longitudinal axis The magnet 506 is piefeiably magnetized peipendiculai to its axis of iotation

As shown in Figs 19a thiough 19c the iotation of the magnet 506 relative to the magnets 502 and 504 changes the magnetic field projected by the assembly Thus by rotating the magnet 506 and by rotating the assembly 500 about axis 508 a magnetic field of sufficient strength foi magnetic navigation of a magnet medical device can be piojected in vntually any diiection at an operating point space f l om the face 510 of the assembly

Oper tion

In using the assemblies of this invention, a magnetically responsive medical device is intioduced into the body This device may be a cannula, catheter, endoscope or other device that is magnetically responsive through the inclusion of an electiomagnet, a permanent magnet, or a per meable magnetrc material The device is oriented in a desired direction by applying a magnetic held rn the appropriate directron to cause the devrce to alrgn rn the desired drrectron The applred field may be slightly different from the desired dnectron because of the properties of the device Where the navigation is computei controlled, the computer can automatrcally take the properties of the device into account in detei mining the direction of the magnet field to apply The magnet cylinders aie turned and the magnet assembly is turned (wheie necessary) until the device is in the desired direction The device can then be advanced, eithei manually oi automatically, using an advancei The device is advanced until a change of diiection is desired The assembly is used to apply a magnetic field to cause the device to orient in the new desired directron, and the device again advanced This is repeated until the device is in the desned location

Claims

We claim

1 A magnet assembly that projects a magnet field of variable diiection the assembly compnsing at least two magnets at least one of which is rotatably mounted for rotation to change the dii ection of the magnetic field piojected by the assembly

2 The magnet assembly accoiding to claim 1 wherein the magnet assembly piojects a magnetic field oi sufficient stiength to onent a magnetic medical device

3 The magnet assembly according to claim 1 wheiein the magnet assembly projects a magnetic field of at least 0 1 Tesla at a sufficient drstance fiom the assembly to orrent a medrcal devrce in a body

4 T he magnet assembly accoiding to claim 1 wheiein there are two magnets one of which is totatably mounted

5 The magnet assembly accoiding to claim 1 wheiein there are two magnets both of which aie totatably mounted

6 The magnet assembly accoiding to claim 5 wheiein the axes or rotation of the two magnets are parallel

7 The magnet assembly accoiding to claim 1 wherein there aie at least thiee magnets ananged genei ally in a plane and wherein theie is at least one rotatably mounted magnet with a non- rotatably mounted magnet on either side of the at least one rotatably mounted magnet

8 The magnet assembly according to claim 1 wherein there aie three magnets ananged geneially in a plane and wheiein all three of the magnets are rotably mounted

9 The magnet assembly accoiding to claim 9 wherein the axes of rotation of the magnets aie parallel

10 A magnet assembly that piojects a magnet field of variable directron in an opeiating zone spaced horn the assembly sufficiently so that the opeiating zone can be disposed inside a body foi navigating a magnet medical device the assembly comprising at least two magnets at least one of which is lotatably mounted for iotation to change the direction of the magnetic field projected by the assembly

1 1 The magnet assembly according to claim 10 wherem the magnet assembly projects a magnetic field of sufficient strength to onent a magnetic medical device

12 The magnet assembly according to claim 10 wherein the magnet assembly projects a magnetic field of at least 0 1 Tesla in the operation zone

13 The magnet assembly accoiding to claim 10 wherein theie are two magnets, one of which is iotatably mounted

14 The magnet assembly according to claim 10 wherein there aie two magnets both of w hich are rotatably mounted

15 The magnet assembly according to claim 14 wheiein the axes of rotation of the two magnets aie parallel

16 The magnet assembly according to claim 10 wherein there aie at least three magnets ananged generally in a plane and heiein theie is at least one iotatably mounted magnet with a non- lotatαbl) mounted magnet on eithu side ot the at least one iotatably mounted magnet L7 The magnet assembly accoiding to claim 10 wherein there are three magnets, an anged genei ally in a plane, and wheiein all thi ee of the magnets ai e l otably mounted

18 The magnet assembly according to claim 17 wherein the axes of rotation of the magnets aie pai allel

19 An adjustable field magnet assembly comprising at least two magnets iotatably mounted so that the rotation of at least one of the at least two iotatably mounted magnets changes the magnetic field piojected by magnet assembly in an operating region spaced from the assembly

20 The adjustable field magnet assembly according to claim 19 wheiein the magnets aie generally cyhndi ical per manent magnets fabricated from a pnmarily high-intrinsic coercive force matenal with a large residual induction field

21 The adjustable field magnet assembly according to claim 19 wheiein there are at least thiee rotatably mounted magnets

22 The adjustable field magnet assembly according to claim 19 wheiein the diiection of magnetization of the magnets is geneially peipendicular to the axis of rotation

23 The adjustable field magnet assembly according to claim 19 wherein the diiection of magnetization of each the magnets is unifotm

24 The adjustable field magnet assembly according to claim 19 wheiein the direction of magnetization of each of the magnets is not unifoi m

25 The adjustable field magnet assembly accoiding to claim 19 wherein theie aie at least thiee rotatably mounted magnets, ananged in a plane

26 The adjustable field magnet assembly according to claim 19 wheiein the magnets aie peimanent magnets fabricated from a primarily high-rntπnsrc coeicive force material with a large iesidual inductron field

27 The adjustable field magnet assembly according to claim 19 wheiein the magnets aie electromagnets

28 The adjustable field magnet assembly according to claim 19 wherein there are at least thiee magnets ananged in a first plane, and at least three magnets ai ranged in a second plane, the first plane being adjacent to, and at angle with tespect to the second plane, to define a treatment space therebetween

29 An adjustable field magnet assembly compnsing at least first and second magnet bodies, at least one of hich is lotatable to change the magnetic field applied at an operating point spaced from the assembly

30 A method of controlling a magnetically responsive element in the body, the method compnsing applying a magnetic field to the object with a vanable field magnet assembly having at least two rotatable magnetic elements, and changing the direction of the magnetic field applied to the object by rotating at least one of the two iotatable magnetic elements

31 The method of controlling a magnetically responsive element in the body accoiding to claim 30, further compnsing rotating the magnetic assembly

32 The method accoiding to claim 30 wherein the magnet assembly compnses at least two magnet elements rotatably mounted on paiallel axes 33 The method accoiding to claim 30 wherein the magnet assembly comprises at least thiee magnets arranged in a plane, and lotably mounted on parallel axes

34 The method accoiding to claim 30 wheiein a processor calculates the optimal combination of directions of magnetization of the individual magnets comprising the assembly so as to maximize the field stiength at a given location in a patient, and further compnsing lotating the magnets to the calculated combination oi directions of magnetization of the individual magnets to yield the maximum field stiength

35 The method of claim 30 wheiein a processor calculates the optimal combination of directions so as to include at least two successive motions of a guided element