Patent Publication Number: US-2022219006-A1

Title: Magnetic resting apparatus with compressed static magnetic fields

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application is a divisional of U.S. application Ser. No. 17/509,309 filed on Oct. 25, 2021, which is a continuation in part of U.S. application Ser. No. 17/174,980 filed on Feb. 12, 2021, which claims the benefit of U.S. Provisional Application 62/989,022 filed on Mar. 13, 2020. The disclosures of the prior filed applications are incorporated herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     The disclosure of the present patent application relates to a sleeping/resting apparatus with compressed static magnetic fields for stimulating the immune system. Specifically, the instant invention is directed to a sleeping/resting apparatus with embedded static magnets for stimulating user while user is sleeping/resting within. Further, the instant invention is directed a sleeping capsule for astronauts to rest in a weightless/gravity free environment, provides protection against harmful rays in the outer space, and also stimulating astronauts&#39; immune system. The instant invention further applies compressed magnetic fields to the surrounding tissues of any damaged or abnormal tissues, which stimulates the sleeper&#39;s immune system in the healthy tissues for repairing the damaged or abnormal tissues. 
     Malignant tumors are presently treated by a variety of different methods, including, but not limited to, chemotherapy, radiation therapy, surgery, immunotherapy and laser therapy. Although proven to be effective, each of these methods is typically seen to be undesirable for the patient due to the inherent risks of the treatment itself as well as the various negative side effects associated with each treatment. Each of these methods is also costly, time consuming and requires highly specialized equipment and medical practitioners. 
     The use of non-ionizing magnetic fields to treat tumors has shown promise in a number of in vitro and animal studies. Such treatment is not painful, relies only on conventional magnets or electromagnets and, unlike chemotherapy and ionizing radiation treatments, does not also harm normal tissues. Similarly, blocking tumor blood vessel growth, and the associated starving of tumors of their blood supply, is of great interest for tumor treatment due to the lack of damage to healthy tissue and general absence of pain and side effects for the patient. It would obviously be desirable to be able to effectively treat tumors using non-invasive and easily administered magnetic techniques. Thus, a method of treating tumors and causing full regrowth and regeneration of tissue solving the aforementioned problems is desired. 
     SUMMARY OF THE INVENTION 
     The devices and methods of stimulating the immune system to treat damaged and abnormal tissue using compressed static magnetic fields provides for noninvasive treatment of damaged tissue, removal of abnormal tissue, and regrowth of the tissue. 
     The present invention provides a sleeping/resting apparatus with compressed static magnetic fields for stimulating the immune system. Specifically, the instant invention is directed to a sleeping/resting apparatus with embedded static magnets for stimulating user while user is sleeping/resting within. Further, the instant invention is directed a sleeping capsule for astronauts to rest in a weightless/gravity free environment, provides protection against harmful rays in the outer space, and also stimulating astronauts&#39; immune system. The present invention applies compressed magnetic fields to the surrounding tissues of any damaged or abnormal tissues while the user rests in the apparatus of the present invention, which stimulates the sleeper&#39;s immune system in the healthy tissues for repairing the damaged or abnormal tissues. 
     At least two magnets are positioned to have their magnetic fields intersect at the damaged or abnormal tissue and the immediately surrounding healthy tissue while the user rests in the apparatus. The compressed magnetic fields stimulate the immune system in the immediately surrounding healthy tissue which treats the damaged or abnormal tissue. The treated tissue fully regenerates without additional medical intervention. The devices provide for efficient exposure to compressed magnetic fields and ease of use for different locations on a human body, as well as multiple animal species. 
     These and other features of the present subject matter will become readily apparent upon further review of the following specification. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1A  is a perspective view of a magnetic therapy helmet. 
         FIG. 1B  is side view of the magnetic therapy helmet of  FIG. 1 . 
         FIG. 1C  is a bottom view of the magnetic therapy helmet of  FIG. 1 . 
         FIG. 2  is a sectioned view of the magnetic therapy helmet of  FIG. 1  when on a user&#39;s head, showing the magnetic fields produced by the magnets of the helmet. 
         FIG. 3  is a perspective view of magnetic therapy system including the magnetic therapy helmet of  FIG. 1A  and a magnetic therapy mouth guard. 
         FIG. 4  is an environmental view of the magnetic therapy system of  FIG. 3  being worn by a user. 
         FIG. 5  is an environmental view of a magnetic therapy head harness being worn by a user. 
         FIG. 6  is a perspective view of the magnetic therapy head harness of  FIG. 5 . 
         FIG. 7  is a rear view of the magnetic therapy head harness of  FIG. 5 . 
         FIG. 8  is a top view of a magnetic therapy hat. 
         FIGS. 9-10  are opposing side views of the magnetic therapy hat of  FIG. 8 . 
         FIG. 11  is a bottom view of the magnetic therapy hat of  FIG. 8 . 
         FIG. 12  is an environmental view of the magnetic therapy hat of  FIG. 8  being worn by a user. 
         FIG. 13  is a sectioned view of the magnetic therapy hat of  FIG. 8  on a user&#39;s head and the magnetic therapy mouth guard of  FIG. 3  in the user&#39;s mouth, showing the magnetic fields produced by the magnets of the helmet and mouthguard. 
         FIG. 14A  is a top view of a second embodiment of a magnetic therapy hat. 
         FIG. 14B  is a diagram showing placement of the magnets within the hat of  FIG. 14A . 
         FIG. 15  is a sectional view of a head of a patient wearing the helmet of  FIG. 1  for treating Alzheimer&#39;s. 
         FIG. 16  is an environmental view of magnetic therapy belts being worn by a dog. 
         FIG. 17  is a bottom view of the belts of  FIG. 16 . 
         FIG. 18A  is a sectioned view of the magnetic therapy belt and dog of  FIG. 16  taken at line  18 A. 
         FIG. 18B  is a sectioned view of the magnetic therapy belt and dog of  FIG. 16  taken at line  18 B. 
         FIG. 19  is an overhead perspective view of a magnetic therapy muzzle. 
         FIG. 20  is a perspective view of the magnetic therapy muzzle of  FIG. 19  from below. 
         FIG. 21  is a perspective view of the magnetic therapy muzzle of  FIG. 19  from the side. 
         FIG. 22  is a perspective view of the magnetic therapy muzzle of  FIG. 19  from the front. 
         FIG. 23  is an environmental view of the magnetic therapy muzzle of  FIG. 19  being worn by a dog. 
         FIG. 24  is a perspective view of a magnetic therapy jock from the front. 
         FIG. 25  is a perspective view of the magnetic therapy jock of  FIG. 24  from the rear. 
         FIG. 26  is a perspective view of a rectal magnetic therapy device. 
         FIG. 27  is a perspective view of the rectal magnetic therapy device of  FIG. 26  from below. 
         FIG. 28  is an exploded view of the rectal magnetic therapy device of  FIG. 26 . 
         FIG. 29  is a perspective view of a vaginal magnetic therapy device. 
         FIG. 30  is a perspective view of the vaginal magnetic therapy device of  FIG. 29  from below. 
         FIG. 31  is an exploded view of the vaginal magnetic therapy device of  FIG. 29 . 
         FIG. 32  is an environmental view of a gastrointestinal magnetic therapy device within a frontal, sectioned view of a human body. 
         FIG. 33  is an environmental view of the gastrointestinal magnetic therapy device of  FIG. 32  within a rear, sectioned view of a human body. 
         FIG. 34  is a zoomed in environmental view of the gastrointestinal magnetic therapy device of  FIG. 32  within a sectioned view of a human gastrointestinal tract. 
         FIG. 35  is an overhead view of a dual magnetic therapy support positioned adjacent a sectioned view of a human body. 
         FIG. 36  is an environmental view of a severed spinal cord being exposed to a compressed magnetic field. 
         FIG. 37  is a perspective view of a fully body magnetic therapy stand. 
         FIGS. 38-40  are environmental views of the fully body magnetic therapy stand of  FIG. 37  with a patient in different positions. 
         FIG. 41A  is an overhead, environmental view of a magnetic bed for use with a fully body magnetic therapy system. 
         FIG. 41B  is a diagram of a full body magnetic therapy system including a magnetic bed and magnetic table. 
         FIG. 41C  is a front view of the full body magnetic therapy system of  FIG. 41B . 
         FIG. 41D  is a top view of an embodiment of magnetic module including an array of magnets, the magnetic module can be embedded in the full body magnetic therapy system, bed, or tray. 
         FIG. 41E  is a front view of the embodiment in  FIG. 41D . 
         FIG. 41F  is a zoom-in view of each magnet in the magnetic module in  FIG. 41D . 
         FIG. 42A  is an overhead view of a mounting magnet. 
         FIG. 42B  is a sectioned view of the mounting magnet of  FIG. 42A  along line  42 B. 
         FIG. 43A  is an overhead view of an embodiment of a full body magnetic therapy system including a magnetic bed and magnetic table. 
         FIG. 43B  is a section view of the full body magnetic therapy system of  FIG. 43A  taken along line  43 B. 
         FIG. 43C  is a zoomed-in, sectioned view of the full body magnetic therapy system of  FIG. 43A  taken along line  43 B, detailing a magnet and its respective actuator. 
         FIG. 43D  is a view of magnetic therapy system frame with magnets. 
         FIG. 44A  is an environmental perspective view of an embodiment of a full body magnetic therapy system. 
         FIG. 44B  is an environmental perspective view of an embodiment of a full body magnetic therapy system. 
         FIG. 44C  is a top view of an embodiment of a full body magnetic therapy system with a body scanner. 
         FIG. 44D  is a side view of the full body magnetic therapy system with the body scanner in operation. 
         FIG. 45  is a perspective view of a magnetic therapy collar. 
         FIG. 46  is an environmental, perspective view of the magnetic therapy collar of  FIG. 45 . 
         FIG. 47  is a perspective view of second embodiments of a magnetic therapy muzzle. 
         FIG. 48  is an overhead view of the magnetic therapy muzzle of  FIG. 47 . 
         FIG. 49  is an environmental view of the magnetic therapy muzzle of  FIG. 47 . 
         FIG. 50A  is a perspective view of an embodiment of a magnetic therapy mouth guard. 
         FIG. 50B  is a perspective view of a second embodiment of a magnetic therapy mouth guard. 
         FIG. 51  is perspective view of an electronic, magnetic mouth treatment system. 
         FIG. 52  is an overhead view of an embodiment of magnetic therapy knee brace in an unwrapped configuration. 
         FIG. 53  is a perspective view of the magnetic therapy knee brace of  FIG. 52  with one of the magnets and articulating member removed for illustration. 
         FIG. 54  is an environmental view of the magnetic therapy knee brace of  FIG. 52  wrapped around the knee of a user. 
         FIG. 55  is a perspective view of a magnetic therapy crate with the lid opened. 
         FIG. 56  is an environmental perspective view of the magnetic therapy crate of  FIG. 55 . 
         FIG. 57  is a perspective view of a magnetic vest. 
         FIG. 58  is a front view of the magnetic vest of  FIG. 57 . 
         FIG. 59  is a back view of the magnetic vest of  FIG. 57 . 
         FIG. 60  is a sectional side view of the magnetic vest of  FIG. 57 . 
         FIG. 61  is a perspective view of a magnetic sleeping pod from the front. 
         FIG. 62  is a perspective view of the magnetic sleeping pod of  FIG. 61  from the rear. 
         FIG. 63  in an overhead view of a sleeping unit, containing magnetic sleeping pods of  FIG. 61 , docked with a spacecraft. 
         FIG. 64  is a cross sectional view of the sleeping unit of  FIG. 63 . 
         FIG. 65A  shows a front view of a magnetic therapy bra. 
         FIG. 65B  shows a rear view of the magnetic therapy bra of  FIG. 65A . 
         FIG. 66A  shows an environmental, front view of the magnetic therapy bra of  FIG. 65A  being worn on a patient. 
         FIG. 66B  shows an environmental, side view of the magnetic therapy bra of  FIG. 65A  being worn on a patient. 
         FIG. 66C  shows an environmental, rear view of the magnetic therapy bra of  FIG. 65A  partially removed from a patient. 
         FIG. 66D  shows an environmental, side view of the magnetic therapy bra of  FIG. 65A  partially removed from a patient. 
         FIG. 67  shows a diagram of polarized neutron imaging device imaging magnetic fields within a human. 
         FIG. 68  shows an embodiment of a static magnetic quantitative electroencephalography system. 
         FIG. 69A  is a perspective view of a dog having a mast cell tumor on it lip, prior to magnetic treatment. 
         FIG. 69B  is a perspective view of the dog of  69 A receiving magnetic treatment on the mast cell tumor and immediately surrounding healthy tissue. 
         FIG. 69C  is a perspective view of the dog of  FIG. 69A  after magnetic therapy which caused the mast cell tumor to become necrotic and fall off. 
         FIG. 69  D is a perspective view of the dog of  FIG. 69A  one month after completion of magnetic therapy, showing full lip regrowth. 
         FIG. 70  is a perspective view of a plasma globe with two attached ring magnets. 
         FIG. 71  is a zoomed in view of the plasma globe and attached magnets of  FIG. 70  based on box  71 . 
         FIG. 72  is a perspective view of the plasma globe and attached magnets of  FIG. 70  when a user is touching the magnets. 
         FIG. 73  is a perspective view of the plasma globe and attached magnets of  FIG. 70  for the user&#39;s point of view. 
         FIG. 74  is a perspective view of the plasma globe and an attached ring magnet when a user is toughing the magnet. 
         FIG. 75  is a perspective view of the plasma globe and an attached mounting magnet. 
         FIG. 76A  shows a strong side of an embodiment of a magnet. 
         FIG. 76B  shows a peripheral side of the magnet of  FIG. 76A . 
         FIG. 76C  shows the weak side of the magnet of  FIG. 76A . 
         FIG. 77  shows a rocket suitable for the sleeping capsule according to the present invention. 
         FIG. 78A  shows a top view of the sleeping capsules arrangement from a horizontal cross section of the rocket in  FIG. 77 . 
         FIG. 78B  is a zoom-in enlarged view of the capsule arrangement from the  FIG. 78A . 
         FIG. 78C  is another zoom-in enlarged view of the capsule arrangement from the  FIG. 78A . 
         FIG. 78D  shows a user standing on the sleeping capsules. 
         FIG. 78E  shows the outer shell of the rocket as shown in the  FIG. 77 . 
         FIG. 78F  shows users standing on both top and bottom of the single-deck sleeping capsule. 
         FIG. 78G  is an enlarged view of the magnetic socks that users wear. 
         FIG. 78H  shows users standing on both top and bottom of the double-deck sleeping capsule. 
         FIG. 78I  shows magnetic socks users wear to standing on the sleeping capsule. 
         FIG. 79A  shows a sleeping cell according to the present invention. 
         FIG. 79B  shows a sleeping cell as shown in the  FIG. 79A  with its door opened. 
         FIG. 79C  shows a top view of multiple sleeping cells arranged within a rocket from a horizontal cross section of the rocket. 
         FIG. 79D  shows an enlarged view of the sleeping cell from the  FIG. 79C . 
         FIG. 79E  shows a cross view of multiple sleeping cells arranged within a rocket from a vertical cross section of the rocket. 
         FIG. 79F  shows a perspective view of the multiple sleeping cells arrangement from  FIG. 79C . 
         FIG. 79G  shows the resting bed in the sleeping cell as illustrated in  FIGS. 79A and 79C . 
         FIG. 79H  shows the resting bed in the sleeping cell as illustrated in  FIGS. 79A and 79C . 
         FIG. 79I  shows a user resting in the bed with the face down. 
         FIG. 79J  shows a user resting in the bed the face up. 
         FIG. 79K  shows the tract mechanism for facilitating sliding motion of the upper tray of the bed. 
         FIG. 79L  is a perspective view of the bed according to the present invention. 
         FIG. 79M  shows the bed from the  FIG. 79L  with an inflatable cushion. 
         FIG. 79N  shows the bed and the inflatable cushion from the  FIG. 79M  with the inflatable cushion been inflated. 
         FIG. 79O  shows a user rests in bed with the inflatable cushion. 
         FIG. 79P  shows the user rests in bed from the  FIG. 79L  with the inflatable cushion inflated. 
         FIG. 79Q  is a view from the user head as user rests in bed as showed in  FIG. 79O . 
         FIG. 79R  is a view from the user head as user rests in bed as showed in  FIG. 79P . 
         FIG. 80  shows the sleeping capsule as shown in  FIG. 79C  ready to connect to a space station. 
         FIG. 81  is an embodiment of a magnetic device according to the present invention. 
         FIG. 82  shows a position on a user&#39;s forearm where discomfort occurs. 
         FIG. 83  shows a first view where the magnetic device is position on the forearm. 
         FIG. 84  shows a second view where the magnetic device is position on the forearm. 
         FIG. 85  shows a third view where the magnetic device is position on the forearm. 
         FIG. 86  shows an embodiment of chair with a user on it. 
         FIG. 87  shows the magnetic field from the chair shown in  FIG. 86 . 
         FIG. 88  shows a first view of the chair shown in  FIG. 86 . 
         FIG. 89  shows a second view of the chair shown in  FIG. 86 . 
         FIG. 90  shows a third view of the chair shown in  FIG. 86 . 
         FIG. 91  shows a fourth view of the chair shown in  FIG. 86 . 
         FIG. 92  shows a fifth view of the chair shown in  FIG. 86 . 
         FIG. 93  shows a top view a foot treatment device according to the present invention. 
         FIG. 94  shows the foot treatment device from  FIG. 93  with its side penal flat down. 
         FIG. 95  is a top view of the foot treatment device from  FIG. 93 , and a side view of the device while treating a foot. 
         FIG. 96  shows a front view of an embodiment of helmet according to present invention. 
         FIG. 97  shows a side view of the helmet from  FIG. 96 . 
     
    
    
     Similar reference characters denote corresponding features consistently throughout the attached drawings. 
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The method of stimulating the immune system to treat damaged or abnormal tissue involves providing compressed, static magnetic fields, from static magnetics, in the area immediately surrounding the damaged or abnormal tissue, and on the damaged or abnormal tissue (“treatment tissue”). By compressing the static magnetic fields, a condensed, static magnetic field is formed in the area of the compressed fields. A condensed, static magnetic field interacts with the electrical charges and/or currents present in the healthy tissue surrounding the treatment tissue, which stimulates the patient&#39;s immune system in the healthy tissue. For example, the condensed, static magnetic field may draw electrical current to the targeted health tissue which in turn stimulates the immune response of the healthy tissue. The stimulated immune response from the healthy tissue located adjacent the treatment tissue will act on the treatment tissue to remove abnormal tissue, as well as provide tissue repair and regeneration. In many scenarios, the interaction between the compressed static magnetic field and the tissue will provide an increased presence of stem cells. 
     Any embodiment of the device and methods for stimulating the immune system to treat damaged or abnormal tissue using compressed static magnetic fields may use mounting magnets to produce the static magnetic fields. A mounting magnet is static magnet surrounded by a spacer (typically a polymer) and a steel (or other non-magnetically charged magnetic materials) cup. The steel cup extends over one pole (“weak pole”) of the magnet to direct the magnetic field towards the opposing pole (“strong pole”), thus resulting in a more powerful static magnetic field extending out from strong pole of the magnet. Accordingly, in some embodiments, the strong pole of the magnets will be directed at the treatment tissue, which will also encompass the healthy tissue immediately surrounding the treatment tissue. Any discussion of directing magnetic fields in the below description is referring to pointing the strong pole of a mounting magnet in that direction. In some embodiments, the magnets may be oriented so the compressed magnetic fields are all north pole magnetic fields, all south pole magnetic fields, or a combination of the two. In some non-limiting embodiments, the magnets may have a width and length in the range of 1 to 10 inches, a thickness in the range of 0.25 to 2 inches, a central opening in the range of 0.25 to 2 inches, and/or a grade in the range of N42 to N55. Magnets with higher grades may be used when they become available. 
     The strength of the static magnetic field at the treatment tissue and immediately surrounding treatment tissue is related to the distance between the magnet and the target tissue. Accordingly, the magnets may be secured at locations that provide the shortest distance between the magnet and the treatment tissue, which will provide the strongest magnetic field to the healthy tissue immediately surrounding the treatment tissue. The following Figures depict non-limiting embodiments of magnetic therapy devices which may be used to provide compressed, static magnetic fields (condensed magnetic fields) in treatment tissue and the healthy tissue immediate surrounding the treatment tissue for different treatment sites on multiple types of patients (humans, dogs, or any other mammal). 
       FIGS. 1A-1C  depict an embodiment of a magnetic therapy helmet  100  for providing compressed static magnetic fields to a head of a user. The helmet  100  may be any device that provides a rigid body for supporting magnets around a patients head. For example, in some non-limiting embodiments, the helmet  100  may be hard hat, as seen in  FIG. 1-3 , a hockey helmet, a football helmet, or a bicycle helmet. Static magnets  110  may be attached to the inside of the helmet by a nut and bolt connection  120 , as seen in  FIGS. 1-4 , or any connection known in the art. In some embodiment, the connections  120  may be removable to allow a user to adjust the location of the magnets based on the needs of a patient. Each of the magnets  110  may be directed inwards towards the area a head would reside within the helmet  100 . 
     The non-limiting magnet  110  locations shown in  FIG. 1C  may be used for treating a damaged or abnormal tissue, such as a tumor (T), on the left side of a patient&#39;s brain. Each magnet  110  may be connected perpendicular to the curvature of the helmet body  102  at its location of attachment, to provide compressed, static magnetic fields in the left side of a patient&#39;s brain when the helmet  100  is being worn. As previously discussed, if the exact location of the treatment tissue is known, the magnets  110  can be moved to locations that provide maximum strength compressed, static magnetic fields at the healthy tissue immediately surrounding the treatment tissue, as well as on the treatment tissue. For example, the magnets  110  can be connected to the multiple holes defined in the hard hat, or new holes may be created for custom attachment. 
       FIG. 2  depicts a magnetic therapy helmet  100  configuration similar to the embodiments of  FIGS. 1-3  with the magnets  100  on pivotable bushings  130  for directing the static magnetic fields. One or more of the magnets  100  may be attached to a bushing  130  at an angular offset. As a result, rotating the bushing  130  will change the direction of the static magnetic field. As seen in  FIG. 4 , two or more magnets  110  may be strategically pointed so their magnetic fields are compressed at the healthy tissue immediately surrounding the treatment tissue and on the treatment tissue, which in the case of  FIG. 4  is a tumor (T). Other methods known in the art may be used for pivoting the magnets  110  to adjust the direction of their magnetic field such as a ball joint or a dial axis hinge joint. 
       FIGS. 3-4  shows a magnetic therapy system including a magnetic therapy helmet  100  and a magnetic therapy mouth guard  140 . The helmet  100  may produce static magnetic fields directed horizontally inwards and downwards. To provide an additional compressed magnetic field, a mouth guard  140  having a magnet  110  directed upwards may be worn by a user. In some embodiments, the magnet  110  on the mouth guard  140  may be pivotable for directing the magnetic field towards the exact location of the treatment tissue. For example, as shown in  FIG. 1B , the mouth guard magnet  100  may be connected to the mouth guard body  142  by a ball joint  144 . In alternate embodiments, the magnet  110  may be connected to the mouth guard body  142  by any pivotable connector known in the art.  FIG. 4  shows a user be treated with the helmet  100  being worn on a top of the head and the mouth guard  140  being inserted into the mouth with the magnet facing upwards. 
       FIGS. 5-7  depict a magnetic head harness  200  for holding magnets  210  at a base of a patient&#39;s brain. The harness  200  may include a rigid body  230  with flexible upper support straps  220 . The rigid body  230  may include an adjustment mechanism  232  for accommodating different sized heads. For example, as seen in  FIG. 7 , a dial  234  may be rotated to increase and decrease the circumference of the body  230 . The straps  220  may also be adjustable for properly positioning a height of the magnets  210 . The magnets  210  may be attached to the rear portion of the rigid body  220  and oriented with the strong pole facing inwards (towards the head). 
     The head harness  200  shown in  FIGS. 5-7  may be used to treat abnormal or damaged tissue in the cerebellum or brain stem. An example of a disease treated by the head harness may be ataxia, which is degeneration of the cerebellum. In other embodiments, magnets  210  may be attached to any location of the rigid body  230  based on the location of the treatment tissue. The magnets  210  may be positioned so the treatment tissue is being exposed to a maximum strength compressed magnetic field though approximating the magnets  210  to the treatment tissue and adjusting the direction at which the strong pole of the magnetic  210  is directed. In some embodiments, the magnets may be 3 inches in diameter. 
       FIGS. 8-15  depict a magnetic hat  300  which may be used to provide static magnetic fields that compress within a head of a user. In the embodiment shown in  FIGS. 8-13 , the hat  300  may include five magnets  310 , one magnet  310  for positioning directly on top of the head and one magnet  310  for positioning on each of the front, back, left side, and right sides of the head. Each magnet  310  may be attached to the hat through any means known in the art, such as a nut and bolt connection  312  as seen in  FIGS. 9-12 . In some non-limiting embodiments, the magnets  310  may be held in place by additional ring magnets on the outside of the hat via the clamping force between the magnets. Embodiments having the magnets  310  held in place by ring magnets may be used in situations that require frequent removal and adjustment of the magnets  310 . Additionally, additional ring magnets may be used to attach magnets  310  that do not have a central opening for receiving a bolt  312 . 
       FIG. 13  shows a cross-section, taken through the center of the top and side magnets  310  of the hat  300  on the head of a user (line  13  shown in  FIG. 8 ), and the associated compressed, static magnetic fields provided by the hat  300 . In the non-limiting embodiment shown in  FIG. 13 , each magnet  310  is a mounting magnet which includes a ring magnet surrounded by a spacer and a steel cup. The steel cup extends over the south pole of the magnet to direct the magnetic field towards the north pole, thus resulting in a more powerful magnetic field extending out from the north pole of the magnet  310  and into the patient&#39;s head. As seen in  FIG. 13 , the magnetic fields of the three shown magnets  310  are all compressed in the patient&#39;s brain. The magnets  310  in the front and back of the head, which are not shown in this cross-sectional view, would also be providing magnetic fields that are interesting with the shown magnetic fields. As such, the brain tissue of the patient resides within an intersection of five magnetic fields from the hat  300 . In some embodiments, each magnet may be directing a south facing magnetic field into the patient&#39;s brain or, alternatively, some of the magnets may be directing south facing magnetic fields, while others are direct north facing magnetic fields, into the brain. 
     A user may also place a magnetic therapy mouth guard  14  in his/her mouth to provide an additional magnetic field. The mouth guard may include a centrally located magnet  110 . The magnet  110  may be pivotally attached to the mouth guard by a ball joint or other pivoting mechanisms known in the art. As seen in  FIG. 13 , a user will be able to direct the magnetic field of the mouth guard, due to the pivotal relationship, at the target tissue to provide an additional compressed magnetic field. 
       FIG. 13A  shows an example of a patient with a brain tumor (T). As seen by the circles (M) representing example static magnetic fields of the magnets  310 ,  110  (the example magnetic fields (M) are show in their before compression state to clarify the interaction between the fields), the tumor is being exposed to at least four compressed magnetic fields in addition to the magnetic fields of magnets  310  not located on the cross-section. As seen by the dashed lines, each magnet  310 ,  110  will provide a different strength magnetic field at the location of the tumor due to the differences in distance from the tumor. A larger distance from the magnet  310 ,  110  (longer dashed line) will result in a weaker magnetic field. In most cases, a stronger magnetic field provides greater results. Accordingly, in some cases, when the location of damaged or abnormal tissue is known, the magnets  310 ,  110  can be strategically placed so each compressed magnetic field is at its strongest. 
       FIGS. 14A and 14B  depict the magnetic therapy hat  300  containing seven static magnets  310 . The embodiment of  FIGS. 14 and 15  includes additional magnets  310  in the front and back of the hat, as compared to the embodiment shown in  FIGS. 8-13 , which will be resting on the top of the head when the hat  300  is being worn by a user. The additional magnets  310  will provide more compressed magnetic fields at the targeted healthy tissue surrounding the treatment tissue, thus resulting in a more condensed magnetic field at and around the treatment tissue. 
     The previously discussed magnetic therapy helmet  100 , magnetic therapy head harness  200 , and the magnetic therapy hat, as well as any other device describe herein or any combination of magnets within the scope of this description may be used to treat neurological conditions such as chronic traumatic encephalopathy (CTE). CTE caused the neurons in the brain to die. Without intervention, dead neurons will not be regenerated. Exposing the dead neurons to a condensed magnetic field may result in an increase of stem cells at the location of the dead tissue resulting in new neurons being created. 
     To treat Alzheimer&#39;s disease, or other neurodegenerative diseases, a magnetic therapy helmet  100  may be placed on the patient&#39;s head to produce a compressed magnetic field around the patient&#39;s brain. In addition to the increased presence of stem cell due to the compressed magnetic fields, an injection tube  199  may be used to provide additional stem cells to the patient&#39;s brain. 
       FIG. 15  shows an embodiment of a static magnetic therapy helmet  100  being used to treat Alzheimer&#39;s disease. Alzheimer&#39;s disease is a result of neuron degeneration in the brain. The presently discussed magnetic therapy can be used to regenerate neurons through the increased presence of stem cells in the area of the compressed magnet fields. Additional stem cells may be delivered to the user by a delivery lumen  199 . 
     Transcranial magnetic stimulation (TMS) may be used in conjunction with static magnetic therapy to further treat Alzheimer&#39;s disease. As seen in  FIG. 15 , a TMS device  198  may provide electromagnetic fields to the brain at the same time as the static magnetic fields of the magnets  110 . The electromagnetic fields may prevent binding of beta-amyloid proteins to capillary walls by drawing electrical charge to the capillary wall which in turn repels the charged beta-amyloid protein. The repetitive nature of the electromagnetic field produced by the TMS device  198  may also break apart beta-amyloid protein clumps on the capillary walls. Additionally, a pulsed electromagnetic field generator, such as a Bemer 3000™, may be used with the static magnetic field therapy, or the combination of the static and electromagnetic field therapy discussed above, to further treat Alzheimer&#39;s disease. Quantitative electroencephalography (qEEG) may be used to map the brain during treatment to precisely align the static magnets  110  and the electromagnetic field of the TMS device  198 . 
       FIGS. 16-18B  depict magnetic belts  400   a ,  400   b  which provide compressed, static magnetic fields within a portion of a body surrounded by the belt  400   a ,  400   b . For example, as shown in  FIG. 16  the belts  400   a ,  400   b  can be used on and animal, such as a dog, with a first belt  400   b  acting as a torso belt and a second belt  400   a  acting as a collar. Each belt  400   a ,  400   b  may support at least two magnets  410  along its length on a body facing surface of the belt  400   a ,  400   b . In some non-limiting embodiments, the magnets  410  may be equally spaced to provide consistent coverage to the wrapped body part as a whole. In other non-limiting embodiments, the magnets  410  may be positioned to provide more powerful compressed magnetic fields at a specific location. The locations and amounts of magnets, as well as the animal shown, in  FIG. 16  are provided as examples. The belts  400   a ,  400   b  may be used on any type of animal and may be wrapped around any part of the body that may require, or benefit from, magnetic treatment. In some embodiments, the belts  400   a ,  400   b  may include between 2 and 25 magnets. 
       FIGS. 18A and 18B  depict cross-sections of  FIG. 16  at each belt  400   a ,  400   b , as well as circles (M) indicating examples of the associated magnetic fields (the fields (M) are shown in a non-compressed state to clarify the interaction between the fields).  FIG. 18A  shows a cross-section of the torso belt  400   b  based on line  18 A of  FIG. 16 . In the non-limiting embodiment of  FIG. 18A , two magnets  410  are oriented with the north pole facing inwards and two magnets are oriented with the south pole facing inwards. As shown in  FIG. 18A , the torso of the dog will be exposed to the intersection of the strongest portions of the magnetic fields of each magnet  410 . The belt  400   a , shown in  FIG. 18B  which is based on line  18 B of  FIG. 16 , alternatively has each magnet  410  oriented so the south pole is facing inwards to produce compressed static magnetic fields through the neck of the dog. 
       FIGS. 19-23  depict a magnetic therapy muzzle  500  which provides compressed, static magnetic fields through the snout, mouth, and jaw of the muzzled animal. The muzzle  500  includes a rigid cage  520  with multiple attached magnets  510  which may be directed into the cage. Multiple magnets  510  may be located on each side of the jaw, as well as on the top and bottom of the jaw. In some non-limiting embodiments, each side of the cage  520  may be fitted with between 1 and 10 magnets and the top and bottom of the cage  520  may each be fitted with between 1 and 10 magnets. The location and size of the magnets  510  may be selected based on the treatment sought and/or size of the animal. In some embodiments, each magnet  510  may have a complimentary magnet  510  on the opposing side of the cage  520 , as shown in the embodiment of  FIGS. 19-23 . A collar  530  may be attached to the cage  520  to assist in securing the cage  520  to the face of the animal. The collar  530  may also include two or more magnets  510 , similar to the embodiments of  FIGS. 16-18B . The shape of the rigid cage  520  may be adjusted for different animals with different snout sizes. 
       FIGS. 24 and 25  depict a magnetic therapy jock  600  which may be used to provide compressed, static magnetic fields through the groin area of a patient. The jock  600  may include a male athletic cup  630 , as shown in  FIGS. 24-25 , or a female athletic pelvis protector. Left and right frontal magnets  610 A may be provided around a periphery of the cup  630 . A strip of rear magnets  610 B may extend down from a bottom of the cup  630  for being placed within the intergluteal cleft. Mounting magnets  610 C may be attached to the cup and directed inwards towards a user. In the non-limiting embodiment shown in  FIGS. 24 and 25 , cylindrical magnets  610 A,  610 B are contained within tubes  620  attached to the sides of the cup  630 . In other embodiments, the magnets  610 A,  610 B may be attached to the cup  630  by other means known in the art. A strap (not shown in the Figs.), such as an adjustable belt or jock strap, may connect the tubes  620  and cup  630  to assist in holding the magnets  610  in the desired positions. The magnetic jock  600  may include a magnetic belt similar to the belts shown in  FIGS. 16-18 . In some non-limiting embodiments, a rigid “V” or “U” shaped structure may hold the left and right frontal magnets  610 A without the use of a cup  630  or pelvic protector. 
     In use, the magnetic jock  600  may be warn similar to an athletic jock with the left and right frontal magnets  600 A on respective sides of the front of the groin region with the rear magnets  600 B residing within the intergluteal cleft. The magnetic field of each magnet  600 A,  600 B will resultantly compress within the groin region and may be used for treating the urinary tract, bladder, reproductive tissue, and rectum tissue. 
       FIGS. 26-28  depict an embodiment of a rectal magnetic therapy device  700  for providing a static magnetic field extending into the body from the rectum. The device  700  may include an outer body  720  defining a cavity  722  and a flange  724 . A magnet  710  may be housed within the cavity  722 . In some non-limiting embodiments, the magnet  710  may be cylindrical or egg shaped. A disposable sheath  730  may be used to cover the body  720  during use. During use, the body  720  of the device  700  may be inserted into the rectum and held in place by the flange  724 , thus positioning the magnet  710  within the rectum of the user. The rectal magnet  70  may be used with other magnetic therapy devices such as the magnetic jock  600  of  FIGS. 24-25  and/or the belts  400 A,  400 B of  FIGS. 16-18  to provide an additional magnetic field from within the body. The poles of the device  700  may be oriented based on other compressed magnetic fields. For example, if the magnets  410  from a belt  400 B worn around a patient&#39;s waste are all oriented with the north pole facing inwards, the north pole may be oriented towards the tip of the device  700 . 
       FIGS. 29-31  depict an embodiment of a vaginal magnetic therapy device  800  for providing a static magnetic field extending into the body from within the vaginal canal. The device  800  may include an outer body  820  defining a cavity  822  and a flange  824 . A magnet  810  may be housed within the cavity  822 . In some non-limiting embodiments, the magnet  810  may be cylindrical or egg shaped. A disposable sheath  830  may be used to cover the body  820  during use. During use, the body  820  of the device  800  may be inserted into the vagina and held in place by the flange  822 , thus positioning the magnet  810  within the vaginal canal of the user. The device  800  may be used with other magnetic therapy devices such as the magnetic jock  600  of  FIGS. 24-25 , the belts  400 A,  400 B of  FIGS. 16-18 , and/or the rectal magnet  700  of  FIGS. 26-28  to provide an additional magnetic field from within the body. The poles of the vaginal magnet  700  may be oriented based on other compressed magnetic fields. For example, if the magnets  410  from a belt  400 B worn around a patient&#39;s waste are all oriented with the north pole facing inwards, the north pole may be oriented towards the tip of the device  800 . 
       FIG. 32-34  depict an embodiment of a gastrointestinal “GI” magnetic therapy device  900  and a method of use. The GI device  900  may include an endoscope  920  or steerable rod having a static magnet  910  attached along its length. In some non-limiting embodiments, the magnet  910  may be a ring magnet wrapped around the endoscope  920 . In some embodiments, the magnet  910  may be located near a distal end of the endoscope  920 . The magnet  910  may be offset a distance from a distal end of the scope which allows the endoscope  920  to coil over for visualizing the magnet  910  in relation to the treatment tissue. 
     To perform a procedure, the GI device  900  may be inserted into the GI tract either orally or anally, depending on the location of the treatment tissue. Once inserted, the magnet  910  may be approximated to the treatment tissue. The location of the magnet  910  in relating to the treatment tissue may be determined using a camera on the endoscope, medical imaging, or a magnetic sensor such as a MEMS magnetic sensor. Once the magnet  910  is in place, external magnets  912 ,  914  may be positioned to provide one or more magnetic fields for interaction with the magnetic field of the internal magnet  910 . As seen in  FIG. 32 , a magnet  912  may be placed on a chest of the patient at a position proximate the internal magnet  910 , and as seen in  FIG. 33 , a magnet  914  may be placed on a back of the patient in a position proximate the internal magnet  910 . As a result, multiple magnetic fields will be compressed in the healthy tissue surrounding the treatment tissue, thus stimulating the immune system to act on the treatment tissue. 
       FIG. 35  shows an embodiment of a dual magnetic therapy support  1000  which may be used for treating severed nerves. The compressed magnet fields may cause an increase in stem cells in the damaged tissue which may repair the severed nerves. The support  1000 , as shown in  FIG. 35 , may be used to treat a severed spinal cord (S). As seen in  FIG. 35 , the support  1000  may be designed so the static magnets  1010  are connected to a member  1020  that directs their magnetic fields out towards the spine and slightly inwards to increase the interaction between the strongest parts of the magnetic fields. The support  1000  may be positioned so each magnet is on an opposing side of the spine at the location of the severed spinal cord (S). This location will provide a compressed static magnetic field on the severed ends of the spinal cord nerves and in the surrounding healthy tissue. As a result, the healthy tissue surrounding the injury may draw in stem cells that can be used to repair and reconnect the severed spinal cord. 
       FIG. 36  shows an embodiment of spinal column repair method having two or more static magnets  1030  located on the anterior and posterior sides of the spinal column. In some embodiments, one or more of the magnets  1030  may be implanted or inserted into in the patient to decrease the distance between the injured tissue and the magnet  1030 , thus increasing the strength of the magnetic field at the location of the damaged tissue. 
       FIGS. 37-40  show an embodiment of a full body magnetic therapy stand  1100  for exposing a full body to compressed, static magnetic fields. The stand  1100  may include a platform  1120  and multiple legs  1122  raising the platform  1120  from the ground. Multiple magnets  1110  may be dispersed throughout the platform. In some non-limiting embodiments, the magnets  1110  may be attached to the top, bottom, or embedded within the platform  1120 . As seen in  FIG. 37-40 , the platform  1120  is in the shape of a “U” to provide locations for magnets  1110  having fields directed laterally from a raised position. The magnets  1110  may be attached to the platform  1120  with their magnetic fields directed radially inwards to position an interaction of the multiple magnetic fields at the location of the patient within the “U” shaped platform  1120 . Strength of the magnetic field may be varied by changing the amount and/or strength of the magnets  1110 . In some embodiments, the table may have in the range of 12-100 magnets. The magnets  1110  may be evenly dispersed throughout the table  1100  or may be concentrated at specific areas, such as the torso, for targeted treatments. In some embodiments, the platform  1100  may be made of a soft material or may have a soft covering to aid in user comfort. 
       FIGS. 38-40  show a patient being treated by the full body magnetic therapy stand  1100 . By laying on the platform  1120 , the patient will be exposed to multiple compressed magnetic fields covering their whole body. The magnetic fields will be stronger closer to the platform, so the patient may lie in multiple positions, as seen in  FIG. 38-40 , to maximize the effect of the compressed magnetic fields to each part of the body. Additionally, changing position of the patient will assure each portion of the body is receiving a similar amount of magnetic therapy. During a magnetic therapy session, a user may lay on each of their back, right side, front, and left side for timed intervals. A non-limiting time interval for each magnetic therapy session may be in the range of 1 hour to 24 hours, and the time interval for each position may be in the range of 15 minutes to 6 hours. 
       FIGS. 41A-41C  show an embodiment of a fully body magnetic therapy system including a magnetic bed  1220  and table  1230 . The bed  1220  includes a platform  1222  for supporting a patient. A head portion of the platform may include multiple magnets  1212  for providing compressed magnetic fields in and around the head of the patient. Magnets  1212  positioned to the sides of the patient&#39;s head may be raised from the platform  1222  and have their magnetic field directed laterally towards the patient&#39;s head. A distance between the magnets  1212  and the patient&#39;s head may be adjusted by twisting screws  1214 . A magnet  1212  below the patient&#39;s head may have its magnetic field directed upwards. As seen in  FIG. 41A , a steel encasement may be used to direct the magnetic field of the magnets  1212 . Alternatively, in some non-limiting embodiments, the magnets  1212  may be mounting magnets with the strong poles oriented to direct the magnetic field as discussed above. A patient may change the angle of their head to provide different concentrations of magnetic field to different portions of the head and brain. 
     A middle portion of the platform  1222  may contain an array of magnets  1210  for providing magnetic fields to the body of the patient. Each magnet  1210  may be directed upwards towards a patient lying on the bed. In some non-limiting embodiments, the magnets  1210  may be pivotable so the magnetic fields can be directed as desired by a practitioner. For example, magnets directed at areas not requiring treatment may be directed downwards. A density and amount of the magnets  1210  may be determined based on the strength of the individual magnets  1210 , the desired amount of individual magnetic fields, and the desired spacing between magnetic fields. In some non-limiting embodiments, the entire platform  1222  may be covered by the array of magnets  1210 . In some non-limiting embodiments, the platform  1222  may support in the range of 20 to 100 magnets  1210  of the same or different sizes and strengths. In some non-limiting embodiments, densities of the magnets  1210  may be varied through the platform  1222  to treat conditions at specific parts of the body. 
       FIGS. 41B and 41C  show a magnetic table  1230  for use with the magnetic bed  1220 . The table  1230  may be designed to contain magnets  1210  having their magnetic fields direct downwards to interact with the magnetic fields directed upwards from the bed. As a result, the portions of a patient sandwiched between the bed  1220  and table  1230  will be exposed to multiple compressed magnetic fields originating from above and below the patient. The table  1230  may include an upper platform  1232  containing an array of magnets  1210  and at least one adjustable support  1236 . In some non-limiting embodiments, the supports  1236  may be height adjustable to allow for the height of the upper platform  1222  to be adjusted based on a thickness of the patient. Height adjustability allows a practitioner to maximize the strength of the magnetic fields in which the patient is exposed since the strength of the magnetic fields increases with proximity to the magnets  1210 . Any adjustment mechanism known in the art for moving a platform up and down may be used, for example a locking telescopic pole. The bottom of each support  1236  may contain wheels  1234  to allow the practitioner to move the array of magnets  1210  over different portions of the patient&#39;s body and/or align the magnets  1210  of the table  1230  with the magnets  1210  of the bed  1220 . Tracks  1240  may run along the length of each side of the bed  1220 . The table  1230  may be connected to the tracks  1240  to prevent any instability that may be caused by the repulsive or attractive magnetic forces between the magnets  1210  on the table  1230  and bed  1220 . The portion of the patient&#39;s body directly in between the bed  1220  and table  1230  will be exposed to the maximum strength compressed magnetic fields. The magnets  1210  of the table may be arrange in an array matching the magnets of the bed  1220 , but with the magnetic fields being directed downwards. In some embodiments, the array of magnets  1210  on the bed  1220  may share width and/or length dimension with the array of magnets  1210  on the table  1230 . In some non-limiting embodiments, the table  1230  may support an array of magnets  1210  having between 20 and 100 magnets. The amount of magnets  1210  may be varied based on the size and strength of magnets used. 
       FIGS. 41D-F  shows an embodiment of magnet module including an array of magnets. In this embodiment, the magnets are in a square shape and bolted on a ½ inch substrate/board. In this embodiment, each magnet is 6 inch wide and 2½ inch thick, and the module comprises 20 magnets. Each magnet is bolted directly onto the substrate or bolted into each individual slot of an array brackets/encasements on the substrate. The sizes of the magnets and substrate of the instant invention is not limited to the sizes as shown. The polarities of each magnet are both flat surfaces of the magnets facing towards and away from the substrate. The magnet module can be embedded in the bed, sleeping capsule, or any therapeutic device according to the instant invention. 
       FIGS. 42A and 42B  show a non-limiting example of a magnet  1210  that may be used on the magnetic bed  1220 , the magnetic table  1230 , or any magnetic device described herein. In some embodiments, the magnetic material  1210   a  may be a grade N42-N55 neodymium ring magnet. The outer shape of the magnetic material  1210   a  may be square to allow for a higher density of magnetic material  1210   a  in the arrays. Each magnetic material  1220   a  component in the arrays may be encased in steel  1210   d  with a spacer  1210   c  between the magnet and the steel to produce a mounting magnet. A metallic shield  1210   e  may be provided on the outside of the metal encasement to provide further deflection of the magnetic field towards the strong side of the magnet  1210 . In some non-limiting embodiments, the magnets  1210  may have a width and length in the range of 2 to 10 inches, a thickness in the range of 0.25 to 2 inches, and/or a central opening  1210   b  in the range of 0.25 to 2 inches. An upper portion of the central opening  1210   b  may be fileted for accepting a countersunk bolt. 
       FIGS. 43A-43C  show an embodiment of a fully body magnetic therapy system including a magnetic bed  1220  and table  1230  which have extendable magnets  1210 . Each magnet  1210  may be individually attached to an actuator  1260  that may move the magnet  1210  towards the patient to provide treatment, or further away from the patient for areas that do not need treatment. As shown in  FIG. 43B , when each magnet  1210  is retracted, a patient facing surface of the magnet  1210  may rest 3 to 12 inches from the patient. Using the actuator  1260 , selected magnets  1210 ′ may be moved closer to the patient for providing a stronger magnetic field within the patient. Any magnetic therapy device within the scope of this disclosure may be used with the magnetic therapy bed to expose a user to additional static magnetic fields at specific locations. 
     In some embodiments, a non-magnetic frame  1228  may provide channels to guide each magnet  1210  through its range of motion. For example, the frame  1228  may be six inches thick for a system that can actuate the magnets  1210  six inches. Each of the actuators  1260  may be secured to the side of the frame  1228  opposite the patient. A non-magnetic sheet  1229  may be positioned on the upper side of the platform  1220  to provide a flat surface for supporting the patient. 
       FIG. 43C  shows a cross-section of a single magnet  1210  and its attached actuator  1260 . A body of the actuator  1263  may be threadedly engaged with a threaded rod  1262  that is attached to the magnet&#39;s steel encasement  1210   d . By spinning the threaded rod  1262 , the actuator  1260  is able to move the magnet  1210  up and down in the channel formed by the frame  1228 . In some embodiments, the magnets  1210  may be actuated by other linear actuators known in the art. 
     In use, a practitioner may determine a location on a patient that requires magnetic treatment and which corresponding magnets  1210  magnets to approximate to the patient. Additionally, the practitioner may also determine an ideal distance between the patient and each magnet  1210 , which will dictate the strength of the magnetic fields to which the patient is exposed. In some embodiment, a computer program may be used to determine which magnets  1210  to actuate and how far to actuate the magnets  1210  based on an algorithm inputting imaging data. For example, imaging data providing the size and location of the target tissue may be inputted into the program, and the program may select magnets  1210  and the magnitude of their movement based on the data. In some embodiments, the algorithm may use feedback from a polarized neutron imaging device. The polarized neutron imaging device is capable of detecting magnetic fields within an object. Accordingly, the algorithm may be used the known position of the target tissue, determined by medical imagining such as CT, MRI, EEG, and QEEG, and may adjust the magnets until the magnetic fields are optimally positioned based on the feedback provided by the polarized neutron imaging device. In some scenarios, optimal position may be a maximum magnitude of compressed magnetic fields in the target tissue or a maximum magnitude of compressed magnetic fields in the healthy tissue immediately surrounding the target tissue. 
     As seen in  FIGS. 43A and 43B  each actuator  1260  may be connected to an array of power and data lines  1261 , with an individual line for each actuator  1260 . Accordingly, the actuation of each magnet  1210  may be individually controlled by a computer in communication with the data lines  1261 . 
       FIG. 43D  shows and embodiment of a frame  1228 , including actuators  1260  and magnets  1210 , that may be used in the magnetic platform  1220 . When creating the frame  1228 , channels  1228   c , for guiding the magnets  1210 , may be cut out using a water jet or similar cutting mechanism to form the base  1228   a . The cutouts  1228   b  may then be rotated 45 degrees and welded to the side of the base  1228   a  opposite the patient supporting side for supporting the actuators  1260 . Similar construction may be used to create the magnetic array of the table  1230 . 
       FIGS. 44A and 44B  show the magnetic bed  1220  and table  1230  in use. In  FIG. 44A , the magnetic bed  1220  and table  1230  combination are primarily providing magnetic therapy to the patient&#39;s torso since that is the portion of the body between the two arrays of magnets  1210 . This configuration may be used when the treatment tissue is in the patient&#39;s torso or to treat cancer cells flowing through the patient&#39;s circulatory or lymphatic systems. In some embodiments, a pulsed electromagnetic field generator  1250 , such as a Bemer 3000™, may be attached to the patient during the magnetic therapy. A pulse frequency of the pulsed electromagnetic field generator  1250  may be in the range of 0.05 Hz to 963 Hz. In some embodiments, the frequency may be 10 Hz or 33 Hz as these frequencies have been found to produce a greater therapeutic effect than many other frequencies. The static magnetic fields caused by the arrays of magnets  1210  may cause the red blood cells of the patient to form rouleaues which are stacks of red blood cells. The stacked red blood cells do not circulate as well as individual cells and therefore may affect blood flow. Applying a pulsed electric field to the patient&#39;s circulatory system may prevent or at least mitigate the rouleau formation, thus increasing circulation. The electrode  1252  of the pulsed electromagnetic field generator may be placed at any location on the skin of the patients. In some embodiments, the electrode may be a mat that the patient lays upon. A pulsed electric field generator, such as the Bemer 3000 can be used with any embodiment of a magnetic therapy device discussed herein. A pulsed electric field generator may be used with any Alzheimer&#39;s treatment discussed herein. 
       FIG. 44B  shows the magnetic bed  1220  and table  1230  with actuated magnets  1210 . A computing device  1265  may be used to control the actuators  1260 , as discussed above. When providing treatment, the patient may be placed on the platform  1220  and the table  1230  may be lowered to a position adjacent the patient. The practitioner may them lower selected magnets  1210 , using the computing device  1265 , to provide targeted magnetic treatment to the patient. The computing device  1265  may be any computing device having a user interface such as a laptop, tablet, or cell phone. In some embodiments, the computing device  1265  may communicate with the actuators  1260  via a wireless connection, such as Wifi, Bluetooth, or cellular communications. 
     In addition to the magnetic therapy, stem cells may be injected into the patient&#39;s to enhance the full tissue regrowth. The compressed magnetic fields provide increased stem cell activity indicated by the full tissue regrowth discussed below in Examples 2 and 3. The process of regrowth may be enhanced by using an injection port  1270  to provide additional stem cells. 
       FIGS. 44C and 44D  show the magnetic bed  1220  and table  1230  with a body scanner. The body scanner is a mechanical arm attached to the table  12340 , and a scanning device is attached at the tip of the mechanical arm. The body scanner can be an optional device attached to the table  1230  with magnets in the embodiment shown in  FIGS. 44A and 44B , the body scanner can also attach to a table  1230  which does not have any magnets. As shown in the  FIGS. 44C and 44D , the mechanical arm is attached to a screw track on the table, which the mechanical arm can move side to side while in operation. The mechanical arm in this embodiment has 2 arm sections which can extend the mechanical arm or fold the mechanical arm. In different implementations, the number of arm sections can be more than 2 for increasing the distance on how far the mechanical arm and the scanning device can reach. The table  1230  can also move along the screw tract  1214  for further facilitating positioning the scanning device. The scanning device scans the user&#39;s physical size and appearance in order to determining any changes on the user&#39;s body. The scanning operation can be scheduled before or/and after each usage, and the control system can record and track the measured data for determining the changes on the user&#39;s body. 
       FIGS. 45 and 46  show an embodiment of a magnetic therapy collar  1300 . The magnetic therapy collar  1300  may include five static magnets  1310 , two on each of the left and right sides of the collar and one on the bottom. Each of the magnets  1310  may be a mounting magnet with the strong side directed inwards. The collar  1300  may include an adjustable strap  1320  and a mounting member  1322  which extends around a circumference of the adjustable strap  1320  to hold the magnets  1310  at a generally rigid configuration. For example, in some non-limiting embodiments, the mounting member  1322  may be a ¾ inch by ⅛ inch piece of flat aluminum bar. Holes may be formed through the strap  1320  and mounting member  1322  for accepting bolts that secure the magnets  1310 . The mounting member  1322 , strap  1320 , and magnets  1310  may be secured together by the bolts of the magnets  1210 . In some embodiments, securement may be provided by attachment mechanisms known in the art such as adhesives or rivets. A circumference of the strap  1320  may be adjustable and may be also disconnectable using mechanisms known in the art such as a belt buckle or hook and loop fasteners. 
     As seen in  FIG. 46 , the magnetic therapy collar  1300  may be sized and shaped to loosely hang on the dog&#39;s neck. The loose attachment may allow the magnets  1310  to shift positions on the neck when the dog moves or changes position resulting in a larger exposure of the condensed magnetic field. The magnets  1310  may be positioned based on the location of the treatment tissue. For example, a tumor on the bottom of the dog&#39;s neck may be treated by three magnets  1310  positioned at the bottom of the collar  1300 . In some non-limiting embodiments, the number of magnets  1310  on the collar  1300  may be in the range of 2 to 20. 
       FIGS. 47-49  show an embodiment of a magnetic muzzle  1400 . The magnetic muzzle  1400  may include an adjustable collar  1400  pivotally connected to two jaw rods  1420  which are designed extend down opposing side of a snouted animal&#39;s jaw. A muzzle cage  1422  may extend between the two jaw bars  1402 . Multiple static jaw magnets  1410   a  may be connected along the length of each jaw member  1420 . Two ear magnets  1410   b  may be positioned at opposing ends of a generally “U” shaped connecting member  1430  and may be mounted to the jaw members  1420 . The ear magnets  1410   b  and connecting member  1430  may be directly mounted to the jaw members  1420  using any fastener known in the art such as an adhesive or bolts. The ear magnets  1410   b  may be poisoned above the jaw magnets and towards the rear of the muzzle  1400 . As seen in  FIG. 49 , the magnetic dog muzzle  1400  may encompass the dog&#39;s entire jaw up to the ears in condensed magnetic fields. In some embodiments, the jaw magnets  1410   a  may be a different size than the ear magnets  1410   b . For example, in a non-limiting embodiment, the jaw magnets  1410   a  may be 2 inch mounting magnets and the ear magnets  1410   b  may be 4 inch mounting magnets. 
       FIGS. 50A-B  show embodiments of magnetic therapy mouth guards  1500   a  and  1500   b . The magnetic mouth guards  1500   a ,  1500   b  may define an interior wall  1524   a ,  1524   b , an exterior wall  1522   a ,  1522   b , and a base  1520   a ,  1520   b  connecting the bottom end of the walls  1522   a,b ,  1524   a,b . Multiple static magnets  1510  may be connected along each of the front  1522   a,b  and back  1524   a,b  walls. When the mouth guard is worn by a user, the user&#39;s teeth, jaw, and gums will be exposed to compressed magnetic fields produced by magnets  1510  on the outer walls  1522   a,b  interacting with magnets on the inner walls  1524   a,b .  FIG. 50A  shows a first embodiment of a mouth guard  1500   a  that may be used for exposing the upper teeth, jaw, and gums to compressed magnetic fields.  FIG. 50B  shows a second embodiment of a mouth guard  1500   b  that may be used for exposing the lower teeth, jaw, and gums to compressed magnetic fields. In some embodiments, the magnets  1510  may be connected to the inner or outer side of the inner  1524   a,b  and outer  1522   a,b  walls. In other embodiments, the magnets  1510  may be embedded in the inner  1524   a,b  and outer  1522   a,b  walls. In some non-limiting embodiments, a pair of magnets  1510 , one on the inner wall  1524   a,b  and one on the outer wall  1522   a,b , may be provided and positioned for each individual tooth in a patients mouth. In other non-limiting embodiments, the mouth guards  1500   a,b  may only include magnets  1510  for select teeth and leave the remaining portions of the walls  1524   a,b ,  1522   a,b  free of magnets  1510 . The mouth guards  1500   a,b  may be used to treat conditions such as oral cancer, tooth decay, and gum disease. 
       FIG. 51  shows an embodiment of electronic, magnetic therapy mouth treatment system  1600  including upper  1602   a  and lower  1602   b  mouth guards. The mouth guards  1602   a ,  1602   b  may be similar to the mouth guards  1500   a ,  1500   b  of  FIGS. 50A and 50B , with each mouth guard  1602   a ,  1602   b  having inner and outer walls connected at their bottom ends by a base. Each wall may be embedded with static magnets  1610  that are exposed to the tooth side of each wall. Each magnet  1610  may be electronically connected to a power source  1630  to act as an electrode. Each pair of magnets  1610  may correspond to a single tooth (i.e. a magnet on the inner wall and a magnet on the outer wall on opposing side of a tooth) and may be provided on a single circuit with one magnet  1610  acting as a positive electrode and the other magnet  1610  acting as a negative electrode. The individual circuits for each pair of magnets associated with a tooth may be provided by multiple sets of wires  1632  connected to a selectable power source  1630  capable of sending current trough individual circuits, and thus exposing individual teeth to electric current. The electric current may be used to remove select teeth without causing bleeding of the gums. 
       FIGS. 52-54  show an embodiment of a magnetic knee brace  1700 . The knee brace  1700  includes a support wrap  1720 , two static magnets  1710 , and articulating magnet supports  1730 . Each magnet  1710  is attached to an articulating support  1730  at the articulating joint. The support wrap  1720  includes two sets of pockets  1722   a,b  for supporting the magnets  1710  and articulating magnet supports  1730  on the medial and lateral sides of the knee. Each set of pockets  1722   a - b  has an upper pocket  1722   a  to be positioned above the knee and a lower pocket  1722   b  to be positioned below the knee. Each set of pockets  1722   a,b  may accept the arms  1732 ,  1734  of the articulating support. When attached to a user&#39;s knee, as seen in  FIG. 54 , the magnets  1710  are held in place at the medial and lateral side of the user&#39;s knee. The articulating supports  1730  allow the knee joint to be flexed while maintaining the magnet  1710  placement. In some non-limiting embodiments, the magnets  1710  may have a strength that results in the magnet field on the opposing side of the knee to have the strength of 0.01 to 10 Gauss when only one of the two magnets is present. For example, the magnets may be mounting ring magnets having a diameter in the range of 2 to 5 inches, a thickness in the range of 0.5 to 1 inches, and a grade in the range of N45-N52. In addition to the magnetic therapy, stem cells may also be injected into the target tissue or adjacent tissue to provide additional stem cell at the target tissue. The stem cells may be injected through an injection port  1790  having an outlet that dispenses the stem cells in or near the target tissue. Stem cells may be used in addition to any magnetic therapy treatment or device within the scope of this disclosure to provide enhanced tissue regrowth. 
       FIGS. 55 and 56  show a magnetic therapy animal crate  1800 . The crate  1800  may define six sides, including four side walls  1820 , a base  1824 , and lid  1822 , that form an enclosure for the animal. Each of the side walls  1820 , the base  1824 , and the lid  1822  may include an array of static magnets  1810 . For example, in some non-limiting embodiments, each of the four side walls  1820  and the base  1824  may include magnetic arrays while the lid  1822  does not. The arrays of magnets  1810  may be designed to take up the entirety of the side or just a portion. In some embodiments, all of the magnets  1810  may be directed into the enclosure. Openings  1826  may be defined in the side walls to provide airflow through the crate. During use, a pulsed electric field generator may be used on the animal residing within the magnetic therapy animal crate to prevent, or at least mitigate, rouleau formation in the blood. 
       FIGS. 57-60  show an embodiment of a magnetic vest  1900  for treating tissue within the abdomen of a user. The vest  1900  may have a front portion  1910  and a back portion  1920 . Each portion  1910 ,  1920  may have two shoulder flaps  1912 ,  1922  and two flank flaps  1914 ,  1924 . The front and back portions  1910 ,  1920  may be connected by adjustable straps  1950  spanning from each shoulder  1912  or flank flap  1914  on the front portion  1910  to the corresponding shoulder  1922  or flank flaps  1924  on the back portion  1920 . 
     The front  1910  and back  1920  portions may each define a magnet pocket  1960 . The magnet pockets  1960  may be located at any position on the front  1910  and back  1920  portions, and may be adjusted based on the location of the tissue requiring magnetic treatment. In the embodiments shown in  FIGS. 57-60 , which may be for treating tissue in the kidneys, liver, intestines, stomach, and/or pancreas, the magnet pockets  1960  extend between the flank flaps  1914 ,  1924 . Two static magnets  1940  are provided in each pocket  1960  and may have their strong magnetic field facing towards and inside of the vest  1900  to increase tissue penetration. In alternate embodiments, the vest  1900  may include two or more magnets  1940 , and the magnets  1940  may have various shapes and sizes to accommodate the needs of the patient and/or practitioner. In some non-limiting embodiments, the magnets  1940  may be secured to the vest  1900  using straps, brackets, or other means known in the art for attaching rigid elements to a semi-rigid device. 
     A rigid member  1930  may be secured to an outer side of each magnet  1940  to prevent the magnets  1940  from becoming magnetically attached when the vest  1900  is not being worn by the user, or when the vest  1900  in the process of being donned and doffed by the user. In some embodiments, the rigid member  1930  may be generally “U” shaped and may extend across the flank flaps  1914 ,  1924  of the user. Each magnet  1940  may be connected to the rigid member  1930  by a bolt  1932  which extends through an opening in the magnet  1940 , as shown by  FIG. 60 . 
       FIGS. 61-64  shown a magnetic sleeping pod  2000  for stimulating the body&#39;s immune system to treat abnormal or damaged tissue, as well as protect the body from electromagnetic radiation. The pod  2000  may define an enclosure with one open side. In the embodiment shown in  FIGS. 62-64 , the enclosure is made of 5 planar walls connected at right angles. In other embodiments, the walls of the pod  2000  may be arcuate or have rounded edges. The walls of the pod may comprise an array of static magnets  2010  dispersed throughout the walls. In some embodiments, as shown in  FIGS. 62-64 , the magnets  2010  may be evenly dispersed throughout the walls and may cover an entire surface area of the walls. Accordingly, a user positioned within the pod  2000  will be exposed to multiple compressed magnetic fields which stimulate the immune system and block hazardous electromagnetic radiation from entering the user. 
     When inside the sleeping pod  2000 , a user may be connected to a pulsed electromagnetic field generator  2030 , such as a Bemer 3000™. In some cases, the magnetic field provided by the sleeping pod  2000  may cause the user&#39;s red blood cells to form rouleaues which can decrease circulation. When connected to the user, the electromagnetic pulses from the pulsed electromagnetic field generator  2030  may prevent the user&#39;s red blood cells from forming rouleaues, thus increasing blood flow. The pulsed electromagnetic field generator  2030  may be electrically connected to the user by one or more patches connected to the user&#39;s skin. Alternately, or in addition to the patches, the user may lay in a sheath or sleeping bag  2020  wherein the internal surface is an electrode of the pulsed electromagnetic field generator, thus providing electrical contact over a large portion of the body. In some embodiments, the user may lay on a pad having an electrode of the pulsed electromagnetic field generator covering its upper surface to provide electrical contact over a large part of the body. 
     A research paper “Cardiac Effects of Repeated Weightlessness During Extreme Duration Swimming Compared With Spaceflight” was published by American Heart Association on April 2021 and authored by a group of scientists led by James P. MacNamara. This paper presents an interesting phenomena which how human body reacts with removal of gravitational loading of the musculoskeletal system and the absence of weight-bearing activities. The paper points out that without countermeasures, extended spaceflight will cause cardiac atrophy and orthostatic intolerance. The paper provides an example of an astronaut Scott Kelly who spent 340 days in space, and the astronaut Kelly did exercises in space including cycling, treadmill, and resistive exercise. This paper also provides an example of swimmer Benoit Lecomte who swam 2821 kilometers over 159 days. The left ventricular mass and ejection fraction were measured and compared during the respective campaigns. It is found that the left ventricular mass declined at similar rate for both individuals, and both individuals lost the left ventricular mass over the duration of their campaigns despite substantial amounts of exercise. This paper suggests that extended loss of gravitational hydrostatic gradients through weightlessness or prone positioning in water immersion without proper countermeasures resulted in loss of cardiac mass. Thus, the instant invention provides a mechanism to simulate the earth gravitation effect on human body during spaceflight to minimize the any cardiac atrophy. 
     Another research paper “The NASA Twins Study: A multidimensional analysis of a year-long human spaceflight” was published by the American Association for the Advancement Science and authored by a group scientists led by Francine E. Garrett-Bakelman. This paper reviewed the impact from a long spaceflight to human by comparing Scott Kelly with his twin brother, which Scott Kelly was in spaceflight for 340 days while his twin brother stayed on ground. The paper reviewed and discussed the change on the telomeres length, the DNA damage, and immune response. The paper concludes that some biological functions were not significantly affected by spaceflight, including the immune response (T cell receptor repertoire) to the first test of a vaccination in flight. However, significant changes in multiple data types were observed in association with the spaceflight period; the majority of these eventually returned to a preflight state within the time period of the study. These included changes in telomere length, gene regulation measured in both epigenetic and transcriptional data, gut microbiome composition, body weight, carotid artery dimensions, subfoveal choroidal thickness and peripapillary total retinal thickness, and serum metabolites. 
     The instant invention provides a possible solution to minimize or reverse the negative impact from the spaceflight to the human body by promoting the regeneration and growth of human tissue as the DNA originally intended. In one experience, a treatment according to the instant invention was performed on one of inventor&#39;s feet, and the invention was above the age of 65 at the time of experience. The comparison between the treated foot and the untreated foot shows significant growth and regeneration on the treated foot. A laser scan on both feet also confirms the growth and regeneration of the treated foot. As a conclusion, the treated foot can no longer fit into the shoe, and the size of the treated foot has grown back to the size of the shoes that the inventor wore at the age of early 20s. 
       FIGS. 63-64  show a sleeping pod unit  2100  which may be used attached to a spacecraft  2150 . The sleeping pod unit  2100  may include a docking portion  2110  which may dock with a port on the spacecraft  2150 . The unit  2100  defines a circular cross-section having multiple sleeping pods  2000  dispersed around its circumference. Each pod  2000  opens into a central chamber  2130  which may be used for entering and exiting the pods  2000 . The sleeping pod unit  2100  may be entered and exited through a door  2120  in the docking portion  2110 . The standalone sleeping pod unit  2100  may maintain the static magnets  2010  at an adequate distance away from the spacecraft  2150  to prevent the magnetic fields from disrupting electrical instrumentation on the spacecraft. 
       FIGS. 65A and 65B  show an embodiment of a magnetic therapy bra  2200  for treating tissue in the breast and/or chest area of a patient. The bra  2200  includes two rigid cups  2210  having a series of holes  2212  spaced apart around their perimeter for attaching static magnets  2230 . The magnets  2230  may be mounted on the inside surface of the cups  2210  with their fields directed inwards. The holes  2212  allow a position of the magnets  2230  to be adjusted based on location of the treatment tissue with respect to the cups  2210 . The magnets  2230  may be attached to the holes by a screw and bolt connection  2232 , as shown in  FIGS. 65A and 65B , or other removable connections known in the art. Accordingly, a strongest portion of the compressed magnetic fields may be adjusted to lie in the treatment tissue and adjacent healthy tissue. An adjustable neck strap  2220  may be used to hold the cups in place over a patient&#39;s chest/breasts. 
       FIGS. 66A-66D  show the magnetic therapy bra  2200  being worn by a patient. Each cup  2210  is placed over a respective breast, thus providing compressed magnetic fields throughout the breast tissue. The strap  2220  may be adjusted to hold each cup  2210  over a respect breast when the strap  2220  is worn around a patient&#39;s neck. A traditional bra  2240  may be worn over the magnetic therapy bra  2200  for securing the cups  2210  in place.  FIGS. 66C and 66D  show a cup  2210  partially removed from the breast to show one of many possible magnet  2230  configurations that may be used on the cups  2210 . As previously discussed, a location of the magnets  2230  on the cups  2210  may be adjusted to target specific areas of the breast tissue. 
     A method of using any device within the scope of this disclosure may include adjusting the position of the magnet based on feedback from neutron tomography. Neural tomography disperses neutrons through an object and detects changes to the magnetic moments of the neutrons to map magnetic fields within an object. Accordingly, the magnetic device can be optimally positioned on a patient by mapping the magnetic fields within the patient&#39;s body using the neutron tomography and adjusting the fields to compress in and around the target tissue. 
     A method of adjusting a magnetic device on a patient may include: attaching the magnetic device to the patient; mapping the magnetic fields produced in the patient by the magnetic device using neuron tomography; and adjusting the location of the magnets to maximize the amount of compressed magnetic fields in and/or around the target tissue. In some embodiments, multiple iterations of mapping and adjusting may be performed. 
     A method of using any device within the scope of this disclosure may include attaching the device to a patient so the magnetic fields compress in targeted tissue. The compressed magnetic fields may increase the presence of stem cells in and around the tissue. The stem cells may then differentiate to replace the damages tissue. In some cases, such as in damaged cardiac tissue, stem cells do not differentiate and replace the damaged tissue. However, the presence of stem cells, dead or alive, results in repair of the cardiac tissue. This is due to the stem cell emitting factors that produce an immune response which repairs the tissue. Accordingly, the presently disclosed magnetic device may be used to increase the presence of stem cells in a location of the body for producing an immune response to repair damaged tissue. 
     A method for stimulating the immune system to treat damaged or abnormal tissue using compressed static magnetic fields may include positioning first and second magnets so each magnet provide a magnetic field of at least 0.01 gauss over the target tissue when the other magnet is not present. As a result, at least two magnetic fields having a strength of at least 0.01 Gauss will be compressing the opposing magnet&#39;s field. If the two magnetic fields are from the same pole, such as both fields being north pole magnetic fields, the compressed fields will have a subtractive effect on each other with respect to magnetic flux density. Accordingly, a midpoint of the interaction between the magnetic fields will have a magnetic flux density of 0 Gauss. The present disclosure and experiments do not require a quantity of magnetic flux, but rather an compression of static magnetic fields. 
     A magnetic therapy exposure schedule may be varied based on the user, the condition being treated, and the device providing the treatment. For example, devices that provide magnets in close proximity to the skin may be used on a three days on, two days off schedule. This schedule may provide the skin time to regenerate between treatments which in some cases cause irritation to the skin. In some cases the schedule may include 1 h to 1 week on, with 45 minutes to 5 days off. Days off may be provided by moving the magnets to different location so magnets therapy may still be applied to the user. 
     A method of performing clinical trial of the aforementioned magnetic therapy may include using magnets of different strengths. In addition, placebos magnets may also be used to provide a placebo group. 
     A polarized neutron imaging device  995  may be used with any magnetic therapy device within the scope of this disclosure to enhance the magnetic therapy by guiding adjustment of the magnets based on how the magnetic fields pass through the patient&#39;s tissue.  FIG. 67  shows an example of magnetic fields within a patient being detected by a polarized neutron imaging device  995 . Magnets  1210  may be placed on a patient based on the location of target tissue. The polarized neutron imaging device  995  may then be used to determine how the magnetic fields extend through the patient&#39;s body. The position, orientation, and/or strength of the magnets  1210  may be adjusted to provide a desired strength magnetic field at and/or around the target tissue. For example, the position and orientation of the magnets  1210  may be adjusted until the polarized neutron imaging device  995  indicates the target tissue is exposed to the highest magnitude of compression between the magnetic fields. 
       FIG. 68  shows a static magnetic qEEG system. The system includes typical passive of active electrodes (typical electrodes)  2301  used in qEEG systems known in the art, as well as magnetic electrodes  2310 . The system may be used to ascertain how much electricity is being drawn to the magnets on the user&#39;s head. For example, the readings of the typical electrodes  2301  may be compared to the magnetic electrodes  2310 . Furthermore, the system may be used to map the electricity of the user&#39;s brain in the presence of magnets  2310 . This information may be used for positioning the magnets of a static magnetic therapy device to provide a maximum amount of body produced electricity in desired areas. 
     During space travel or under a prolong period of non-gravitated environment, both the physical size and number of the living tissue cells will start shrinking, which triggers a series of impacts on the body, such as the immune system. The current invention provides a static magnetic field mimicking the earth environment, which the measurement for the earth environment is 0.5 gauss. Although exercise may mitigate the shrinking condition, problem arises if the person is unable to exercise due to sickness or injury, or if the exercising equipment is broken; in addition, the exercise can never completely recover the shrinking condition. The magnetic system according to the instant invention provides an alternative approach to resolve the negative impact of the shrinking condition by providing a static magnetic field mimicking the earth environment for stimulating the immune system to replace the living tissue cells according to the DNA genetic specification. 
       FIG. 77  shows a space rocket, and  FIGS. 78A-C  shows sleeping arrangement according to the present invention.  FIG. 78A  shows top view of the arrangement, where each sleeping space is evenly arranged along the inside perimeter of the rocket. The outer shield of the rocket is the whipple impact shield for protecting the rock and the crew members from any external impact caused by orbital debris. Each resting space/bunk is surrounded and separated by water. While resting in the designed space, each crew member/user has his/her head positioned pointing towards the center of the rocket. Each bunk is constructed with two layers of static magnets, where the crew member is sandwiched between two layers while resting in the bunk. 
     The  FIG. 78C  shows top magnet layer of each bunk with the crew members rest underneath. The  FIG. 78C  further shows that each bunk&#39;s magnet layer is constructed with multiple static magnets. Each static magnet can be a square shape magnet or positioned in a square pouch. In addition to generating and repairing crew members&#39; tissues, both the water and the static magnets will also protect the resting crew member from any harmful radiation from the space. 
     The  FIG. 78I  shows the magnetic socks which crew member wears within the space station or rocket. The magnets embedded in the socks provide the additional assistance for the crew member to walk or move around within the rocket, especially around the sleeping bunks. As shown in the  FIGS. 78F and 78H , with the socks, the crew members can walk above or below the bunks for reaching his/her own designated bunk. The  FIG. 78H  shows an embodiment of double bunk with one bunk stacked on another one. In this embodiment, three magnet layers are employed to construct this stacked bunk arrangement, where each bunk level is sandwiched between two static magnetic layers, and the two bunk levels share the center magnetic layer. 
     The  FIGS. 79A-F  show sleeping cells and a sleeping capsule with multiple sleeping cells. The  FIG. 79A  shows a single sleeping cell with the door closed, while the  FIG. 79B  shows the internal design of the sleeping cell. As shown in the  FIG. 79B , the cell mainly accommodates a bed with a raising tray. Both the bed and tray are embedded with static magnets. Additional customization can be added for personal preference, such as wall decoration and supporting bracket for monitor display.  FIGS. 79C and 79D  show a space sleeping capsule with the sleeping cells constructed within. As shown in  79 C, the capsule has a tapered connector for connecting to the space station; the sleeping cells are arranged against the inside perimeter of the capsule with each cell opened towards the center of the capsule. The  FIG. 79E  provides a cross view of the capsule, the  FIG. 79F  provides a bottom perspective view of the capsule, where the capsule is constructed with the protective outer shield similar to the rocket, and the sleeping cells are arranged against the internal wall of the capsule. Further, as shown in  FIG. 80 , the tapered end of the capsule is meant to be connected to the designated end of the space station. 
     The  FIGS. 79H-79K  show the bed in the sleeping cell. As shown in the  FIG. 79H , the crew member rests on a platform constructed with multiple static magnets. In this embodiment, each magnet is in a squire shape, but the invention is not limited to the square shape. A rising tray with embedded magnet also is a part of the bedding system for providing corresponding magnetic field to the bed. As shown in  FIG. 79G , the rising tray has at least one rising bar attached to the bed platform. The rising bar facilitates the elevating position of the rising tray in respect to the bed platform. The rising bar attaches to a track on the side of the bed platform; thus, the rising bar slides along the track to reposition the rising tray corresponding to different sections of the bed platform. Thus, while crew member rests on the bed platform, the magnets on the rising tray can be moved to any position where treatments are needed. The  FIG. 79K  shows one embodiment of the track sliding mechanism design, where the rising bar has an extended footing secured positioned within the track, and the rising bar further comprises a wheel positioned above the track. In this embodiment, the raising bar&#39;s footing is secured in the track for preventing derailing, and the rising bar&#39;s wheel facilitates the sliding movement. 
     The  FIGS. 79L-79R  show the additional element of cushion for the bed according to the present invention. The  FIGS. 79M-79N  show one embodiment with an inflatable cushion. The  FIGS. 79O-79R  show the crew member rest in a sleeping bag and laying on the inflatable cushion. The inflatable cushion assists in minimizing the discomfort from the hard surface of the bed platform. Further,  FIGS. 79O-79R  show a second inflatable cushion under the bed platform. As shown in  FIG. 79R , the tilting position of the bed platform can also be adjusted via the second inflatable cushion. 
     As discussed above and illustrated in the figures, the present invention provides a sleeping apparatus with magnets. Especially, in one of the embodiment, the present invention provides a sleeping bunk deck within a space rocket for accommodating crew members. Yet, in another embodiment, the present invention provides a sleeping capsule configured for connecting to a space station and accommodating crew members with individual sleeping cells arranged in a circular arrangement within the sleeping capsule. 
     Example 1 (SP-Patient Mar. 1, 2019) 
     A 29 year old male with a malignant brain tumor was taken off chemotherapy because it was not effective at combating the tumor. The magnetic cap shown in  FIGS. 8-13  was worn by the patient for three 24 hour periods over the course of 4 days. Each of the magnets was a 2 inch by ½ inch grade n45 neodymium ring mounting magnet with the north pole being the strong pole. The north poles of the magnets were directed inwards towards the patient&#39;s head and tumor therein. Accordingly, when the hat was positioned on the patient&#39;s head, the tumor resided within five compressed magnetic fields.  FIG. 13  shows the interaction of the magnetic fields of the two magnets on the side and the magnet on the top of the hat. Two additional magnetic fields are provided, in addition to the field shown in  FIG. 13 , by the magnets on the front and back of the cap. A first series of magnetic resonance imaging (MRI) images of the patient&#39;s brain were obtained after chemotherapy was ended, which was 3 weeks prior to the beginning of the static magnetic therapy. A second series of MRI images of the patient&#39;s brain was obtained 2 days after the above discussed static magnetic therapy. The tumor had shrunk roughly 30% due to the four 24 hour static magnetic therapy sessions over the course of 4 days and was in the final stage of dying, without any other cancer therapies being administered, when comparing the first series of MRI images with the second series. 
     Example 2 
       FIGS. 69A-69D  show the progression of magnetic therapy and full healthy tissue regrowth of an approximately 1 inch by 1 inch mast cell tumor growing in a dogs lip. A pair of annular magnets  2010  were used to treat a tumor (T) located in the lip of the dog, as shown in  FIG. 69B . One magnet  2010  was placed on the outside of the lip and the other was placed on the inside of the lip. The magnets  2010  were held in place through magnetic attraction which clamped the magnets  2010  to the lip. Each annular magnet  2010  was a neodymium magnet, with a thickness of 0.095 inches, an inner diameter of 1.296 inches, and an outer diameter of 1.652 inches. At the surface (i.e., at the point of contact with the magnetometer), each annular magnet  2010  generated a magnetic field of 1.35 kG. The dog was approximately 10 years old, with a tumor which had grown over the course of approximately 10 months. After 19 continuous hours of treatment with the pair of annular magnets  2010 , as described above, the tumor became necrotic and treatment with the pair of magnets was ceased. Five days after cessation of the treatment, the necrotic tumor tissue began to separate from the healthy lip tissue and flake off, as shown in  FIG. 69C . The tissue at the site of treatment was quick to heal, regenerate and regrow into healthy tumor-free tissue, with regrowth and regeneration of healthy tissue being clearly evident one month after cessation of the treatment with the pair of annular magnets, as shown in  FIG. 69D . During treatment, the dog did not appear to show any signs of pain, distress, blood loss, infection, or additional generation of any bodily fluids. 
     As described above, the method of treating tumors and causing full regrowth and regeneration of tissue may hold certain types of immune-related cells within the treatment area. The method of treating tumors and causing full regrowth and regeneration of tissue may also hold the body&#39;s stem cells within the treatment area for an extended period of time, and cause an increased influx of stem cells, effecting the observed enhanced healing, regrowth and regeneration of the tumor-free tissue. The resultant full regrowth is distinguishable from the results of surgical tumor removal. When a tumor is excised by a surgeon, the removed tissue will not grow back resulting in the fully healed lip looking similar to  FIG. 69C . 
     Experiment 3 
     The magnetic muzzle shown in  FIGS. 19-23  was used to treat multiple mast cell tumors on the lips and mouth region of an approximately 10 year old dog. The tumors had grown over the course of approximately a week while the dog was being administered chemotherapy. Approximately 10 mast cell tumors between ⅙ to ⅓ of an inch in diameter were growing on the lips and mouth region of the dog. The mast cell tumors were rapidly growing and new tumors were developing despite the chemotherapy treatment. The magnetic muzzle was attached to the dog for a period of 24 hours, with small breaks to allow for eating and drinking. The muzzle included two front magnets which were 1⅝ inch grade 45 neodymium ring magnets and two rear magnets which were 2 inch grade 45 neodymium ring mounting magnets having the north poles as the strong poles. The north poles of the magnets were facing inwards, towards the magnets on the opposing side of the muzzle, to create compressed magnetic fields around the mouth of the dog, thus exposing the tumors to compressed magnetic fields. The muzzle was positioned as shown in  FIG. 23 . When the muzzle was removed after 24 hours, the cells of each tumor became neurotic, scabbed over, and flaked off within 2 days. The location of each tumor experienced full regrowth of healthy tissue thus indicating an increased presence of stem cells. 
     Experiment 4 
     Magnetic therapy was used to treat three malignant tumors in the neck of an approximately 10 year old dog. The tumors had grown over the course of approximately two weeks while the dog was being administered chemotherapy. The tumors had diameters in the range of ½ of an inch to 1 inch. The magnetic collar shown in  FIGS. 45 and 46  was secured around the dog&#39;s neck adjacent the tumor locations. The magnetic collar contained four 4 inch by ⅝ inch grade 45 neodymium ring magnets positioned on opposing sides of the dogs neck and a 3 inch by 1.2 inch grade 45 neodymium ring magnet positioned below the neck, as seen in  FIG. 46 . The north poles of the mounting magnets were each directed towards the neck of the dog resulting in the tumors residing within five compressed north pole magnetic fields. The magnetic collar was loosely secured to the neck of the dog. The loose fit resulted in the location of the magnets constantly being shifted along the length of the neck and rotating around the neck with the movement of the dog. The shifting of the collar, and attached magnets, provided expanded coverage of the strongest portions of the compressed magnetic fields throughout the neck. The magnetic collar was secured to the dog for two periods of four hours each day for 7 days. After 7 days, each of the tumors ruptured and the necrotic cells drained out. Each location experienced natural regrowth without additional medical intervention indicating increased stem cell presence. 
     Experiment 5 
     The effect of electricity with regard to ring magnets was tested using a plasma globe  1900 .  FIGS. 70 and 71  shown two ring magnets  1910  attached to a plasma globe  1900 . The two magnets  1910  we taped to the globe with the north poles facing inwards. As seen in  FIG. 70 , plasma filaments  1920  are directed to the magnets.  FIGS. 72 and 73  show the ring magnets  1910  when being held in place by a user&#39;s hand. When held in place by the hand of a user, a larger amount of plasma filaments  1920  are directed to the magnets  1910  resulting in plasma ring  1922  forming around the entire circumference of each magnet  1910 .  FIG. 74  shows a single magnet  1910  attracting enough plasma filaments  1920  to create a plasma ring  1922  around the globe  1900  facing side of the magnet  1910 , similar to the two magnets  1910  shown in  FIGS. 70 and 71 . 
       FIG. 75  shows a mounting magnet  1912  placed on the globe  1900  with the north pole facing inwards. Only the central magnetic portion of the mounting magnet was contacting the globe, the outer shell, which is separated from the magnetic portion by an insulating polymer, was not touching the globe. The mounting magnet attracted more plasma filaments  1920  than the ring magnets  1910 , resulting in a large plasma donut  1924  forming below the magnet  1912 . A concentration of the plasma filaments were directed at the central opening of the mounting magnet indicating the electricity was being pulled through the central opening by the magnetic field. To confirm that the magnetic field was pulling electricity through the central opening of the magnetic, a voltmeter used to read the voltage present on the outer shell of the mounting magnet (which was not contacting the globe and was separated from the magnetic portion by an insulating polymer). The voltmeter indicated the voltage of the shell was fluctuating between 0.07 and 0.13 mV, thus indicating the electricity was being carried to the shell by the magnetic field. 
     Each of the experiments was also performed with the south pole of the magnets  1910 ,  1912  facing towards the globe  1900  and resulted in the similar plasma attraction. 
     Experiment 6 
     The effect of magnets on the electricity produced by the body was tested by placing a grade 45 neodymium housing magnet having a 3 inch diameter and a ⅝ inch thickness on different portions of a patient&#39;s head and determining the effect on the EEG readings. The EEG electrodes were attached to the patient&#39;s head using the 10-20 system which is well known in the art. The 10-20 system uses 19 electrodes with the location of the electrode indicated by letters based on the brain region or lobes (Fp=fronto-polar; F=frontal; C=central; P=parietal; O=occipital; T=temporal) flowed by a number or letter indicating the distance to the midline (numbers range from 1-6 with large numbers indicate greater distance to the midline, odd numbers indicating left hemisphere and even numbers indicating right hemisphere; the letter “z” indicated on the midline). When the magnet was placed in between electrodes, the readout of the electrodes surrounding the magnet would produce very large inconsistent waves indicating the electrical signal to the electrode would fell below the detectable levels of the EEG machine. For example, when the patient was connected to each electrode and the machine recorded the electrical signals of the patient&#39;s head, each electrode detected a recordable signal resulting in a consistent, readable wave being produced for each electrode. When the magnet was placed on the left rear quadrant of the head, each of electrodes T3, C3, P3, O1, and T5, which are located in the rear left quadrant of the head, were exposed to electrical signals too small for the EEG machine to detect resulting in the large unreadable waves. This indicated the electricity is the brain was being pulled to the magnet and away from the electrodes. 
     Experiment 7 
     A strength of a magnetic field produced by a 2 inch by ½ inch grade n45 neodymium ring mounting magnet was measured using a gaussmeter placed on the face of the strong pole. The gaussmeter measured 2.03 kilogauss (kG). A subject them completely covered the magnet with his hand and measured the strength of the magnetic field that had traveled through his hand. The magnetic field was measured at 0.02 kG, thus indicating the magnetic field retain significant strength through approximately 1 inch of tissue. 
     A strength of a magnetic field produced by a 3 inch by ¾ inch grade n45 neodymium ring mounting magnet was measured using a gaussmeter placed on the face of the strong pole. The gaussmeter measured 2.05 kG. A subject then placed the gaussmeter on a side of his calf, with no magnet near the calf, which resulted in a reading of 0.0 Gauss. The subject then placed the magnet on the side of his calf opposite the gaussmeter, with the circumference of the magnet being completely covered. The strength of the magnetic field was then measure, resulting in a strength of 0.1 Gauss on the opposing side of the calf from the magnet. A width of the calf was measured to be approximately 6 inches. The reading of 0.1 Gauss indicates the magnetic field retains significant strength through approximately 6 inches of tissue. 
     Example 8 
     An embodiment of a static magnet capable of producing a strong static magnetic field through a human body, or a body of other living animals, was created and the static magnetic field was measured. Table 1 shows the strength of the static magnetic field on the strong surface of the magnet at the points shown in  FIG. 76A . 
     
       
         
           
               
               
               
             
               
                   
                 TABLE 1 
               
               
                   
                   
               
               
                   
                 Location on Magnet 
                 Magnetic field strength (kilogauss “kG”) 
               
               
                   
                   
               
             
            
               
                   
               
            
           
           
               
               
               
            
               
                   
                 Z1 
                 5.37 
               
               
                   
                 Z2 
                 6.39 
               
               
                   
                 Z3 
                 5.79 
               
               
                   
                 Z4 
                 5.71 
               
               
                   
                 Z5 
                 5.16 
               
               
                   
                 Z6 
                 5.28 
               
               
                   
                 Z7 
                 5.01 
               
               
                   
                 Z8 
                 4.90 
               
               
                   
                 Z9 
                 −5.24 
               
               
                   
                 Z10 
                 −9.11 
               
               
                   
                 Z11 
                 −5.11 
               
               
                   
                 Z12 
                 −5.4 
               
               
                   
                 Z13 
                 −8.58 
               
               
                   
                 Z14 
                 −5.44 
               
               
                   
                 Z15 
                 −5.13 
               
               
                   
                 Z16 
                 −8.73 
               
               
                   
                 Z17 
                 −5.30 
               
               
                   
                 Z18 
                 −5.52 
               
               
                   
                 Z19 
                 −8.89 
               
               
                   
                 Z20 
                 −5.10 
               
               
                   
                   
               
            
           
         
       
     
     Table 2 shows the strength of the static magnetic field extending out from the strong surface of the magnet, with air as the medium, at the points shown in  FIG. 76A , as well as the center. 
     
       
         
           
               
               
               
               
               
               
             
               
                   
                 TABLE 2 
               
               
                   
                   
               
               
                   
                 Center 
                 Point Z1 
                 Point Z2 
                 Point Z3 
                 Point Z4 
               
               
                   
                   
               
             
            
               
                   
               
            
           
           
               
               
               
               
               
               
            
               
                 1″ from 
                 2.14 kG 
                 2.03 kG 
                 2.33 kG 
                 2.40 kG 
                 2.17 kG 
               
               
                 surface 
               
               
                 2″ from 
                 1.51 kG 
                 1.06 kG 
                 1.06 kG 
                 1.19 kG 
                 1.13 kG 
               
               
                 surface 
               
               
                 3″ from 
                 0.91 kG 
                 0.62 kG 
                 0.62 kG 
                 0.68 kG 
                 0.67 kG 
               
               
                 surface 
               
               
                 4″ from 
                 0.56 kG 
                 0.40 kG 
                 0.40 kG 
                 0.43 kG 
                 0.44 kG 
               
               
                 surface 
               
               
                 5″ from 
                 0.35 kG 
                 0.28 kG 
                 0.28 kG 
                 0.29 kG 
                 0.29 kG 
               
               
                 surface 
               
               
                 6″ from 
                 0.24 kG 
                 0.18 kG 
                 0.18 kG 
                 0.20 kG 
                 0.20 kG 
               
               
                 surface 
               
               
                 7″ from 
                 0.16 kG 
                 0.13 kG 
                 0.13 kG 
                 0.14 kG 
                 0.15 kG 
               
               
                 surface 
               
               
                 8″ from 
                 0.12 kG 
                 0.10 kG 
                 0.10 kG 
                 0.10 kG 
                 0.11 kG 
               
               
                 surface 
               
               
                 9″ from 
                 0.09 kG 
                 0.07 kG 
                 0.07 kG 
                 0.08 kG 
                 0.08 kG 
               
               
                 surface 
               
               
                 10″ from 
                 0.07 kG 
                 0.06 kG 
                 0.06 kG 
                 0.06 kG 
                 0.06 kG 
               
               
                 surface 
               
               
                   
               
            
           
         
       
     
     Table 3 shows the strength of the magnetic field on the side surface of the magnet  1210  (on the surface of the metal shield) at the points shown in  FIG. 76B . 
     
       
         
           
               
               
               
             
               
                   
                 TABLE 3 
               
               
                   
                   
               
               
                   
                 Location on side of magnet 
                 Strength (Kg) 
               
               
                   
                   
               
             
            
               
                   
               
            
           
           
               
               
               
            
               
                   
                 Y1 
                 1.00 
               
               
                   
                 Y2 
                 −3.60 
               
               
                   
                 Y3 
                 1.02 
               
               
                   
                 Y4 
                 −3.21 
               
               
                   
                   
               
            
           
         
       
     
     Table 4 shows the strength of the magnetic field on the weak surface of the magnet  1210  (on the surface of the metal shield) at the points shown in  FIG. 76C . 
     
       
         
           
               
               
               
             
               
                   
                 TABLE 4 
               
               
                   
                   
               
               
                   
                 Location on side of magnet 
                 Strength (Kg) 
               
               
                   
                   
               
             
            
               
                   
                 X1 
                 1.24 
               
               
                   
                 X2 
                 1.31 
               
               
                   
                 X3 
                 1.34 
               
               
                   
                 X4 
                 1.33 
               
               
                   
                   
               
            
           
         
       
     
     It is to be understood that the devices and methods for stimulating the immune system to treat abnormal and damaged tissue using compressed magnetic fields is not limited to the specific embodiments described above, but encompasses any and all embodiments within the scope of the generic language of the following claims enabled by the embodiments described herein, or otherwise shown in the drawings or described above in terms sufficient to enable one of ordinary skill in the art to make and use the claimed subject matter.