Hyperoxygenation/Hyperthermia Treatment Apparatus

Abstract

The described invention is a hyperthermia and hyperoxygenation medical apparatus for treating diseases of the blood and purification of stored blood supplies. The invention comprises a hollow chamber through which blood is made to flow. Within the hollow chamber are a heating element and a gas diffuser. As blood flows through the chamber, blood is heated to a preset limit while ozone or other beneficial gas is diffused into the blood by a diffuser with pores to a preset concentration. After heating and gasification, blood exits the hollow chamber and is either returned to the patient or returned to storage. The hollow chamber, heating element and gas diffuser are designed to maintain efficient, linear blood flow through the invention, in part by taking advantage of die radial symmetry of the hollow chamber and diffuser designs. Linear flow ensures uniform and controlled heating and gasification of the blood with negligible undesirable turbulence to the blood components.

Claims

1. A device for treating illnesses of the blood comprising a chamber suitable to have blood pumped through it an heater and gas diffuser combination positioned on the longitudinal axis of the chamber in which the space between the heater and gas diffuser combination and the inner surface of the chamber have cross-sectional radial symmetry along the said longitudinal axis of the chamber and further in which the radial thickness of blood pumped between the heater and gas diffuser combination and the inner surface of the chamber permits conductive heating of all of the pumped blood in the time the blood flows through the chamber between the heater/oxygenator combination and the inner wall of the chamber.

2. The device of claim 1 in which the heater heats the blood pumped through the device to a specified temperature between 105 degrees F. and 106.7 degrees F.

3. The device of claim 2 in which the heater heats the blood to one or more desired temperatures between 105 degrees F. and 106.7 degrees F.

4. The device of claim 1 in which gas diffuser further comprises a plurality of pores suitable to permit the pumping of a gas into and through the blood flowing through the hollow cylinder.

5. The device of claim 4 in which the gas diffuser saturates the blood with one of a gas including ozone or other therapeutic form of gaseous molecular oxygen.

6. The device of claim 1 in which the elliptical solid heater/oxygenator combination is fixed in position by one or more small diameter columns in which the diameter of each of the one or more columns is small enough not to disrupt the flow of blood through the device.

7. The device of claim one in which the device further comprises a pump controller to control the rate of oxygenation a power cord and controller to control the heat emitted by the heater a vent to permit the outflow of excess oxygen or ozone from the device.

8. The device of claim 1 in which the chamber and the heater and gas diffuser are elliptical in cross section.

9. The device of claim 1 in which the chamber and the heater and gas diffuser are circular in cross section.

10. The device of claim 1 in which the interior surface of the chamber and the outer surface of the gas diffuser are coated in a low friction, non-bioreactive coating.

11. The device of claim 1 in which the heater comprises a plurality of heating elements, each controlled by a separate controller, disposed within the device to heat the blood.

12. The device of claim 1 in which a plurality of gas diffusers, each controlled by a separate pressure controller and capable of diffusing a different gas into the blood, are disposed in the device to oxygenate the blood.

13. A device for killing harmful micro-organisms in the blood through the application of hyperthermia and hyperoxygenation, in which the device comprises: an inlet tube connecting the patient's blood draw needle or the blood from a patient ex vivo to a hollow cylindrical tube sealably connected to the inlet tube into which the blood is pumped by a pump which is controlled by a pump controller for treatment and in which are disposed a heating element powered by a power supply and controlled by a temperature controller, and gas diffuser through which a therapeutic gas is diffused under pressure by a pump and controlled by a pump regulator, and in which the heating element and gas diffuser are placed in radial symmetry within the hollow cylindrical tube.

14. The device of claim 13 in which the heating element heats the blood pumped through the device to a specified temperature between 105 degrees F. and 106.7 degrees F.

15. The device of claim 14 in which the heating element heats the blood to one or more desired temperatures between 105 degrees F. and 106.7 degrees F.

16. The device of claim 13 in which gas diffuser further comprises a plurality of pores suitable to permit the pumping of a gas into and through the blood flowing through the hollow cylindrical tube.

17. The device of claim 16 in which the gas diffuser saturates the blood with one of a gas including ozone or other therapeutic gaseous molecular oxygen.

18. The device of claim 13 in which the elliptical solid heating element and gas diffuser combination is fixed in position by one or more small diameter columns in which the diameter of each of the one or more columns is small enough not to disrupt the flow of blood through the device.

19. The device of claim 13 in which the device further comprises a pump controller to control the rate of oxygenation a power cord and controller to control the heat emitted by the heater a vent to permit the outflow of excess oxygen or ozone from the device.

20. The device of claim 13 in which the hollow cylindrical tube and the heater and gas diffuser are elliptical in cross section.

21. The device of claim 13 in which the hollow cylindrical tube and the heater and gas diffuser are circular in cross section.

22. The device of claim 13 in which the interior surface of the hollow cylindrical tube and the outer surface of the gas diffuser are coated in a low friction, non-bioreactive coating.

23. The device of claim 13 in which the heating element comprises a plurality of heating elements, each controlled by a separate controller, disposed within the device to heat the blood.

24. The device of claim 13 in which a plurality of gas diffusers, each controlled by a separate pressure controller and capable of diffusing a different gas into the blood, are disposed in the device to oxygenate the blood.

25. A blood treatment device suitable to heat blood to a temperature, of at least 105 degrees F. and no more than 106.7 degrees F. and hyperoxygenate blood in order to treat viruses, disease organisms, cancer cells and/or other harmful live blood components without harming beneficial blood components and comprising an entry port through which blood enters the device, a hollow cylinder into which blood flows, which cylinder diameter is substantially larger than the entry port and which cylinder is longer than the diameter of the cylinder, in which is disposed a heating element controlled by a temperature controller and powered by a power supply further within the heating element is disposed a hollow elliptical gas diffuser on the surface of which hollow elliptical gas diffuser is a plurality of pores suitable to diffuse one or more therapeutic gases into the flowing blood in which the flow of gas is made and controlled by a gas pressure regulator and an exit port through which blood exits the device.

26. The device of claim 14 in which the length of the hollow cylinder is sized to ensure flow of blood through the cylinder in the region of the heating element and diffuser without eddies or turbulence.

27. The device of claim 14 in which the gas diffused into the blood is one selected from a group consisting of ozone and molecular oxygen.

28. The device of claim 14 further comprising a vent to permit the outflow of undiffused gas.

29. The device of claim 14 further comprising a pump to control the flow of blood through the device.

30. The device of claim 14 in which the temperature controller of the heating element controls the heating of the blood to a specific temperature of at least 105 degrees and no higher than 106.7 degrees Fahrenheit.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] FIG. 1 depicts a representation of the invention showing the preferred embodiment.

[0017] FIG. 2 depicts an alternate embodiment of the invention in which the chamber is a hollow elliptical solid shape.

[0018] FIG. 3 depicts a top and side view of the preferred diffuser of the invention with ozone pores.

[0019] FIG. 4 depicts a side view of the position of the preferred embodiment of the diffuser in the preferred embodiment of the chamber.

[0020] FIG. 5 depicts an alternate embodiment of the invention in which a tank of heated water acts as the heating element of the device.

[0021] FIG. 6 depicts a cross section of the chamber and diffuser showing that each of the chamber and diffuser has an elliptical cross section.

[0022] FIG. 7 depicts another cross-section of the chamber and diffuser in which the heating element is a radiant heating bar disposed within the diffuser.

[0023] FIG. 8 depicts a cross section of the preferred embodiment of the chamber and diffuser in which the chamber and diffuser each have a circular cross section.

DETAILED DESCRIPTION OF THE INVENTION

[0024] The basic mode of operation of the invention is to heat the blood to a specific, controlled temperature between 105 degrees F. (40.55 degree C.) and 106.7 degrees F. (41.5 degrees C.) while simultaneously hyperoxygenating the blood with ozone or other suitable gas to maximum saturation. In this combination, the high temperature and applied gasification kills or weakens cells and pathogens in the blood susceptible to death at such temperatures. Cells and viruses which are not killed by the high temperature but which are susceptible to high oxygen levels are killed by hyperoxygenation. Similarly, cells and pathogens susceptible to high oxygen levels are killed or weakened by the oxygen levels in the blood. Those cells or viruses not killed by the hyperoxygenation are weakened sufficiently such that they are then killed by the hyperthermic conditions. The blood is then returned to the body. Depending on the patient's illness, the blood may either be cooled before being returned to the body or it may be reintroduced to the body while still warm. Oxygen or ozone diffused into the blood does not typically need to be removed prior to the blood being returned to the patient as they pose no threat to the patient. Hyperthermic/hyperoxygenated blood has the ability to kill pathogens or cancer cells in the body. The design of the invention prevents or minimizes turbulence, eddies and other flow impediments, resulting in even flow past the heating element and hyperoxygenator in a known and controlled manner. As a result, all blood introduced into the invention is heated to a known and controlled temperature and is hyperoxygenated to an equally known and controlled level at an operator controlled rate of flow.

[0025] Referring first to FIG. 1, a preferred embodiment of the invention is depicted. The patient's blood is drawn from the body through a tube inserted in a patient's vein or artery (not depicted) to the inlet 14 of the invention 100, which fluffier comprises a chamber 1, an ozone diffuser 2 and a heating element 3. As noted, “ozone” is used to refer generally to any molecular oxygen with therapeutic value. Blood is drawn from the patient through any means known in the health care industry for allowing a controlled high rate of blood flow ex vivo such as might be performed for transfusion or dialysis. The line segment AB represents the imaginary longitudinal axis of each of the chamber 1 and diffuser 2.

[0026] To obtain the blood from die patient, the patient's blood is drawn and flows into a connecting tube 10. Connecting tube 10 is of approximately the same diameter as the tube carrying blood from the body. To account for fluid flow boundary conditions inside the connecting tube 10, the inner surface of the connecting tube 10 may be coated with a low friction, non-bioreactive coating. Because a small diameter tube increases the likelihood of turbulent or non-linear flow, the low friction coating is used to reduce the amount of shear in the flow. This helps to ensure blood flowing into chamber 1 flows smoothly. The rate of flow into chamber 1 is maintained by use of a pump 28. The design of the pump 28 is such that blood cells and blood components are not damaged by the pump 28 or pumping action. Suitable and commercially available pumps for this are known in the industry. Upon entry into chamber 1, blood temperature is at body temperature (approximately 98.6 degrees F.) or slightly lower, having potentially cooled while passing along the connecting tube 10 and through the pump 28.

[0027] The connecting tube 10 and chamber 1 are ideally constructed of a clear material, such as glass, plastic or other material which will not react either to heat, oxygen or blood. This permits the operator to view the flow of blood through the invention 100 and to make oxygenation and blood flow adjustments if needed. Flow adjustments are made by speeding up or slowing down the pumping rate of pump 28. As shown more clearly in FIG. 8, in the preferred embodiment chamber 1 is a hollow circular cylinder. In this same preferred embodiment, the diffuser 2 is a hollow, three-dimensional ellipsoid with a circular cross-section. It should be understood that while the preferred embodiment comprises a hollow circular cylinder for the design of the chamber 1 and 3-D ellipsoid for the design of the diffuser 2, the invention is in no way limited to these shapes. The invention 100 may be practiced using any geometry for the chamber 1 and diffuser 2 which permits blood to be pumped through the invention 100 and over or around the heating element 3 and diffuser 2 in a manner which heats and oxygenates all of the blood uniformly. Thus, the chamber 1 may have cylindrical geometry, rectangular geometry or otherwise. It is, however, important for the cross-sectional geometry of the chamber 1 to match the cross-sectional geometry of the diffuser 2 or, if applicable, the heating element 3. The longitudinal axis of the diffuser 2 is positioned to lie directly on the longitudinal axis of the chamber 1. This imposes radial symmetry on the invention 100, which helps to ensure the blood flows through the chamber without turbulence or non-linear flow characteristics. Referring to FIG. 6, in an alternative embodiment of the invention 100, chamber 1 has an elliptical cross-section, as does diffuser 2. As in the preferred embodiment, in the alternative embodiment, the distance between a point on the outer surface of the diffuser 2 and the nearest point on the inner surface of the chamber 1 remains constant or very close to constant. Blood flow is constrained between approximately parallel surfaces, which reduces the likelihood of turbulent or non-linear flow.

[0028] Referring again to FIG. 1, chamber 1 has a diameter larger than the diameter of the connecting tube 10, resulting in a reduction of forward velocity of blood flow through the chamber 1. The reduction in the velocity of the blood while in the chamber 1 further reduces the likelihood of turbulence or non-linear flow of the blood through the invention 100. The inner surface of the chamber 1 may also be coated with a low friction, clear, non-bioreactive coating. The combination of the larger cross-sectional area of the chamber 1 as compared to the connecting tube 10 and smooth inner surface means the inner surface boundary conditions are minimized, thus reducing shear forces in the chamber 1. As shown in FIG. 1, the diameter of chamber 1 is approximately three times the diameter of connecting tube 10, although this ratio is not strictly necessary. Flow rate per unit length is proportional to the cross-sectional area through which the fluid flows. In that the specific heat of blood is known, dimensions of the invention 100, such as diameter and length, and likewise dimensions of the diffuser 2 may be determined by calculation based on the characteristics of the pathogens or harmful cells sought to be killed. For clarity, there is no single rate of flow of blood through invention 100. The dimensions of the invention 100 depend in part on flow factors necessary for effective operation of the invention 100.

[0029] As depicted in FIG. 1, the two ends 21 and 23 of the chamber 1 are sealably connected to the chamber 1 perpendicularly. So long as the diameter of the chamber 1 is large enough to permit linear flow through its length, it is generally possible to have right angle corners at the end caps 21 and 23. However, end caps 21 and 23 may connect to the side of chamber 1 using a rounded corner. This rounded corner further reduces the chance for non-linear or turbulent flow. If a higher rate of blood flow through the invention 100 is desired, a rounded corner is generally more optimal than a right angle connection.

[0030] In an alternate embodiment of the invention 100, and referring to FIG. 2, chamber 1 may take the form of a hollow elliptical solid-essentially the same shape as the preferred shape of the diffuser 2. For clarity, the shape of chamber 1 in this embodiment may also be referred to as a prolate spheroid or ellipsoid, that is to say, three dimensional and hollow. In this alternate embodiment, the geometry of the outer surface of diffuser 2 closely conforms to the geometry of the inner, surface of the chamber 1. As a result, the blood flow through the chamber 1 experiences minimal disruptions which might cause turbulence or non-linear flow.

[0031] Referring to each of FIG. 1 and FIG. 2, wholly contained within chamber 1 is a heating element 3 disposed along the long axis of the diffuser 2. The heating element 3 may be a helical wire element. However, any form of heating device capable of fitting within the chamber 1, in either embodiment, and heating blood to a precise and predetermined temperate between 105 degrees F. and 106.7 degree F. as blood flows the length of the chamber 1 may be used. In a preferred embodiment, heating element 3 in the form of a helical coil is disposed on the inner surface of an ozone diffuser 2, described below. The heating element 3 is constructed of a material which does not react either to chamber 1, blood or the ozone diffuser 2. Referring to FIG. 5, in an alternate embodiment, the heating element may be a reservoir 50 of hot water which is circulated via piping through and around the interior of the diffuser 2.

[0032] In each of FIG. 1 and FIG. 2, only a single, uniform helical heating element 3 is depicted. This is not a limitation. As described above, any suitable heating element, such a ribbon heating element (not depicted), disposed within or outside the ozone diffuser 2, may be used. For example and not as a limitation, a plurality of heating ribbons may be embedded in a hollow cylinder of a diameter smaller than that of chamber 1 and placed such that the longitudinal axes of each of the hollow cylinder containing the plurality of heating elements 3 and chamber 1 are congruent. In this embodiment, blood would flow outside and through the hollow cylinder fur heating. The hollow cylinder embodiment requires perforation to permit ozone to be diffused through the flowing blood. How, in this embodiment, the important factor is the retention of radial symmetry to heat the blood evenly through the chamber 1.

[0033] As depicted in FIG. 8, the critical factor in thorough hyperthermia of the blood is the radial symmetry of the chamber 1 and the combination of heating element 3 (or plurality of heating elements 3) and diffuser 2. Based on flow characteristics of a fluid through a cylinder, flow of the fluid is slower at any surface, such as the interior surface of the cylinder, and faster at the center. However, the flow is radially symmetric. Any heating element 3 which heats in a radially symmetric manner may serve as a sufficient heater. Likewise, any diffuser 2 which diffuses gas in a symmetric pattern may serve as a diffuser 2. In FIG. 7, another embodiment of the heating element 3 is depicted. The heating element 3 of FIG. 7 is a solid bar 30.

[0034] The design of the chamber 1 is such that the rate of blood flow through the chamber 1 is sufficiently long, in terms of time, as to ensure uniform heating of the blood and all blood components along the heating coil 3 to the necessary temperature while ensuring accurate control of the temperature of the blood throughout chamber 1. The heating coil 3 is controlled by a regulator 7 and power supply 6, each also depicted in FIG. 1. No specific dimensions of chamber 1 are indicated. In the event a slower hyperthermia cycle is indicated, a longer chamber 1 and longer heating element 3 are required. The primary factors which determine the size of various parts of the invention 100 include the amount of blood to be treated, the temperature or temperatures to which the blood is raised, whether simultaneous or independent hyperoxygenation is performed, the amount of time the blood remains as the desired temperature. All of these elements, of course, depend on the underlying disease the patient has.

[0035] Thus, while a single heating element 3 is depicted in FIG. 1, this is not a limitation. Although it is necessary to maintain radial symmetry of the heating element 3 along the long axis of the chamber 1, in some embodiments it may be useful to provide a plurality of heating elements 3, each controlled by a separate regulator 7 (although wiring techniques may permit a shared power supply 6). A plurality of heating elements 3 would permit heating gradients to be imposed along die length of the chamber 1. For example, a higher temperature heating element 3 at the upstream end of the flow of blood in the chamber 1, with reduced temperature heating elements (one or more) 3 downstream would result in blood subjected to rapid temperature rise following by slower additional temperature rise. In another embodiment, a rising temperature gradient could be imposed using a plurality of heating elements 3 along the flow of blood through the chamber 1. The use of a plurality of individually controlled heating elements, which might include gaps between any two to permit some cooling of the blood, permits precise temperature control as the blood is heated, including the length of time the blood remains at a desired temperature.

[0036] As further depicted in FIG, 1, an off-the-shelf, commercially available ozone source (not depicted) is employed to contain or produce a supply of high concentration ozone, which is then disposed into an ozone supply 4 connected to the diffuser 2 via an ozone connection tube 24 for infusion of ozone into the blood. Ozone pressure in the diffuser 2 is controlled by a pressure regulator 5.

[0037] As with the heating element 3, the ozone diffuser 2 is placed in the chamber 1 in a radially symmetry manner. As depicted in FIG. 1, in a preferred embodiment, the ozone diffuser is an elongate, hollow elliptical solid. The cross-section of the diffuser 2 matches, the cross-section of the chamber 1, as depicted in FIG. 6 and FIG. 8. The outer surface of the ozone diffuser 2 imposes another fluid flow boundary condition. However, the elongate, elliptical shape of the ozone diffuser 2 minimizes any disruption to blood flow. The outer surface of the diffuser 2 may also have a low friction coating applied to it. Referring to FIG. 6 and FIG. 8, the radial symmetry of such a diffuser 2 shape within the hollow cylinder comprising the chamber 1, when mated to the cross-section of the chamber 1, reduces the likelihood of turbulent or non-linear flow. However, in the preferred embodiment, an operator of the invention 100 must be aware of the increase of blood flow rate as the flow approaches the widest (radially) part of the ozone diffuser 2 and the concomitant slowing of blood flow as blood flows past the narrower part of the ozone diffuser 2. This issue is not significant in the alternate embodiment of FIG. 2, in that the shape of chamber 1 closely conforms to the shape of the diffuser 2 along the entire length of the diffuser 2.

[0038] Referring now to FIG. 3, the ozone diffuser 2 is ideally an elliptical solid in shape and hollow. The form of the diffuser 2 is such that, in an embodiment, it is disposable within a helical form of heating element 3. If the heating element 3 is placed on the outer surface of diffuser 2, the diameter of the wire forming the heating element 3 must be small enough not to disrupt the flow of blood. In alternate embodiments, the heating element 3 or plurality of heating elements 3 are disposed within the diffuser 2. Upon the surface of the diffuser 2 are disposed a plurality of pores 22 along the entire surface. The number and size of pores is determined by level of ozone or oxygen saturation required or desired. So long as the heating element 3 is suitably shaped to accommodate the pores 22 of the ozone diffuser b, heating elements 3 (one or more) may be disposed inside or outside the ozone diffuser 2. The only other significant limitation is the need to maintain radial symmetry.

[0039] Referring now to FIG. 4, ozone is infused into the blood via pressure differentials created by the pores 22 which disperse the ozone uniformly across the blood flow through the ozone diffuser 2 within chamber 1. Ozone not absorbed into the blood is vented from the chamber 1 via a vent 13. The diffuser 2 is mounted within the chamber 1 upon one or more support columns 9. The support columns 9 are of sufficiently small diameter and shape so as to prevent interference with blood flow and to prevent the formation of eddies, turbulence or other nonlinear flow.

[0040] Still referring to FIG. 4, at least one support column 9 is hollow. This allows a power cable 12 to be run into the diffuser 2 to power the heating element 3. In the event one or more heating elements 3 is not in contact with the ozone diffuser 2, a separate, small diameter column must be run into the chamber 1 to power each of the one or more heating element 3. If more than one heating element 3 is used, a plurality of power cables 12 may be used. Column 13 is hollow to allow passage of a gas from its supply.

[0041] FIG. 1 and FIG. 2 each depict a single ozone diffuser 2. Although the invention 100 includes a minimum of one diffuser 2 capable of diffusing some hyperoxygenating gas into the blood, other embodiments allow a plurality of diffusers 2 to be disposed in the chamber 1. As with the optional plurality of heating elements 3, the primary limitations on the number and placement of ozone diffusers 2 are the equal needs to maintain radial symmetry and assume linear flow. In the event multiple diffusers 2 are used, it is equally permissible to use a plurality of beneficial gasses. For example, ozone (O.sub.3) might be used in conjunction with oxygen (O.sub.2). Although some human cells, such as lung cells, may be harmed by the presence of ozone, it is generally considered medically that over-saturating blood with oxygen or ozone is not harmful to the patient and poses no medical threat or risk.

[0042] The outer surface of the ozone diffuser 2 may be coated with a low friction material to reduce interaction with the flow of blood over the ozone diffuser 2. In the event a plurality of ozone diffusers 2 are used, a low friction coating may be used with one or more of the plurality of ozone diffusers 2 depending on the desired flow characteristics sought proximate to each.

[0043] Although the ozone diffuser 2 depicted in FIG. 3 is described as being hollow, a hollow ozone diffuser 2 is suitable where the pressure applied to the gas diffused into the blood is sufficient to prevent the incursion of blood into the diffuser 2. In applications in which the gas pressure is too low to accomplish this, an alternate embodiment of the ozone diffuser 2 is a solid body elliptical or other radially symmetric diffuser 2 with pores 22 connected to an ozone supply 4 via small connecting holes drilled or otherwise disposed into the body of the solid ozone diffuser 2. In yet another embodiment, a network of small tubes may be disposed on the surface of the solid ozone diffuser 2. The small tubes then connect to the pores 22 of the ozone diffuser 2.

[0044] Referring to either FIG. 1 or FIG. 2, the pressure applied to the hyperoxygenating gas by the pressure regulator 5 must be sufficient to impose radial symmetry in the diffusion of gas through the blood. Any gas is naturally buoyant in a fluid, such as blood. This makes it more difficult to diffuse ozone or other hyperoxygenating gas to the downward side of the chamber 1 because buoyancy works against diffusion on the downward side. In this disclosure, the “downward” side is simply the side which is toward gravity and away from an “up” or skyward direction. Buoyant forces act toward the up side and against the down side. Because of this, any gas diffused into the blood will move to a higher concentration in the up side of the chamber 1 and in a lower concentration on the down side of the chamber 1. To account for this, pores 22 on the downward side of a hollow diffuser 2 may be larger to permit a larger amount of gas to be diffused. A gradient of pore 22 sizes (smaller at the top of the diffuser 2 and larger at the bottom) may be imposed on the surface of the diffuser 2. In a solid diffuser 2 or if a plurality of diffusers 2 are used, a plurality of pressure regulators 5 may be used to impart different pressures of diffused gas to different positions on the diffuser 2 or diffusers 2 to counteract buoyancy and impose equal diffusion radially in the chamber 1.

[0045] Keeping in mind the lack of general harm in over-diffusing ozone or other beneficial gas, it is equally permitted to regulate the pressure of the ozone or other gas to be diffused to provide sufficient diffusion to the blood in all parts of chamber 1. Hyperoxygenation may be accomplished sufficiently if the operator of the invention 100 supplies enough ozone or other therapeutic gas so as to hyperoxygenate the blood at the far downward side of the chamber 1. All other locations in the chamber 1 will receive a superabundance of the therapeutic gas, but not a harmful amount.

[0046] The length of chamber 1 is determined primarily by the need to impart sufficient heating uniformly to the blood. To some extent, the length of the chamber 1 is determined by the amount and rate of gas diffusion desired. In either case, the structure of the invention 100 is determined primarily by what is needed to kill pathogens or cancer cells while maintaining the health and/or normalcy of the remainder of blood components. For example, it may be effective to kill a certain virus by raising its temperature to 105 degrees F., maintaining that temperature (or lowering it) and then raising the temperature to 106 degrees F. In another embodiment, it may be optimal to kill pathogens by subjecting them to an alternating application of heat, then ozone, then heat, then ozone. These examples are not limiting. In alternate embodiments, any combination of heat or ozone, together or serially, at different temperatures, pressures or types of gas may be imposed within the invention 100.

[0047] Referring to FIG. 1 and FIG. 2, the treated blood exits the chamber 1 through an outlet placed at the opposite end of chamber 1 from connecting tube 10. The outlet is identified in FIG. 1 as connecting tube 11. A variable speed pump 8, which must not harm any blood components, may be used to regulate flow at, the outlet. The blood may then be returned to the patient via a return tube connected to nipple 15 and back into the patient's body and internal circulatory system or stored for later return.

[0048] The approach to the use of the invention is: 1) to use a maximum ozone concentration and predetermined temperature to kill harmful cells or viruses, while improving the rheology and biochemical characteristics of blood components, causing minimal damage to them, and 2) to minimize blood cell damage during ozone saturation and hyperthermia treatment. Further, the procedure is designed to expose autologous blood to ozone and high temperatures sufficient to kill or weaken disease-causing viruses, cells or pathogens, but not so high that it damages or kills blood components (106.7 degrees F. is generally agreed to be the maximum temperature to which human blood cells can be exposed), followed by reinfusion in patients affected by diseases or cancer. The hyperoxygenation and hyperthermia of the blood returned to the body produces additional therapeutic results in vivo.

[0049] In the preferred embodiment, the electrical heating system for the heating element 3 consists of a basic AC/DC power supply unit attached to the ends of a heating element 3 on or in the diffuser 2 in a helical fashion so as to distribute the heating uniformly over the surface of the diffuser 2. As described above, in other embodiments the heating element 3 may take any shape suitable to fit within the chamber 1 that does not disrupt the flow of blood and which can heat in a radially symmetric pattern.

[0050] In addition to the alternative heating elements 3 described above and now referring to FIG. 5, heating of the blood may also be accomplished by the use of heated water piped into a reservoir 50 disposed in the diffuser 2. Hot water is pumped into the reservoir 50 through a supply line 51. Similarly, a coiled tube of water (not depicted) in the manner of a radiator may be placed within the diffuser 2. The supply line 51 further comprises an integrated water return line 52. This permits the hot water to be continuously replenished. The water supply is pumped by a standard pump 53.

[0051] In the preferred embodiment, and referring to FIG. 1, the power cable 12 supplying current to the heating, element 3 enters the diffuser 2 ellipsoid from the power supply 6 and regulator 7 through the support tube 9 penetrating the wall of the chamber 1, and is attached to the heating element 3 in the interior surface of the diffuser 2 ellipsoid in a helical fashion so as to distribute heating uniformly over the surface of the diffuser 2.

[0052] Still referring to FIG. 1, each support tube 9 is of sufficiently small diameter and geometry as to prevent the creation of turbulence or other non-linear flow characteristics. Generally, support tube 9 is a long, thin circular cylinder. In some applications of the invention 100, however, the flow of blood through chamber 1 may be fast enough that a circular cylinder of any sufficient size to support the diffuser 2 may still cause turbulence or other non-linear flow characteristic. In that case, an elliptical cylindrical design for the support tube 9 may be used. In that case, the long axis of the elliptical cylindrical support tube 9 is oriented to lie parallel to the direction of blood flow, thus reducing turbulence or non-linear flow.

[0053] Heating within the chamber 1 is controlled and regulated by a current regulator 7 to achieve a blood temperature of at least 105 degrees F., and maintained within, the temperature range of 105 degrees to a maximum of 106.7 degrees F. within the chamber 1. One or more thermometers, of a design and with operational capabilities known in the industry, may be incorporated into the body of the chamber 1 along, its length to measure the temperature of the blood in the invention at various locations.

[0054] Having heated the blood to a controlled temperature of at least 105 degrees F., the blood is simultaneously oxygenated with a high concentration of ozone (O.sub.3) to a specified level of concentration regulated by a regulator 5. The ozone is infused into the blood through the plurality of pores 22 on the surface of the diffuser 2 by pressure differential created within the interior of the diffuser 2, and dispersed via pressure through the plurality of pores 22.

[0055] Blood is returned to the patient's circulatory system oxygenated and heated. In an alternate embodiment, the blood is cooled to body temperature prior to return to the patient.

[0056] In an alternate embodiment, the invention 100 may be an effective means of delivering other cancer fighting agents to the patient in addition to or other than ozone and oxygen by changing the ozone supply to an optional cancer fighting agent supply system.

[0057] In an alternate embodiment, the invention 100 may be used to treat illnesses and conditions in non-human animals, with temperatures and oxygen saturation levels scaled to allow for the needs of the individual animal so treated.

[0058] The invention 100 can be made in different sizes and dimensions to whatever scale (large or small) is necessary to accomplish its intended function and purpose. In an alternate embodiment, the invention may be used to sterilize stored blood. Sterilization of blood supplies may require a larger scale device than one used for individual human or animal treatments. Consequently, the design of the device enables homogeneous heating and oxygen/ozone mixing with the possibility of fabricating the device at variable dimensions and scales.

[0059] The invention 100 as described is portable. As such, it is usable away from hospital environments and treatment centers, and so may have tremendous use and application in the home care industries, ambulances as well as military battlefield environments. It is especially useful for transportation to and use at blood storage facilities.