ES2834308T3 - LED therapy bed - Google Patents

Abstract

LED therapy bed (19) comprising: a plurality of separately controlled LED modules (40); each module having a plurality of LEDs regulated by a current limiting circuit; the bed being characterized in that the plurality of LEDs is adapted to be supercharged in order to increase the light output beyond normal operating intensity and to further produce thermal heat from said plurality of LEDs; wherein each module further includes at least one thermal sensor (85) that is adapted to detect a local temperature of said module; and wherein each module further includes at least one fan (51), the fan speed being regulated directly or indirectly by the at least one thermal sensor; and a master controller that is adapted to control each LED module, the at least one thermal sensor, and the at least one fan; wherein the temperature of at least more than one of the modules or LEDs is controlled separately.

Description

DESCRIPTION

LED therapy bed

Background of the invention

Field of the invention

The present invention relates to improvements in a light emission (LED) therapy bed. More particularly, the LED therapy bed provides a dermal therapy bed that can bring benefits to the health of a person by raising and maintaining the therapy temperature of a person lying in bed as a non-monochromatic light source, non-coherent and biostimulant.

The present invention also relates to improvements in medical devices for the treatment with topical photodynamic therapy (POT) of patients and, in particular, to a rigid surface (circuit board) that contains LEDs as a non-monochromatic light source, non-coherent and biostimulant, which are placed in contact or in close proximity to the skin or tissue of the patient and to a procedure for the manufacture of that apparatus. Description of Related Art

Non-monochromatic light at defined wavelengths has produced beneficial biostimulant effects and is known to trigger specific biological functions, such as increased metabolic rate, photorepair, and cell division. However, the stimulation has occurred with light emitted at specific wavelengths.

Although the exact mechanism by which the beneficial biostimulant effects have been achieved is not precisely known, several theories have been proposed. It has been suggested that non-monochromatic light emitted in the range of about 415nm to about 940nm penetrates body tissue and is absorbed, reflected, and scattered to excite molecules within cells and tissue to thereby accelerate repair and regeneration. However, light in the range from about 415 nm to about 465 nm is known to exhibit a bactericidal effect, thus alleviating the onset of bacteria-induced acne.

Another theory suggests that different cells have different photoreceptors, which respond only to certain wavelengths of light. This theory supports the phenomenon that the application of only certain wavelengths of light leads to biostimulant effects and consequent stimulation of the dermis and increased collagen and elastin production. Compared to similar technology, but without LEDs, light therapy has used relatively low power lasers and biostimulant laser treatment has been called "soft" laser therapy. In such applications, low-level laser energy radiation has been used with success to promote wound healing and the treatment of musculoskeletal disorders and skin ulcers.

It had previously been theorized that the properties of laser radiation, which led to the beneficial biostimulant effects of mild laser therapy, were the monochromaticity and coherence of the laser radiation.

In a previous invention, the applicant observed that if the biostimulant effects of light were combined by combining in a single device four different wavelengths of light, each with known benefits, the effects could be greater than if each wavelength was applied separately, and that the proximity of the LEDs to the user favored uniform coverage of the target area, in order to receive all wavelengths simultaneously and achieve a more efficient penetration of light.

Therapy beds have taken on various forms and functions over the years. Some of the early therapy beds claimed to provide health benefits from the sun, while later versions primarily provided tanning effects to the user's skin.

Various patents and / or publications address these issues. Examples of patents and / or publications that attempt to address these problem (s) are identified and set forth below.

US Patent No. 6,896,693 discloses a "phototherapy device." The patent's phototherapy device operates at a distance of up to several feet from the user.

US Patent No. 8,425,577 discloses an "LED phototherapy apparatus". This patent uses red and near infrared light to provide phototherapy. This patent also uses an acrylic holder that separates the LEDs from the user and further distances the LEDs from the user with a top cover that is distanced from the user. US Patent Publication No. 2009/0222070 discloses a "Whole Body LED Phototherapy System Capsule".

Furthermore, US 20140202715 discloses an LED tanning bed in which the LED modules are regulated by current limiting circuits.

Known LED beds appear to be based on adapted tanning beds. This design raises several problems including:

1) . Tanning beds that have a shell-shaped design and an upper portion that may be too far from the body for the light emitted by the ^l E ^{d to} effectively penetrate a user's body and distribute therapeutic energy. The lower portion of a custom tanning bed can present the same proximity problem, as the LEDs may be too far from the body for optimal effectiveness.

2) . An acrylic tanning bed cover can distort the preset angle the LEDs emit and can also reduce the power output.

3) . With an LED bed adapted from a tanning bed, it may be impractical or impossible to simultaneously raise the temperature of all parts of the human body, since the torso would become hotter and reach more heat than the legs or arms , and in some cases even the legs would heat up faster and reach more heat than the arms.

4) . With a gap of several inches, that is, typically more than about fifty millimeters, between the LEDs and the user, it can be difficult, impractical, or even impossible to obtain the necessary temperature to lift the skin to achieve dilation of the same and provide a better penetration of phototherapy. In such an application, the benefits provided by the LEDs may be limited by the bracket and the distance between the user and the LEDs.

Summary of the invention

An LED therapy bed is provided comprising:

a plurality of separately controlled LED modules, each module comprising a plurality of LEDs regulated by a current limiting circuit;

wherein the plurality of LEDs is supercharged in order to increase the light output beyond normal operating intensity and to further produce thermal heat from said plurality of LEDs;

wherein each module further includes at least one thermal sensor that detects a local temperature of said module; Y

wherein each module further includes at least one fan, the fan speed being regulated directly or indirectly by the at least one thermal sensor; Y

a master controller that controls each LED module, the at least one thermal sensor, and the at least one fan;

in which the temperature of each module or LED is controlled separately.

The LED therapy bed may comprise a support frame having a plurality of rails that form a curved support.

The plurality of rails can support the plurality of separately controlled LED modules.

Exemplary embodiments provide a custom designed bottom portion that presents the LEDs practically against an acrylic or other cover, such that the LEDs are only 6.4-12.7 mm (1/4 -1/2 inches) approximately from the user's body, where a user would treat one side of their body and then turn around and treat the other side of their body. Alternatively, both sides of a user's body can be treated at the same time by having another bed positioned above the user that can be lowered into contact or near contact with the user. This arrangement solves the problem of the LEDs being too far from the patient.

The LED modules can be controlled individually or in groups so that one part of the user is not too hot or too cold compared to other parts of the user's body. To obtain FDA clearance, it is necessary to simultaneously raise the temperature of all parts of the human body, for example, the torso, legs, arms, neck, etc. Additionally, these modules can maintain temperature independent of normal variations in ambient or other conditions, such as ambient temperature. Such an arrangement solves the problem of having a different temperature in different parts of the body of a user, where, for example, the arms or legs of a user may be at a different temperature than the torso of the user, and the problem of different environmental or other conditions that cause different body temperatures.

Thermal heat from said plurality of LEDs can be arranged to produce a user's skin temperature of between 36 ° C and 42 ° C (97 ° F and 108 ° F).

The LED therapy bed may comprise an acrylic polymer cover over the LEDs, and preferably the acrylic polymer is a clear acrylic polymer. The acrylic polymer does not distort, or minimize the angle distortion of the energy of the LED being emitted and allows almost all of the energy to pass to the user for a therapeutic effect. This solves the problem associated with distortion of the energy angle of the LED being emitted. A transparent or ultra-transparent acrylic polymer can be used.

The LEDs of an LED module can be arranged in a matrix. The LED modules can also be arranged in a matrix.

The LEDs in an LED module can be contained on a printed circuit board (PCB).

Each of the separately controlled LED modules can incorporate electrical connections for between 100 and 1,000 LEDs in each module.

The plurality of LEDs, eg an array of LEDs, can have different wavelengths that emit light of different colors and is arranged in a repeating pattern, eg an array. Alternatively, a three-color RGB LED can be controlled to produce the desired wavelengths across individual or multiple LEDs within an array.

LEDs can transmit light in wavelengths of at least one of 605nm, 630nm, 660nm, 850nm to 855nm, and 940nm. These wavelengths, alone or in combination, can cause at least one of: increased nitric oxide level of a user of the LED therapy bed, reduction or elimination of wrinkles and tightening of the user's skin, relief of stiffness and / or muscle, arthritic or joint or carpal tunnel pain, blood circulation, psoriasis, eczema, postoperative to minimize scarring, bruising, healing time, pain, inflammation and redness, scarring of mouth sores caused by chemotherapy, reversal of blindness caused by diabetes, reversal of macular degeneration, reversal of loss of vision caused by stroke, treatment of skin cancer, reduction or removal of bruises, to clear the sinuses, restore growth of the hair and fibromyalgia treatment.

The current limiting circuit can be configured to increase the heating of at least one wavelength of the LEDs to heat said skin tissue temperature between 36 ° C and 42 ° C (97 ° F and 108 ° F) when held in shape continues against, or in close proximity to, skin tissue for a predetermined period of time.

The thermal sensor can be located between the LEDs on a spring arm that is driven by a spring.

The master controller controls the supplied voltage (and thus the current produced within each LED given its internal resistance) to the LEDs in each array within each LED module, or otherwise generally controls a complete array of LEDs in a module.

The master controller can control each LED module separately. Alternatively, the master controller can control some of the LED modules separately or individually and control other LED modules together or as a group.

The plurality of LEDs can be arranged in a repeating pattern, for example, in an array.

The LED therapy bed may further comprise: an acrylic polymer cover over the LEDs, in which the plurality of LEDs have the same wavelength or different wavelengths and in which the master controller controls the LEDs.

The current limiting circuit can be selected to cause a deliberate increase in thermal heating of at least one wavelength of the LEDs to heat said skin tissue temperature between 36 ° C and 42 ° C (97 ° F and 108 ° F) when is continuously held against, or in close proximity to, skin tissue for a predetermined period of time.

The thermal sensor can be located between the LEDs on a spring arm, the spring arm preferably being spring-loaded. While thermal sensors can be placed near, or on a surface of, the LEDs closest to the acrylic polymer cover, other forms of detector can replace or augment the temperature sensing function performed by thermal sensors. For example, the pressure sensors can be under or incorporated within or on the acrylic polymer cover, with feedback from localized pressure readings providing an additional mechanism by which the controller can control the supply of power to individual LEDs or groups of them. For example, depending on the pressure detected, the LEDs may overcharge to a greater or lesser extent; This saves energy when the absence of pressure reveals the lack of contact. Additionally, by developing a recorded pressure profile based on weight distribution across the entire surface of the therapy bed, the master controller can vary the energy output of the ^l E ^{d accordingly} . Furthermore, this arrangement makes it possible to avoid areas of the bed that are relatively hot and where there is no heat loss due to lack of body contact on a supporting surface of the acrylic polymer cover.

The acrylic polymer layer or cover can have a variable thickness along its surface, the different thicknesses presenting a form of attenuation of the thermal power in localized regions; this allows clusters of LEDs to generally supercharge, with the thermal properties of the acrylic polymer shell moderating localized heating. Such an arrangement eliminates the need for a master controller by reducing the controller to an on / off switch function. Control of LEDs and therefore thermal control can be achieved by POT pulse width "PWM" modulation of a control waveform applied to a drive voltage. The generation of a representative signal that reflects the localized temperature can provide a feedback loop that controls the actuation time, or applied boost voltage / current level, of each LED or group of LEDs.

Therefore, the heating effects produced through the acrylic polymer shell can be substantially homogeneous across all modules or else variations in localized heating can be practiced to address different skin qualities on different parts of a body. (or region of a body).

The LED therapy bed comprising a plurality of separately controlled LED modules or a plurality of separately controlled LED modules may comprise a system for light therapy using non-coherent light generated by an array of light-emitting diodes. Conventional LEDs that are confined within a bandwidth of 415nm to 940nm. The diode array is configured in a structure to direct light onto a diffuse area of the user without using an optical system or any intermediate material other than the acrylic polymer layer. The LEDs rest directly on the user, or in close proximity to the user, through the use of the acrylic polymer layer or similar layer.

The LED therapy bed comprising a plurality of separately controlled LED modules or a plurality of separately controlled LED modules alone can supercharge the LEDs to create heat which is conducted to the skin of the user in order to provide heat in addition to light therapy. In some embodiments, a single dimmer, current limiter, or single resistor is used to consistently limit current to all LEDs and provide both uniform lighting and heat.

The LED therapy bed comprising a plurality of separately controlled LED modules or a plurality of separately controlled LED modules alone can provide a light therapy system of the general character described, which produces beneficial biostimulating effects.

The LED therapy bed comprising a plurality of separately controlled LED modules or a plurality of separately controlled LED modules alone can provide a light therapy method of the general character described whereby non-coherent and non-coherent light is employed. Monochromatic within a wavelength range of 415 nm to 940 nm for photobiostimulation.

The LED therapy bed comprising a plurality of separately controlled LED modules or a plurality of separately controlled LED modules alone makes it possible to provide a light therapy procedure of the general character described that uses non-coherent and non-monochromatic light emanating of the LEDs.

The LED therapy bed comprising a plurality of separately controlled LED modules or a plurality of separately controlled LED modules alone may include multiple LED bank modules where each bank includes an individual thermal control of the module to maintain temperature optimal dilation of the skin. Each module can include 608 LEDs arranged in 19 rows by 32 columns. More or fewer columns and / or rows can be provided, including patterns other than columns and / or rows, such as circular shape, V shape, diagonal shape, etc.

The LED therapy bed comprising a plurality of separately controlled LED modules or a plurality of separately controlled LED modules alone may have an open top surface that does not cover a person. The bed only includes LEDs below the user where the distance between the LEDs and the user can be maintained. Each bed can have module banks arranged in three rows by six columns.

In a further embodiment, one or more fans can be used to cool individual modules in order to regulate the temperature transmitted to the acrylic cover. These cooling fans can drive a circulating air stream within a plenum below the LED array, the plenum being part of the structural compartment that constitutes each module or one or more sections of the therapy bed, with each section containing one or more more modules. Again, instead of regulating a supply current for each LED or each matrix, a temperature sensor can be used that is located within each plenum and located near each matrix (and preferably near a transfer surface. matrix LEDs) to provide an indication of temperature to a thermal transfer interface. In response to the sensed temperature, the master controller can regulate the fan speed to regulate the temperature created on the surface of the LED matrix, with the master controller arranged to run a control algorithm that varies the temperature profile over time. Of course, in some embodiments it is considered that a temperature delivered to the thermal interface between a body undergoing therapy and the acrylic polymer covering (or layer) can be substantially constant over a selected period of time that varies, for example, between tens seconds and several minutes.

Additionally, or alternatively, cooling fans can be placed on the surface of the acrylic polymer cover to blow regulator air over the surface, with surface mount temperature sensors providing feedback for fan and / or control control. LED power control. The modules may further include a perforated surface so that cooling air circulates with the plenum from the fan and exits through perforations to produce localized cooling of the skin in contact with the surface of the acrylic polymer. The operation of the ventilator in this embodiment can be continuous or scheduled for selected periods controlled by the master control (to reflect a program of heat and light delivery of the entire therapy bed or isolated and selected parts of each of the modules or arrays .

The benefits of LEDs can be logarithmically proportional to the distance between the LED and the user. Various objects, features, aspects, and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the invention, in conjunction with the accompanying drawings in which like numbers represent like components.

The LED therapy bed may comprise a support frame having a plurality of rails that form a curved support.

The plurality of rails can support the plurality of separately controlled LED modules.

Thermal heat from said plurality of LEDs can be arranged to produce a user's skin temperature of between 36 ° C and 42 ° C (97 ° F and 108 ° F).

The LED therapy bed can support the body of a user lying on the LED therapy bed, but does not cover the user while lying on the LED therapy bed.

After one side of the user has been treated by the modules, the user can turn over to treat the opposite side of the user's body.

At least one of the following may be caused by using the LED therapy bed: increased nitric oxide level of a user; reduction or elimination of wrinkles and tightening of the skin of a user; relief of muscle, arthritic or joint or carpal tunnel stiffness and / or pain, blood circulation, psoriasis, eczema; postoperative to minimize scars, bruises, healing time, pain, inflammation and redness; scarring of mouth sores caused by chemotherapy; reversal of blindness caused by diabetes; regression of macular degeneration; reversal of vision loss caused by stroke; skin cancer treatment; reduction or elimination of bruises; sinus cleansing; hair growth restoration and fibromyalgia treatment.

The therapy bed comprises a support frame having a plurality of rails, the plurality of rails forming a curved support, wherein the plurality of rails supports a plurality of separately controlled LED modules.

In one embodiment, an LED therapy bed includes a support frame having a plurality of rails. The plurality of rails forms a curved support. The rails support a plurality of separately controlled LED modules, where each module comprises a plurality of LEDs regulated by a current limiting circuit. Said plurality of LEDs are supercharged to increase the light output beyond normal operating intensity and to further produce thermal heat from said plurality of LEDs in order to produce a user's skin temperature of between 36 ° C and 42 ° C (97 ° F and 108 ° F) by direct thermal conduction, the temperature measured at or near a surface of the acrylic polymer. Each module also includes at least one thermal sensor that detects the local temperature of said module; and each module further includes at least one fan in which said fan speed is regulated directly or indirectly by said at least one temperature sensor. A master controller that controls each of said module LEDs, the thermal sensor and the at least one fan, in which the temperature of each module can be controlled separately.

In a further embodiment, an LED therapy bed includes a support frame having a plurality of rails that form a curved support. The rails support a plurality of LED modules. Each module comprises a plurality of LEDs regulated by one or more current limiting circuits. The plurality of LEDs of different colors are supercharged to increase the light output beyond the operating intensity normal and to further produce thermal heat from said plurality of LEDs to produce a wearer's skin temperature of between 36 ° C and 42 ° C (97 ° F and 108 ° F) by direct thermal conduction. Each LED module also includes at least one thermal sensor that detects the local temperature of said module. Examples of known acrylic are clear or ultra clear acrylic. However, other acrylics can also be used. The cover is located over the top of the LEDs and separates the LEDs from the user. Each module further includes at least one fan in which said fan speed is regulated directly or indirectly by said at least one temperature sensor. A master controller controls the LEDs, the at least one fan, and the at least one thermal sensor in each module, where the temperature of each module can be controlled separately.

Advantageously, the embodiments provide a phototherapy device that provides a regulated temperature of the skin so that all areas of the body can reach a therapeutic temperature level simultaneously and be maintained at that temperature. Furthermore, the structural arrangement of the devices of at least some of the preferred embodiments achieves regulated and localized acoustics regardless of non-optimal environmental conditions, such as room temperature, while at the same time providing dermal phototherapy very close to the sources. of light.

Brief description of the drawings

FIGURE 1 shows a perspective view of an LED therapy bed;

FIGURE 2 shows a cross-sectional perspective view of the LED therapy bed, taken along lines 2-2 of FIGURE 1;

FIGURE 3 shows a cross-sectional perspective view of the LED therapy bed, taken along 3-3 of FIGURE 1;

FIGURE 4 shows a perspective view of a single LED module;

FIGURE 5 shows a perspective sectional view of the single LED module, taken along line 5-5 of FIGURE 4;

FIGURE 6 shows a detailed view of the LED module, according to detail 6, identified in FIGURE 2; FIGURE 7 shows a detailed view of the LED module, according to detail 7, identified in FIGURE 3; FIGURE 8 shows a block diagram of the LED therapy bed according to the invention;

FIGURE 9 shows the thermal sensor of the thermistor of FIGURE 9 in greater detail; Y

FIGURE 10 shows the thermistor thermal sensor of FIGURE 9 placed in an LED module.

Detailed description of the invention

In order to further an understanding of the principles of the invention, reference will now be made to exemplary embodiments illustrated in the drawings and specific language will be used to describe the same. However, it will be understood that it is not intended to limit the scope of the invention. Any further alteration and modification of the principles of the invention as described herein is contemplated and would normally occur to one of ordinary skill in the art to which the invention relates. The invention is defined in the claims; other embodiments, aspects, and procedures are provided for illustrative purposes only and do not constitute parts of the invention.

FIGURE 1 shows a perspective view of an LED therapy bed 19, according to an exemplary embodiment. The LED therapy bed 19 is configured with an open top structure. A plurality of legs 23 suspend a frame structure above the ground. The frame structure has front and rear frame elements 22 and 25 and with elongated side elements 24 between them. As shown in FIGURE 1, the bed comprises a plurality of modules 40, as described in more detail below. At one or both ends of the therapy bed 19 is a headrest / face support 20 having inner side supports 21. Component 20 acts as a headrest when a user is lying on their back on the LED therapy bed and acts as a support. facial when a user is lying face down on the LED therapy bed 19. A space between the inner side supports 21 serves to receive the face of a user who is lying face down on the LED therapy bed 19. As shown additionally shows in FIGURE 1, an acrylic cover 49 rests on the LED therapy bed 19 and is located between the user and the LED modules 40. The acrylic cover or layer 49 is designed to reduce the temperature between the lower part of the cover, which rests on the LEDs and the frame of the modules and the temperature of the upper part of the cover, which receives the user's body. The temperature of the upper part of the acrylic cover 49 that receives the user's body is between 36 ° C and 42 ° C (97 ° F and 108 ° F), depending on the therapy to be provided. Although an acrylic cover is disclosed, other suitable materials can be used for a transparent or near-transparent acrylic cover resting on the LEDs in the LED modules. In the illustrated exemplary embodiment, the weight of the user exerts downward pressure on the acrylic layer 49 such that the LEDs contact the body through the acrylic layer.

FIGURE 2 shows a perspective view taken along lines 2-2 of FIGURE 1. The longitudinally extending frame members extend from one end of therapy bed 19 to an opposite end. The frame elements comprise an upper part having an inverted "V" shape.

Connected to the bottom of each inverted frame member is a horizontally extending member 31. Two horizontally extending members in the central portion are of the same height. The two elongated frame members on either side of the two centrally located horizontally extending members are labeled 27 and are higher in height than the centrally located horizontally extending members, which are labeled 31. Therefore Therefore, both horizontally extending elements 31 are of the same height and both elongated frame elements 27 are of the same height. Outside of the horizontally extending elements, there are outer elements that are hollow and are labeled 33. Above the outer tubular elements 33 are hollow upper portions 34. Extending transversely between the frame elements are frame supports 28, extending transversely below the center of each LED module 40. Although a specific frame structure has been described, it can be substituted for other frame structures. One or both ends of the LED therapy bed 19 comprises a headrest or facial support 20 with inner side supports 21 that support a person who is lying on the LED therapy bed 19 on their back or on their back, in order to of allowing the person using the LED therapy bed 19 to receive the therapeutic benefits on the front, back or sides of the user. The user's sides are treated by a user lying on one side and then, if necessary, on the other side. A plurality of removable and replaceable LED modules 40 are positioned in the frame of the LED therapy bed 19. The clear acrylic cover 49 provides a slight separation between the user and the LEDs. The clear acrylic cover 49 distributes the weight of the user over the frame structure of the plurality of removable and replaceable LED modules 40. The clear acrylic cover 49 is preferably formed of a transparent material, such as acrylic or polycarbonate, but other materials that provide equivalent or superior transparency or structural strength may be used.

As can be further seen in FIGURE 2, the elongated side members 24 and 26 are above the legs 23. Between the elongated side members 24 and 26, the elongated frame members 27 and 31 support the LED modules. 40 in a curved configuration that centers the user in the center of the LED therapy bed 19. The headrest or face support 20 supports the back of a user's head and can support a user's face and provides clearance for the user to breathe through the nose or mouth. A bracket 29 connects one end of the LED therapy bed 19 and the headrest or facial support 20. Although a headrest or facial support 20 has been shown, the headrest or facial support 20 can be located at either end of the therapy bed. . In an exemplary embodiment, the LED therapy bed 19 has thirty LED modules 40 configured in five columns and six rows, but LED therapy beds can be provided with more or fewer modules and a different number of columns and rows. of modules. Each LED module 40 is essentially the same, but can be a different shape or size, and each LED module 40 can be removed, replaced, or exchanged. Each LED module 40 is self-contained and can function independently and or in conjunction with any or all of the other LED modules 40. The LED modules 40 are shown and described in more detail in other figures herein.

FIGURE 3 shows a perspective view of FIGURE 1, taken along line 3-3. A rectangular connector 30 is provided. This connector 30 fits into cut-out portions 45 (see FIGURE 4) at the corners of each LED module 40. The corners of four modules form a rectangle that receives the rectangular connector 30 to hold the modules. of LED 40 instead. In an exemplary embodiment, the top of the connector 30 is below the top of the LEDs.

FIGURE 4 shows a perspective view of a single LED module 40. In an exemplary embodiment, each LED module 40 has an LED structure configured in 19 by 32 columns for a total of 608 LEDs, but can be provided other embodiments of rows and columns of LEDs, rather than the particular configuration shown. LEDs provide non-coherent light generated by an array of conventional light-emitting diodes (LEDs) that are confined within a bandwidth of about 415 nm to about 940 nm. The LED matrix is configured in a structure to direct the light towards a diffuse area of the user, through the acrylic layer, without using an optical system, etc. The light is emitted at a preset angle to provide the user with the most effective treatment. The housing 41 supports the internal electronics and a circuit board 46 (see FIGURE 5) that supports the LEDs 44. Each individual LED module 40 44 can be attached to the housing 41 with latches 43. Furthermore, in an embodiment by way of For example, one or more of the separately controlled LED modules 40 may incorporate electrical connections for between about 100 and about 1,000 ^l E ^d 44

Each LED module 40 is autonomous and independently regulates its temperature in order to maintain an optimum temperature for skin expansion. A current limiting device connects to the LEDs. In an exemplary embodiment, the current limiting resistor is selected to provide a deliberate increase in said skin tissue temperature of a user where the skin temperature is between 36 ° C and 42 ° C (97 ° F). and 108 ° F), when continuously held against or in very close proximity to the skin tissue of a user for a period of fifteen minutes. Each LED module 40 features openings or holes 42 for air ventilation from within the LED module 40. The holes 42 allow cooling or heating air to move independently through each LED module 40 to regulate independently the temperature of each LED module 40. As shown in FIGURE 4, the portion The top of the LED module 40 protrudes from the housing 41 so that the air from the holes 42 exits each LED module 40. In addition, each module comprises one or more fans 51 to move the air within the module, in order to controlling the temperature of the air below the acrylic cover 49, which results in controlling the temperature of the upper part of the acrylic cover, which is in contact with the user's body. Individual control of the air temperature above and below the acrylic cover is important since different parts of a user's body emit more heat than other parts. For example, the legs of a user emit more heat than the trunk of the user; while the user's arms can emit more heat than the user's legs, etc. Alternatively, the LED therapy bed 19 can be formed from two modules. In addition, a second set of modules can be lowered or otherwise positioned on the other side of the user to treat both sides of the user at the same time. Furthermore, the upper and lower bed or beds can be oriented vertically or at an angle to the vertical or horizontal.

FIGURE 5 shows a perspective sectional view of the single LED module 40 of FIGURE 4, taken along line 5-5 of FIGURE 4. Each module 40 may incorporate a heating component (not shown) that allows preheating each module independently in order to reduce the time required to obtain the desired therapy temperature for a particular user. A thermistor, other heat sensor, or temperature sensor 85 is located on top of each LED module 40 to determine the temperature of each LED module 40. The thermistor, another heat sensor, or temperature sensor 85 sits on top of a frame and rests on legs 82. An illustration of the thermistor or other heat or temperature sensor can be found in FIGURES 9 and 10.

A controller is located within each LED module 40 or in a separate master location. The controller measures the temperatures through sensors 85 and drives the fan 51 which is connected to a motor 52 which is located in the compartment 50 at the bottom of the LED module 40. The fan 51 comprises blades and the fan speed changes. to maintain the temperature of the surface of the LEDs 44 at the bottom of the acrylic cover 49. The fan cage 50 is held in place by screws 53, or is otherwise secured to the housing 41 of the LED module 40 Regulation of fan speed and cooling is necessary since LEDs 44 are supercharged to create heat that is conducted to the wearer's skin in order to provide heat in addition to light therapy.

In some exemplary embodiments, power is applied to the bank of LEDs through an LED driver. The LED driver can come in various forms, from a simple resistor to a transistor, SCR, current driver, Diac, Triac, or other solid state device. Power is supplied to an LED module or to each LED 44 at the desired power or current, as controlled by the controller. The current limiting or regulating device is used to consistently limit the current to the LEDs and provide uniform lighting and the specific temperatures required. Because LEDs are often powered beyond their normal illumination level, LEDs produce excessive heat. Excess heat exits each LED module 40 through holes 42, as a result of airflow created by fan 51.

Different wavelengths of light and combinations of wavelengths of light have been shown to provide various treatments, including, but not limited to:

1. Anti-wrinkle / anti-aging treatment and to reduce pore size: about 605nm, about 630nm, about 660nm, and about 850nm to about 855nm.

2. Relief of pain, including arthritic and carpal tunnel pain: about 630 nm, about 660 nm, about 850 nm to about 855 nm, and about 940 nm.

3. Acne treatment and burn cure: about 415 nm or about 460 nm to about 465 nm, about 660 nm and about 850 nm to about 855 nm.

4. Rosacea: about 415 nm or about 460 nm to about 465 nm, about 630 nm, about 660 nm, and about 850 nm to about 855 nm.

5. MRSA: about 415 nm or about 460 nm to about 465 nm, and about 850 nm to about 855 nm.

6. Treatment of swelling and inflammation of the brain caused by severe head injury: about 850 nm to about 855 nm.

7. Psoriasis Eczema (used with serum): about 630 nm, about 660 nm, about 850 nm to about 855 nm, and about 940 nm.

8. Postoperative to reduce scars, bruises, healing time, pain, inflammation and redness: approximately 630 nm, approximately 660 nm, approximately 850 nm to approximately 855 nm and approximately 940 nm.

9. Reversal of blindness caused by diabetes: approximately 630 nm, approximately 660 nm, approximately 850 nm to approximately 855 nm, and approximately 940 nm.

10. Receding macular degeneration: about 630 nm, about 660 nm, about 850 nm to about 855 nm, and about 940 nm.

11. Cure of mouth sores caused by chemotherapy: about 630nm, about 660nm nm, about 850 nm to about 855 nm and about 940 nm.

12. Skin cancer: about 630 nm, about 660 nm, about 850 nm to about 855 nm, and about 940 nm.

13. Bruising: approximately 630 nm, approximately 660 nm, approximately 850 nm to approximately 855 nm, and approximately 940 nm.

14. Sinuses: approximately 630 nm, approximately 660 nm, approximately 850 nm to approximately 855 nm, and approximately 940 nm.

15. Bell's palsy: about 630 nm, about 660 nm, about 850 nm to about 855 nm, about 940 nm, about 605 nm, about 630 nm, about 660 nm, and about 850 nm to about 855 nm.

16. Chest healing after open heart surgery: around 850 nm to 855 nm.

17. Helps regeneration of hair growth: about 630nm, about 660nm, about 850nm to about 855nm, and about 940nm.

18. Fibromyalgia: about 630 nm, about 660 nm, about 850 nm to about 855 nm, about 940 nm, about 605 nm, about 630 nm, about 660 nm, and about 850 nm to about 855 nm.

19. Increased nitric oxide production: about 630 nm, about 660 nm, about 850 nm to about 855 nm, and about 940 nm.

20. Increased blood circulation: about 630 nm, about 660 nm, about 850 nm to about 855 nm, and about 940 nm.

21. Pigmentation and age spots: about 605 nm, about 630 nm, about 660 nm, and about 850 nm to about 855 nm.

The plurality of light can have a small variation between light frequencies, such as about 625 nm, about 630 nm, and about 635 nm, through the use of LEDs with different dispersions and intensities. These light frequencies, of about 625nm, about 630nm, and about 635nm, can be combined with a light frequency of about 415nm that kills bacteria to provide optimal benefit. Although specific wavelengths have been described above, the wavelengths can be modified, if desired. Furthermore, although the term "approximately" is used in the specification when specific wavelengths are indicated, the term "approximately" is used because manufacturing tolerances may differ and because a very similar but not exact wavelength may work as well. as well as the indicated wavelength.

FIGURE 6 shows a detailed view of LED module 40 from detail 6 identified in FIGURE 2. LED module 40 is shown installed and retained on top of side frame element 26. On top of element of side frame 26 there is a hollow upper part 34 (see FIGURE 2). As further shown in FIGURE 6, one side of the acrylic cover 49 rests on a rubber strip 47 and is held in place so that it is not displaced upward by the protrusion 48 of the hollow top 34 of the side frame element 26. These sections show the fan compartment 50 that provides airflow to maintain the temperature of the LED module 40, and in particular, to control the temperature of the air at the bottom and top of the LEDs that are below the acrylic cover 49. Beneath the rails 28 is a mesh fabric 35 which is made of metal or other suitable material, and which runs the length of the majority of the bottom of the LED therapy bed.

FIGURE 7 shows a detailed view of the LED module 40 from detail 7 identified in FIGURE 3. The headrest or face support 20 supports the back of a user's head and can support a user's face and provides space free for the user to breathe through the nose or mouth. A support 29 is connected between the frame element 26 of the LED therapy bed 19 and the headrest or face support 20. Although a frame supporting the modules is shown, this can be replaced by other different frames. Furthermore, although a plurality of modules 40 positioned below the user are shown, the modules 40 can also be positioned above the user. In addition, assemblies of modules 40 can be positioned both above and below the user, as well as arranged to cover the sides of the user. Furthermore, although the modules 40 are described as essentially horizontal, they may alternatively be positioned in a vertical orientation or at an angle to the vertical or horizontal axes.

FIGURE 8 shows a block diagram of the LED therapy bed 19. A controller 70 is attached by wires 71 to each of the LED modules 40. The connection from the controller 70 to the LED modules 40 may be a direct connection to each LED module 40 or can be connected in series or daisy chain. Controller 70 is the master controller and each LED module 40 is a slave unit to controller 70. The host controls the display and a keyboard or knobs that accept user input, and drives the display, indicators, devices generation generator, etc., and the slave unit (s). Each slave LED module 40 has its own controller that controls the LEDs, the fan, and monitors the temperature sensors.

FIGURES 9 and 10 show that the temperature sensor 85 is located at the end of a flexible arm 80 that rests or is secured to the circuit board of the LED frame through a support frame. Flexible arm 80 holds temperature sensor 85, which may be a thermistor, in conductive contact or nearly conductive with the underside of the clear acrylic cover 49 and accommodates some flex from the clear acrylic cover 49 that is supported on the frame containing the LEDs 44. It is also contemplated that a thermal imaging temperature sensor may be used that do not depend on conductive contact with the bottom of the transparent acrylic cover 49. At the bottom of the flexible arm 80 is a protrusion 83. This protrusion 83 can exert downward pressure on the top of the spring 81 when the arm is flexed down. Thermistor 85 or equivalent rests in a slot in the upper surface of flexible arm 80. A wire or wires 86 extend from thermistor 85 through flexible arm 80 and down to the printed circuit board (PCB) on which LEDs 44 are supported. Flexible arm 80 is supported on a frame 79 that rests on legs 82. The frame is located between LEDs 44 and the top of thermistor 85 is just below the top of LEDs 44. Although In this exemplary embodiment a temperature sensor is shown, multiple temperature sensors can be placed in the LED array at the bottom of the clear acrylic cover 49. Multiple temperature sensors 85 allow to reduce heat / cooling conduction from a part of the user's body placed over the transparent acrylic cover 49. In addition to the temperature sensors placed between the LEDs and under the transparent acrylic cover Before 49, additional temperature sensors can be located on the PCB and / or elsewhere within the LED module. The temperature sensors 85 communicate with the module, where a controller 70 is located in each module, or a central controller, which drives one or more cooling fans 51 to maintain the temperature of the module 40.

At least one temperature sensor 85 is kept nearly in contact with the bottom surface of the clear acrylic cover 49 by being positioned just below the top of the LEDs 44. As described above, each LED module 40 comprises six hundred eight LEDs, but more or less than the six hundred and eight LEDs can be provided. The number of wavelengths of the LEDs used is selected based on the desired therapy. In addition, LEDs can be manufactured with an internal group of LEDs and the transmission color of each individual LED 44 can be changed, depending on the therapy desired. In an exemplary embodiment, a plurality of LEDs of different colors may be arranged in a repeating pattern. The skin and other body tissues have the ability to absorb light and use it as an energy source to stimulate cell regeneration. The light rays emitted by the device are beneficial to the skin, as they do not contain UV rays. The problem with getting these same rays of light from the sun is that harmful UV rays are also received. These harmful rays can do more harm than good to the skin. With LEDs, when the correct wavelengths of light flow closely and intensely into the body, at the right temperatures, collagen and elastin are produced by cells called fibroblasts. Inside these cells is a smaller cellular structure called mitochondria.

Claims (12)

1. LED therapy bed (19) comprising: a plurality of separately controlled LED modules (40); each module having a plurality of LEDs regulated by a current limiting circuit; the bed being characterized in that the plurality of LEDs is adapted to be supercharged in order to increase the light output beyond normal operating intensity and to further produce thermal heat from said plurality of LEDs; wherein each module further includes at least one thermal sensor (85) that is adapted to detect a local temperature of said module; Y wherein each module further includes at least one fan (51), the fan speed being regulated directly or indirectly by the at least one thermal sensor; Y a master controller that is adapted to control each LED module, the at least one thermal sensor, and the at least one fan; wherein the temperature of at least more than one of the modules or LEDs is controlled separately. The LED therapy bed according to claim 1, further comprising a support frame having a plurality of rails, the plurality of rails forming a curved support, the plurality of rails supporting the plurality of modules of LEDs controlled separately. The LED therapy bed according to any preceding claim, further comprising an acrylic polymer that covers the LEDs. The LED therapy bed according to claim 3, wherein the acrylic is a transparent acrylic polymer. The LED therapy bed according to any preceding claim, wherein the LEDs of an LED module are contained on a printed circuit board (PCB). The LED therapy bed according to any preceding claim, wherein each of the separately controlled LED modules has electrical connections for between about 100 and about 1,000 LEDs in each module. The LED therapy bed according to any preceding claim, wherein the plurality of LEDs have different operating wavelengths in order to emit light of different colors and are arranged in a repeating pattern. The LED therapy bed according to any preceding claim, wherein the LEDs transmit light at wavelengths of at least one of: 605 nm, 630 nm, 660 nm, 850 to 855 nm and 940 nm. The LED therapy bed according to any preceding claim, wherein the thermal sensor is located between the LEDs on a spring arm that is spring-driven. The LED therapy bed according to any preceding claim, wherein the master controller controls the LEDs in each LED module. The LED therapy bed according to any preceding claim, wherein the master controller controls each LED module separately. The LED therapy bed according to any one of claims 1 to 11, wherein the master controller separately or individually controls some of the LED modules and controls other LED modules together or as a group.