WO2008144157A1 - Phototherapy light cap - Google Patents

Abstract

A phototherapy light cap is a flexible, generally hemispherical cap having a light source to supply suitable dosage requirements of current and future light therapies. The phototherapy light cap may also include a rechargeable battery source, a light source or an array of light sources, a light diffuser and an interface to a recharging source that may be a docking station. A phototherapy light cap may alternatively be an insert for any commercial head dressing, preferably adapted for convenient recharging.

Description

Phototherapy Light Cap

Field of the Inventions

The inventions described below relate to the field of hair growth and regeneration in a human scalp.

Background of the Inventions

There is a substantial body of anecdotal evidence supporting phototherapy for promoting human hair growth and regrowth. Additional evidence exists that low-level light therapy (LLLT) may be most beneficial if provided within one or more narrow spectral windows .

At least three US manufacturers sell products that deliver red light to the scalp: Sunetics, HairMax and Laser Hair Therapy. Prior art methods of dosing include "laser" combs using LEDs or laser diodes which must be slowly scanned across the scalp or full-head hoods similar in appearance and dimensions to the classic hair salon hair dryer hood which deliver red light to the head, usually in a doctor's office setting.

Conventional phototherapy regimens generally require the patient to administer the therapy, either by applying the light themselves, region by region with a light comb or by sitting under a hood in a medical or salon setting.

Another complication of conventional phototherapy is that patient compliance with the therapy requirement of a three times weekly, fifteen minutes per session is not good, largely due to the difficulties described above. Another serious drawback for users with thinning but substantial remaining hair is that their at-risk remaining hair blocks therapeutic light from reaching their scalps, eliminating or substantially reducing the beneficial effects of LLLT.

Summary

The phototherapy light cap discussed below is a flexible, generally hemispherical cap having a light source to supply suitable energy dosage for light therapy. The phototherapy light cap may also include a rechargeable battery source, a light source or an array of light sources, a light diffuser and an interface to a recharging source that may be a docking station. The phototherapy light cap may alternatively be an insert for any commercial head covering or headgear, so that it may be disguised during use.

An alternate phototherapy apparatus includes one or more light sources such as LEDs or lasers, a power source, and a series of optical fiber strands that originate from the light source and terminate near the scalp of the wearer. The light therapy hat may also include an optical switch, or any suitable switch apparatus, to distribute light from the source to the various optical fibers, a programmable integrated circuit to control the switch, and a flexible polymer matrix to hold the terminal ends of the fibers relative to the scalp. The matrix may be adapted to fit under any suitable hat such as a standard baseball cap. The terminal end of the optical fiber strands may include any suitable 90° termination and or any suitable lens or lenses to control the distribution of the illumination .

The phototherapy light cap may combine phototherapy with one or more of a host of therapies such as vibration, massage, occlusion (creating a warm scalp environment by preventing scalp heat and moisture from escaping), ventilation, heating, cooling and a variety of liquid applications. A method for combined therapy includes the steps of parting the user's hair along the sagittal midline to expose the scalp, and applying hair regrowth formulations (preferably a foam or gel of sufficient viscosity) to the scalp along the sagittal midline, and placing the phototherapy cap over the treated scalp area to deliver heat & occlusion. This serves to liquefy the hair regrowth formulations and keep volatile solvents such as alcohol trapped, and provides illumination as a hair regrowth agent and to improve transdermal absorption of hair regrowth formulations .

Alternate configurations may also include a microprocessor-controlled light dosing circuit suitable for controlling the scalp area to be treated and associated software and provision of red tracer lights for an infrared dosing apparatus. An alternate configuration includes one or more light guides to convey the therapeutic light energy from the cap surface past any hair to the surface of the scalp. A passive phototherapy light cap may provide filters to eliminate unwanted light energy having non-therapeutic or counter-therapeutic frequencies.

There are energy spectra that facilitate hair follicle growth, each absorption peak with about 20 to 40 nm full spectral width (at half maximum) centered about four key wavelengths in the visible and infrared region of the spectrum, specifically at 630 nm, 670 nm, 800 nm and 900 nm. Typical dosing levels are from 1-10 J/cm², delivered over a duration of ten or more minutes, shorter durations being less effective. Thus, individual light sources, each illuminating a one square centimeter area of scalp with a 5-10 mW total output power integrated over that square cm constitute a suitable light source array.

Brief Description of the Drawings

Figure IA is a top view of a phototherapy light cap. Figure IB is a side view of the phototherapy light cap of Figure IA.

Figure 1C is a cross-section view of the phototherapy light cap of Figure IA taken along A-A.

Figure 2A is a top view of an LED array.

Figure 2B is a close view of an LED connected to a portion of an array circuit.

Figure 2C is a schematic diagram of a light module with four series LEDs.

Figure 3 is a cross-section of an alternate phototherapy light cap.

Figure 4 is a cross-section of another alternate phototherapy light cap.

Figure 5 is a top view of a woven conductor array.

Figure 6 is a cross-section of a phototherapy light cap with light guides.

Figure 7 is a cross-section of a light guide configuration for high intensity sources.

Figure 8A is a top view of a beam splitter light distribution system for high intensity light sources.

Figure 8B is a side view of the beam splitter light distribution system of Figure 8A.

Figure 9 is a plan view of a portion of a multilayer phototherapy lattice.

Figures 9A, 9B, 9C and 9D are cross-section views of the portion of a multilayer phototherapy lattice of Figure 9. Figure 10 is a plan view of a portion of a combined multilayer phototherapy and liquid treatment lattice.

Figures 1OA, 1OB, 1OC and 1OD are cross-section views of the portion of a multilayer phototherapy lattice of Figure 9.

Figure 11 is a perspective view of a passive phototherapy light cap.

Detailed Description of the Inventions

Cap 10 of Figures IA, IB and 1C includes cover 11 protecting and shielding LED array 12 and diffuser 14 which combine as therapy insert 15. Cap 10 may be powered by one or more rechargeable batteries such as batteries 16 and controlled using switch 17 which may be secured to hat brim 19 along with microcontroller or microprocessor 20. Batteries 16 may be recharged through a button connector/interface such as connector 22. The power source, power controller and switch may also be separated from the therapy insert and provide the electrical power through any suitable tether.

As shown in Figure 2A, the therapy insert includes several triangles, segments or gores 23A, 23B, 23C, 23D, 23E and 23F that may be secured at their edges to form a generally hemispherical cap. The LED arrays in each gore such as array 12 are generally identical. Each LED array may be controlled simultaneously or separately and may each consist of subarrays under separate control. Such area control is desirable for clinical trial studies or to deliver phototherapy differentially to different areas of the scalp.

Figure 2A and Figure 2B illustrate a configuration of LEDs for each gore, such as gores 23A, 23B, 23C, 23D, 23E and or 23F. The LED arrays may be wired in series as illustrated with all LED anodes 25A connected in common and all LED cathodes 25C connected in common. Alternatively, light modules such as light module 29 of Figure 2C may be connected between the LED anode 25A and the LED cathode 25C. Within each light module are four LEDs 29D in series with a current limiting resistor 29R. This configuration permits the voltage to each light module to be higher but the total current to be lower, resulting in reduced resistive heating and thus less wasted power. Series resistor 29R prevents catastrophic failure of the unit by limiting current to a value tolerable by a single LED such as LED 29D.

Each gore, petal, wing or sector such as gore 23A may be separately controlled. Thus if gores 23A, 23B and 23C are located on the right side of a cap and gores 23D, 23E and 23F are located on the left side of a cap, and gores 23A and 23F are in the front of a cap, then gores 23C and 23D are in the back of the cap. With this configuration, typical male pattern baldness may be treated using primarily gores 23C and 23D, and typical female front-centered baldness may be treated using primarily gores 23A and 23F. With specific sector control each sector may be independently controlled for time and or intensity.

The phototherapy light cap is discussed with respect to red-light phototherapy dosing but it can be used to apply any other wavelength optical therapies. For example, the cap light dispenser can be used to deliver broad-spectrum white light therapy, which is preferred by some users. Commercially available white light LEDs consisting of blue LEDs with phosphor layers will provide the desired intensity, up to and beyond typical bright daylight brightness levels. The current therapeutic cap or cap insert concept can also be extended to heat or cooling inserts or electromagnetic therapies. The phototherapy light cap may also be constructed so as to provide any combination of these and other therapies at the same time. The phototherapy light cap may additionally combine one or more of a host of therapies such as vibration, massage, occlusion (creating a warm scalp environment by preventing scalp heat and moisture from escaping), ventilation, heating, cooling and a variety of liquid applications. For example, a combined therapy approach for women ' s hair regrowth would include the steps:

1. part user's hair along the sagittal midline exposing the scalp;

2. apply a hair regrowth formulation to the scalp along the sagittal midline, preferably a foam or gel of sufficient viscosity;

3. place phototherapy cap over the treated scalp area to deliver heat & occlusion to liquefy the hair regrowth formulations and keep volatile solvents (e.g., alcohol) trapped while providing illumination as a hair regrowth agent and to improve transdermal absorption of formulations .

A combined therapy approach for men ' s hair regrowth would include the steps:

1. apply a hair regrowth formulation to the entire affected head (front, top, crown, occipital);

2. work slightly into hair;

3. place phototherapy cap over the treated scalp area to deliver heat & occlusion to liquefy the hair regrowth formulation and keep volatile solvents (e.g., alcohol) trapped while providing illumination as a hair regrowth agent and to improve transdermal absorption of formulations . In both examples, the hair regrowth formulations may also include elements for hair volumizing and or camouflage with keratin-like powder or scalp dye which may be heat-activated and/or heat-cured substances, light-activated and/or light- cured substances. The phototherapy cap may then deliver heat & illumination to physically and or chemically change cosmetic formulations to provide a suitable cosmetic effect.

Referring to Figure 1C, a first configuration suitable for very thin hair in which the hair does not present a significant light shield to the scalp, a high-forward scatter diffuser such as diffuser 14 may be used in close proximity to the light emitter array 12, achieving uniform illumination and requiring only very small separation between scalp and light source. Diffusers can range from inherently scattering, usually milky-colored plastics to dielectric-scatterer impregnated plastics and standard photographer's white diffuser cloth.

The diffuser in a thin-film diffuser configuration may be a photographic plastic forward scattering film, for example, folded over as necessary to create a suitable diffuser. The complete power rail, LED, diffuser combination may have a thickness of under 5 mm. Various high forward scattering materials and engineered materials can be used to create an optimally thin and effective diffuser. The diffuser must have minimum attenuation of light while angularly spreading the preferably wide-angle LED output beam further out so that the diffuser output illuminates the scalp with uniform dosage. The goal is to have the diffuser appear as a uniformly glowing forward light emitter.

Referring now to Figure 3, when the hair is thin enough to be insubstantially opaque to LLLT illumination, uniform scalp illumination may be achieved by spatial separation of an array of wide-angle emission surface-emitting LEDs combined with use of a light emitter-scalp separation layer, preferably consisting of bristles under laying the LED array in a suitable pattern to maintain adequate separation for the individual LED beams to diverge adequately to achieve uniform illumination. LED Substrate 24 supports one or more LEDs such as LED 25. Spacer 26 includes a plurality of openings 27 oriented relative to the LEDs to optimize the light energy emissions of the LEDs and to uniformly illuminate scalp 1. Spacer 26 includes one or more bristles such as bristle 28 to maintain a predetermined space between LEDs 25 and scalp 1.

Wide-angle LEDs can be used without a diffuser by employing a short separation between the LED array and the scalp surface to allow the individual beams to diverge enough to achieve uniform intensity surface illumination. Experiments were performed using a photodiode linearized in a transimpedance configuration to measure absorbed energy with respect to position at various heights above the LED array. With only 6 mm of separation, the beam varied 20% across the illuminated flat surface. With 9mm spacing, the variation was under 3%. A simple LED array with 5mm to 10mm spacer bristles will provide adequate uniformity for the scalp.

Another alternate technique for achieving uniform illumination is by redirecting the therapeutic light energy from the source to points under most of an opaque hair volume by means of waveguides. Referring now to Figure 4, one or more waveguides such as waveguide 30 may employ a design that has a wide-diameter LED-side surface 3OA to ease alignment tolerance combined after an adiabatic taper 3OT, to a smaller waveguide portion that emits a wide-angle emission from emitting surface 3OE. Additional spacer bristles may also provided for the "hair bypass" light guides to achieve uniformity. As illustrated in Figure 5, the light source arrays can be placed at grid points in a woven conductor array such as conductor array 31 of Figure 5 or on a flexible PC board. This single-layer board consists of a copper interconnect layer sandwiched between two thin polyimide layers .

Referring now to Figure 6, LED array 32 illuminates a co- registered lens and waveguide array 35 that directs light inwardly toward the scalp through a light guide 35L that penetrates the hair and terminates at the scalp 1, in contact with the scalp. At the scalp level, light energy from the light guide is dispersed so as to re-emit in all downward directions, bathing the scalp with substantially uniform illumination, bypassing the hair above it.

Scattering bulb 36 in contact with the scalp can be, for example, a single or multiple reflective and or refractive elements, preferably spherical, that will refract and or reflect light with little loss but redirect it around the bulb so that it more or less uniformly illuminates the scalp.

Referring now to Figure 7, another light guiding configuration such as light guide 38 employs refraction and reflection to conduct therapeutic light past hairs such as hair 34 to the scalp. Light source 39 which may be LEDs or other suitable light sources such as lasers. Light 40 is captured by an integrated, preferably plastic, waveguide channel 38 which collects and focuses light 40 from the source and then redirects it downward toward an included scatterer 44. The downward light is then uniformly directed toward the scalp.

Referring now to Figures 8A and 8B, high intensity light source 37 may be LEDs or other suitable light sources such as lasers. Light 40 is captured by an integrated, preferably plastic, waveguide channel 41 which collects and repetitively splits the light 40 using splitters 42A, 42B and 42C and then redirects it downward to the hair at a plurality of re-emitter locations such as diffuser 43. The downward light can be directed to the scalp, to a diffuser or to a subsequent additional waveguide element.

Waveguides for the hair-bypass configurations of the LED array may be constructed from flexible 1 mm diameter acrylic rods. The emission at 9 mm spacing from the rod array ends will be uniform. Alignment tolerance is tight for 1 mm diameter rods and the output divergence angle is somewhat smaller than the original LED sources. Both of these limitations can be advantageously traversed by use of tapered rods that have a larger emitter-side diameter, such as 2 mm, and a smaller output diameter, typically 0.5 mm.

Although there are many ways of generating light in the desired wavelength bands at the desired total power levels, such as by fluorescent, incandescent, laser diode, LED and photo luminescent sources, a suitable method of delivering light is by means of an array of light emitting diodes, preferable because they meet the optical power requirements while being low in operating voltage and electrically efficient, low in cost, have a wide emission angle and are therefore able to illuminate a wide area more or less uniformly with a relatively thin intervening diffuser. Fewer diodes or a single diode source may be able to have their output directed to emanate quite uniformly from a broad surface, but the sources represent a concentrated heat load and light source and are burdened by the light distribution requirement .

Surface emitting light emitting diodes are currently preferred because they are low in profile and can emit light with very little source footprint either in area or in thickness. Thin diffuse light-source inserts are preferred so that the overall therapeutic device is as comfortable to wear and as unobtrusive as possible. The ideal device is battery powered (as by rechargeable battery embedded or tethered to the therapy insert). Suitable rechargeable matrices include lithium ion polymers which possess an energy density of over 100 Watt-hours per kg. For example, to achieve full adult head coverage using 10 J/cm2 over 300 cm2 would require 3kJ of energy. With a 20% electrical-to-optical conversion efficiency, 15kJ of stored energy per dosing would be required, which is equivalent to less than 5 Wh of battery storage capability or 50 grams weight of storage medium. A typical baseball cap weighs about 80 grams, so that the insert itself, including battery, connection matrix, light source(s) and light diffuser need not more than double the typical cap weight.

Although the LED array is not likely to produce uncomfortable heat levels on the scalp, it is possible to move heat load elsewhere on the cap or to the outer surface of the cap by various electrical or passive heat conducting means. Cooling can be achieved by Peltier cells, if desired, heat being dissipated in the brim or outer surface of the cap.

Creating an array of ventilation holes for convective cooling may also be achieved with no significant reduction of the light intensity directed toward the scalp.

Figure 9 illustrates a portion of a multilayer phototherapy lattice 45 formed of substrate layer 46, optoelectronics layer 48 and capping layer 50. Substrate layer 46, which is the scalp side layer may also includes an array of bristles such as bristle 51. Opto-electronics layer 48 includes flexible conductor arrays such as anode array 48A and cathode array 48C as well as LEDs such as LED 52 which is soldered or otherwise electrically connected between anode array 48A and cathode array 48C. Capping layer 50 creates a hermetic seal for opto-electronics layer 48. The multiple layers and or bristles may be formed of any suitable flexible material such as silicone and may formed in any suitable color or be clear. Lattice 45 also includes ventilation openings such as vent opening 53 to reduce weight and provide good ventilation through the lattice.

In an alternative multilayer therapy lattice of Figure 10 multimode multilayer therapy lattice 54 includes substrate layer 55, opto-electronics layer 57, fluid distribution layer 59 and capping layer 61. Substrate layer 55, which is the scalp side layer may also includes an array of bristles such as bristle 62. Opto-electronics layer 57 includes flexible conductor arrays such as anode array 57A and cathode array 57C as well as LEDs such as LED 63 which is soldered or otherwise electrically connected between anode array 57A and cathode array 57C. Fluid distribution layer 59 includes multiple interconnected fluid distribution lumens or channels 64 for simultaneous delivery of therapeutic fluids, foams, compounds and or formulations to assist in low-level light therapy or as simultaneous therapy. Capping layer 61 creates a hermetic seal for fluid distribution layer 59 and opto-electronics layer 57. The multiple layers and or bristles may be formed of any suitable flexible material such as silicone and may formed in any suitable color or be clear. Lattice 54 also includes ventilation openings such a vent opening 65 to reduce weight and provide good ventilation through the lattice.

Referring now to Figure 11, passive light therapy cap 66 may be used to filter out external light sources (room light or sunlight) so as to provide only therapeutic wavelengths to the patient's scalp. Passive phototherapy will generally involve intense "white-light" sources, such as sunlight, which is not effective in hair growth therapy because the green and blue regions of the visible spectrum are deleterious at high intensities. Therefore, sunlight therapy may be achieved by passing only therapeutic wavelengths to the scalp. Such a configuration of restricted-wavelength phototherapy may be used because it is passive and the light source of choice, daylight, is free and ubiquitous. Such a passive cap can be configured to also prevent ultraviolet exposure.

Achieving wavelength-specific attenuation is possible in a variety of ways. For example, filter element 67 colored films consisting of a polymer matrix with various dyes can achieve red-only transparency. More sophisticated multilayer dielectric films can provide reflectivity in blue and green portions of the spectrum to provide relative cooling. Such films, which can also be comprised to absorb rather than reflect unwanted wavelengths, can be tailored to have complex spectral shapes for more demanding wavelength-specific therapy or novelty purposes.

The red wavelength region of the solar spectrum is intense enough to provide adequate dosing (10J/cm²) over a ten to thirty minute period. Because different cloud cover, times of year, geographical locations, etc will alter the optical power level, this technique optionally provides for a resettable dosimeter element 68 which lets the user know when they have achieved a selected degree of exposure.

While the preferred embodiments of the devices and methods have been described in reference to the environment in which they were developed, they are merely illustrative of the principles of the inventions. Other embodiments and configurations may be devised without departing from the spirit of the inventions and the scope of the appended claims.

Claims

We claim:

1. A portable phototherapy apparatus comprising:

a power supply;

a power controller;

a plurality of light emitting diodes powered by the power supply under control of the power controller, the plurality of light emitting diodes providing phototherapy to a patient's scalp;

an LED membrane for securing and supporting the plurality of LEDs, the LED membrane shaped to form a generally hemispherical shape with a concave inner surface with the LEDs on the concave inner surface; and

a cap for enclosing the LED membrane.

2. The portable phototherapy apparatus of claim 1 further comprising:

a plurality of bristles disposed on the concave inner surface of the LED membrane for creating a predetermined separation between the LED membrane and the patient's scalp.

3. The portable phototherapy apparatus of claim 2 further comprising:

a plurality of fluid distribution lumens disposed within the plurality of bristles and the LED membrane for delivering therapeutic compounds to the patient's scalp during phototherapy.

4. The portable phototherapy apparatus of claim 1 further comprising: a diffuser oriented between the LED membrane and the patient's scalp.

5. A portable phototherapy apparatus comprising:

a power supply;

a power controller;

a plurality of light emitting diodes powered by the power supply under control of the power controller, the plurality of light emitting diodes providing phototherapy to a patient's scalp;

an LED membrane for securing and supporting the plurality of LEDs, the LED membrane shaped to form a generally hemispherical shape with a concave inner surface with the LEDs on the concave inner surface; and

a cap for enclosing the LED membrane and supporting the power supply and the power controller.

6. The portable phototherapy apparatus of claim 5 further comprising:

a plurality of bristles disposed on the concave inner surface of the LED membrane for creating a predetermined separation between the LED membrane and the patient's scalp.

7. The portable phototherapy apparatus of claim 6 further comprising:

a plurality of fluid distribution lumens disposed within the plurality of bristles and the LED membrane for delivering therapeutic compounds to the patient's scalp during phototherapy.

8. The portable phototherapy apparatus of claim 5 further comprising:

a diffuser oriented between the LED membrane and the patient's scalp.

9. A method of treating and preventing hair loss of a patient comprising the steps:

applying therapeutic hair regrowth compounds to the patient's scalp;

placing a phototherapy apparatus over the treated scalp area, the phototherapy apparatus including:

a power supply;

a power controller;

a plurality of light emitting diodes powered by the power supply under control of the power controller, the plurality of light emitting diodes providing phototherapy to a patient's scalp;

an LED membrane for securing and supporting the plurality of LEDs, the LED membrane shaped to form a generally hemispherical shape with a concave inner surface with the LEDs on the concave inner surface; and

a cap for enclosing the LED membrane and supporting the power supply and the power controller.

10. The method of treating and preventing hair loss of claim 9 wherein the step of applying therapeutic hair regrowth compounds to the patient's scalp further comprises the steps:

parting a patient's hair exposing the scalp;

applying therapeutic hair regrowth compounds to the scalp along the part.

11. The method of treating and preventing hair loss of claim 9 wherein the step of applying therapeutic hair regrowth compounds to the patient's scalp further comprises the steps:

applying heat-activated substances to improve hair volume.

12. The method of treating and preventing hair loss of claim 9 wherein the step of applying therapeutic hair regrowth compounds to the patient's scalp further comprises the steps:

applying heat-activated substances to camouflage hair loss.

13. The method of treating and preventing hair loss of claim 9 wherein the step of applying therapeutic hair regrowth compounds to the patient's scalp further comprises the steps:

applying light-activated substances to improve hair volume.

14. The method of treating and preventing hair loss of claim 9 wherein the step of applying therapeutic hair regrowth compounds to the patient's scalp further comprises the steps:

applying light-activated substances to camouflage hair loss.