Systems and methods for tissue treatment

Abstract

A method for aesthetic soft tissue treatment includes placing at least one applicator in contact with the patient's body. The applicator has at least one electrode. Electrotherapy and radio frequency therapy are provided to the soft tissue, optionally with overlay or sequentially. A handheld applicator may be used, with the applicator moving during the therapy, which may provide muscle stimulation in the patient, or provide an analgesic effect during the treatment. A spacing object may be positioned between the skin of the patient and the applicator.

Description

TECHNICAL FIELD

The field of the invention is devices and methods for providing aesthetic and therapeutic soft tissue treatment via application of a radio frequency field (RF) and electric currents into the human and/or animal soft tissue.

BACKGROUND

Skin tightening, wrinkle reduction, removal of cellulite, skin lesions, breast and lips enhancement, reduction of fatty tissue, muscle building, strengthening and/or body contouring are aesthetic treatments for which there is a growing demand. Aesthetic therapy commonly includes the application of different treatment energy sources, such as light sources, radio frequency energy sources, ultrasound energy, electric energy or other sources. Every source of energy mentioned above may have some beneficial effect.

Energy is focused to skin and/or to lower layers of body soft tissue. Human skin is composed of three basic layers: the epidermis, the dermis and the hypodermis. The epidermis is composed of the outermost layers of cells in the skin. The epidermis is a stratified squamous epithelium, composed of proliferating basal and differentiated suprabasal keratinocytes which acts as the body's major barrier against an inhospitable environment. The dermis consists of collagen, elastic tissue and reticular fibers. The hypodermis is the lowest layer of the skin and contains hair follicle roots, lymphatic vessels, collagen tissue, nerves and also fat forming a subcutaneous white adipose tissue (SWAT).

Energy may be delivered to soft tissue in order to stimulate skeletal muscle contraction, to treat fat, fibrous tissue, blood vessels and/or other supporting matrix that soft tissue include. Fat is composed mostly of adipocytes. It is possible to distinguish different types of fat tissue but in general, for aesthetic treatment, of primary interest is visceral fat located around internal organs and subcutaneous fat in the hypodermis and/or beneath the skin but above skeletal muscle.

Invasive therapies for body and/or skin enhancement such as skin tightening, wrinkle reduction, cellulite reduction, skin lesions, breast and/or lips enhancement, reduction of fatty tissue and others may be associated with relative long recovery time, discomfort during and/or after treatment (e.g. accompanying liposuction) and increased health risk. Conventional non-invasive treatments for body and/or skin enhancement includes drugs, ointments with active agents, exercise, dieting or combinations of these treatments. These may not be effective or even possible under certain circumstances and therefore the results may disappoint.

Application of RF energy to the tissue may have several benefits on the body and skin function and/or appearance. Nevertheless, methods and devices used for non-invasive ways for improving skin visual appearance and/or body shape and contour by delivering RF energy source of energy may result in irritation of the skin and/or other soft tissues, painful application especially for high intensity stimulus, discomfort during the treatment, lack of deep tissue stimulation, inappropriate localization and/or inhomogeneity of the delivered energy to the treated tissue. Some existing devices and therapies cannot compensate for unexpected circumstance which may occur during the treatment, resulting in treatment which can be insufficient, non-homogenous or risky.

Another problem is that treated cells are accumulated in the soft tissue during and/or after treatment. Accumulation of treated cells may slow healing or cause inflammation and safety concerns.

SUMMARY

It is an object of the present method and/or device to introduce an apparatus and method for improving skin viability, skin and body rejuvenation, skin tightening, scar removing, spider veins removing, restoring and restructuring collagen in the soft tissue body shaping (e.g. butt lifting, breast lifting etc.), body contouring, circumferential reduction, cellulite removing, adipose tissue reduction, adipose tissue removing, muscle relaxation, relaxation of muscle tone, muscle building, muscle strengthening, treating and stimulating pelvic floor tissue and adjacent muscles, remodeling of outer part of genitals treat sexual dysfunctions, treat or reduce incontinence problems, accelerate neocolagenesis, improving blood flow, lymph flow, stimulation of lymph nodes, movement of the vessels, bruise removing, reduce swelling, enhancing vitamin D metabolism, restoring nerve signal transfer, accelerate body metabolism, accelerate cell metabolism, pigmentation disorders, tattoos removal, stress relive, micro-dermal abrasion, hair removal, shortening of recovery time after injury and/or other skin and body affliction using application of RF energy and electrical stimulation to the soft tissue.

Different body parts may be treated, e.g.: saddlebags, abdomen, love handles, bra fat, arm, buttocks and/or others. During one session one or more body parts may be treated.

The device and/or method are based on synergic effect of combined electrotherapy and RF therapy provided by one or more applicators. Therapies may be provided simultaneously, consecutively or with partial overlay.

One or more applicators with a source of energy able to provide electrotherapy and/or RF therapy may be stationary and/or movable. The device may include one or more applicators designed as handheld applicator(s) and/or applicators attached to patients body automatically operating.

The device and method is targeted mostly to people with BMI (body mass index) in range from 18 to 40.

Currently no device and/or method is known having movable applicators with sequential or simultaneous combination for effectively applying electrotherapy (for mainly analgesic effect and/or muscle stimulation) and/or RF therapy for aesthetic treatment.

Combinations of electrotherapy with RF therapy provide a synergic effect as described below. A handheld applicator may be personalized according to an individual patient's needs. The applicator may be able to change targeting and parameters of the treatment during the treatment session without stopping the treatment. The present device and method may provide high treatment effectivity, shortening time of one treatment session, decreasing treatment costs and also provide long lasting results. The device and/or method may have a lower initial cost of the device against equipment covering whole body part treatment techniques that require more or larger treatment energy sources. More complicated and more expensive hardware and software components may be avoided while providing homogenous effective treatment with minimal health risks.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of a treatment system.

FIG. 2 illustrates example of thermal gradients.

FIG. 3 is a schematic representation of a spacing object.

FIG. 4 is schematic representation of cooperation multiple applicators across the patient body.

FIG. 5 is a partial perspective view of an embodiment of the belt providing hardware pattern.

FIG. 6 is a schematic diagram of treatment elements in the applicators.

GLOSSARY

Stimulating signal is a signal inducing a physiological effect in the patient's body e.g. a muscle contraction.

Electrotherapy or electrostimulation or electro-stimulation or electrical stimulation is the application of electrical energy (current) into the soft tissue for medical and aesthetic treatment with minimal and/or no thermal effect in soft tissue. Electrotherapy may have different targeted soft tissue and/or stimulating effects (e.g.: analgesic, muscle contraction, muscle relaxation and/or other as described below) depends on electrotherapy parameters. One or more electrotherapy effects or targeting may be combined during one treatment session.

RF therapy provides radio-frequency waves into the soft tissue in order to provide thermal effects in the patient's soft tissue. RF therapy may have different targeted soft tissue and/or stimulating effect (e.g.: skin tightening, cellulite removing, reduction of number and/or volume of adipose cells, collagen recovery and restructuring and/or other effects as described below) depending on RF therapy parameters. One or more RF therapy effects or targeting may be combined during one treatment session.

A treatment session starts with a first treatment therapy and ends with the last treatment therapy described below where delay between two consecutive therapies is no longer than 100 minutes.

RF therapy is application of electromagnetic waves into the soft tissue, with at least some thermal effect in soft tissue.

Soft tissue includes skin, muscle, fat, fibrous tissue, nervous tissue (e.g. neurons, motor neuron, and neuromuscular junction) and/or other supporting matrix.

Parameters of the therapy may be any parameter that can influence treatment therapy (e.g. intensity of the delivered energy, frequency of delivered energy, shape of delivered energy and its modulation, phase shift between several waves, targeting of the energy source, type of the energy source, time interval between application one/or more, the same or different types of the energy source, duration of the treatment therapy, sequence of the treatment therapy, number of the applicators, position of one or more applicators, geometry of the applicator, cooling and/or heating during the treatment, method of the treatment and other parameters that could provide changes in the treatment therapy).

A treatment energy is an energy with a treatment effect (e.g. muscle contraction, heating of the soft tissue etc.). Preferred treatment energy sources are electrodes providing RF therapy and/or electrotherapy. Treatment energy is included in RF waves and/or electric current.

Therapy is at least one of electrotherapy and/or RF therapy.

Aesthetic treatment is one or more of: skin tightening, wrinkle reduction, removal of cellulite, skin lesions, breast and lips enhancement, reduction of fatty tissue, muscle building, strengthening body shaping, body contouring and/or other skin and body affliction.

Viability is better resistance against external influences and removing of some skin affliction as acne treatment, scar removal.

Rejuvenation is younger appearance, removing symptoms of aging.

Skin tightening is change in the helical structure of collagen and results in a micro inflammatory stimulation of fibroblasts, which produces new collagen (neocollagenesis) and new elastin (neoelastogenesis), as well as other substances to enhance dermal structure (breast, lips enhancement, wrinkle reduction and others).

Body shaping is loss of fat but also muscle strengthening, increasing muscle definition and volume of the muscle.

Body contouring is loss of fat (as fat is defined above).

Signal and energy has the same meaning in the manner of delivered energy such as an electromagnetic field, RF field by electrode into the soft tissue and/or electrical energy.

The pelvic floor is formed in a bowl-like structure and contains tissues

DETAILED DESCRIPTION

The device and method may include one or more applicator providing RF therapy and/or electrotherapy. The device may include heating/cooling mechanism. Patient surface may be cooled or heated for the reason of minimizing discomfort, influence of RF therapy tissue penetration and/or decrease health risk.

Cooling/heating may be provided by thermoelectric element with heating/cooling mechanism based on Peltiere's effect and/or heating cooling may be provided by thermal diffusion provided by heated/cooled liquid, air and/or other material with good thermal conductivity. Heating may be also provided by treatment source of energy e.g.: light emitting source of energy, RF source of energy, ultrasound, source of positive and/or negative pressure applied to the patient's surface etc.

Heated or cooled may be directly patient's body and/or any part of the device (e.g. applicators head).

Warming of the tissue is based on dielectric characteristic of the tissue. Heating and/or cooling of the soft tissue may play a significant role because of the soft tissue dielectric characteristic influenced by blood flow in the tissue. Temperature of the soft tissue also influenced metabolism of the cells and organism. While the conductivity of soft tissue increases with the temperature, cooling of the soft tissue may result in less electrical conductivity. These properties may help with targeting of the delivered energy into the soft tissue. Heating and/or cooling during, before and/or after treatment session may be provided via delivering of the energy via therapy, by cooling/heating pads, plates based on thermal diffusion principle, spacing object and/or gels.

Some component of the device may be cooled to prevent overheating.

The present devices may have several possible embodiments based on invasive and/or non-invasive methods. The device sand methods use synergic effects of combination RF therapy with electrotherapy.

According another embodiment RF therapy and electrotherapy may be also combined with any one or more other treatment energy sources: e.g. heating energy source, light energy source, ultrasound energy source, shock wave energy source and/or magnetic field energy source. RF therapy and also RF electrodes may be replaced by any other(s) treatment energy source described above.

RF energy may selectively treat different tissues based on their dielectric properties and localization. Applied RF field affects treated soft tissues mainly by thermal effect. However, RF field may also influence ions and partially charged molecules in the patient's body. This effect may be beneficial in different types of therapies and may provide therapy faster, safer and more effective treatment.

On the other hand the electrotherapy is founded on effects where an electric current (a) passes through the body, and locally changes tissue polarization and ion balance that effect electric potentials in the soft tissue. The effect of electrotherapy may be muscle contraction, local analgesia and/or creating local potentials that influenced cell metabolism, membranes permeability, body metabolism and dielectric characteristic of the soft tissue. Electrotherapy may also heat specific soft tissue structures based on tissue resistivity. According to one embodiment the RF energy source and electrical stimulation may be used simultaneously or in sequence with one or more energy sources.

Electrotherapy maybe used in order to improve: analgesia, tissue regeneration, relaxation, partly tissue ionization, muscle building, muscle strengthening and/or others mentioned in the document. Combinations of above mentioned electrotherapy effects and RF therapy have desirable synergic impact on the soft tissue treatment.

Synergistic use of electro-stimulation of skeletal muscle fibers and/or other soft tissue by using electrotherapy and application of RF field has several benefits. Repeated contraction of muscle fibers improves effect to lymphatic and blood circulation in local and peripheral tissue. Increased blood circulation has positive effect to homogeneity and dissipation of delivered energy into the targeted tissue. Combined therapy (in simultaneous and/or sequential use) minimizes risk of creating of hot spots and consecutive unwanted soft tissue injury during the treatment. Without being bound to the theory it is believed that the increased blood flow in the target soft tissue and/or peripheral soft tissue has substantial influence to removal of cellulite and/or fat tissue.

Another method to reduce adipose cells is skin massaging by electro-stimulation. This method is based on improving of blood circulation and increasing fat metabolism. Improved effect of blood, lymphatic circulation and fat metabolism may be provided by skeletal muscle stimulation.

Electrotherapy may be provided simultaneously, with some overlay or sequentially, before and/or after application of RF therapy. Targeting of electrotherapy may be provided to the same and/or to the different target area as RF therapy is targeted. Electrotherapy and/or RF therapy may be provided by different types of pulses and/or by continual stimulation. Energy of RF therapy and/or electrotherapy may be modulated in different manners (e.g. shape of the signal and his envelop-curve outlining extremes of the signal, polarization of the signal, intensity, frequency, timer between one or more pulses and/or others modulation of delivered energy into the patient soft tissue).

An advantage of electrotherapy is targeting of the energy into concrete muscle fibers or muscle groups. Contracting of muscle fibers may be used for internal massage of target and/or adjacent tissue. This massage phenomenon is beneficial to lymphatic and blood circulation that cause acceleration of metabolism. Faster metabolism provide better treatment result and more effective treatment which means shorting the therapy time and the effect may be long lasting in comparison with prior art methods. Increased lymph flow, blood flow and metabolism activity caused by electrostimulation may help to remove necrotic cells damaged during RF therapy that lower risk of panniculitis.

According to another embodiment a beneficial effect is to treat the cells in order to induce apoptotic death. Due to the combined effect of the RF therapy and electrotherapy and increased blood and lymph circulation, the cells at the targeted area are treated more homogenously and removing of cells is faster.

To improve the treatment effects, the electrotherapy may be used also in several other ways: analgesia, tissue regeneration, relaxation, partly tissue ionization, muscle building, muscle strengthening and/or others mentioned in the document. Combinations of above mentioned electrotherapy effects and RF therapy have desirable impact on the soft tissue treatment.

Analgesic effects of electrotherapy may be used to minimize discomfort during the treatment. Some oversensitive individuals frequently have uncomfortable and/or painful feelings during the treatment if the treatment therapy is running in the range of safe threshold limits. If the delivered energy would be in comfortable limits for oversensitive individuals, treatment therapy would be inefficient, that is the reason why analgesic effect of electrostimulation is desirable during the RF therapy.

Without being bound to the theory, it is believed that the electrotherapy may also improve localization of RF therapy, because through electrotherapy it is possible to change impedance in soft tissue. Partial ionization of some tissue could also improve localization of delivered RF energy and make therapy faster and more effective.

It is possible to combine different effect of electrotherapy (e.g. analgesic and/or muscle stimulation) and/or RF therapy at the same and/or different time and/or at the same or different areas. This may be used to influence treatment results (e.g. tissue repair, improve cutaneous perfusion during and/or after treatment, comfort during the treatment, effectiveness of the treatment and/or other treatment process parameters and results).

Another synergic use of warming up tissue by an RF field and electrotherapy is improvement of muscle relaxation after muscle stimulus reverberation. Tissue warm up accelerates tissue regeneration and prevents or minimizes risk of muscle injury.

The applicator may use three types of the electrodes used as a treatment energy source. A first type of the electrode may be used as a source of energy for electrotherapy and also RF therapy. A second type of the electrode may provide just electrotherapy and the third type of the electrode may provide just RF therapy. One applicator may combine each type of the electrodes or just some of them.

In one embodiment the applicator may be stationary adjacent to the patient surface. In another embodiment moving the applicator or multiple applicators may be advantageous.

The one or more applicators may be placed or moved in a chosen geometry pattern comprising of e.g. linear, wavy circular, elliptical, zigzag, polygonal, oval, irregular, curvilinear or their combination. This moving may be replicated by placing one or more stationary applicators in position and switching over relevant electrodes, without moving the applicators.

The same possible movements of one or more applicators may be considered for moving the electrodes.

The applicator may have a head with removable extensions. Head extensions may be specialized for different kinds of therapies. Extension heads may have different sizes, shapes, geometry (e.g. different distance between RF electrodes that influenced treatment depth), numbers and type of the treatment energy sources (e.g. type of the electrodes) and may be made of different materials (e.g. ceramic, silicone, metal and/or polymeric materials). The applicator's extension heads may be changed during the treatment session based on treated body part or individual patient's needs. The type of the extension head may be recognized automatically by the device and/or the operator may distinguish type of the extension head in user interface 103 of FIG. 1.

The applicator may include at least one RF electrode operating in monopolar, bipolar or multipolar mode and at least one electrode providing electrotherapy operating in monopolar or bipolar mode.

A handheld applicator may include one or more RF electrodes and one or more electrodes providing electrotherapy may be attached to patient body separately from the handheld applicator and/or RF therapy may be located in the patient's body (e.g. in the vagina) in order to provide optimal targeting of treatment energy.

Electrodes as the treatment energy sources may communicate each other no matter on type of the electrodes and/or between the same type of the electrodes.

One or more electrodes may be modularly connected to the applicator to vary the treatment surface, distance between electrodes and provide treatment easier, more effective, faster and/or safer. Electrodes may be controlled individually and/or in group consists of at least two electrodes.

Controlling the electrode by control unit 102 (FIG. 1) includes changing parameters of produced energy: intensity, flux density, time between pulses, shape of signal, phase of individual pulses, type of produced therapy and/or switching on/off individual electrode or electrodes. Controlling of the electrode may be automatic by the device, according treatment protocol and/or may be changed by the operator.

Control unit 102 may be part of one or more applicators 104, individual electrodes and/or may be located out of the applicator.

The applicator and/or electrodes may be created from rigid or at least partly flexible material adaptable to curved patient's body surface.

Transfer of electrical and/or RF energy into the soft tissue and may be based on capacitive, inductive and/or resistive energy transfer.

RF therapy provides electromagnetic field which heats soft tissue. Heat is produced as a resistive loses of electromagnetic energy. RF therapy may be also used for the reason of pre-heating of the soft tissue that may influence soft tissue dielectric parameters as was mentioned above. Pre-heating before during and/or after electrotherapy or other RF therapy treatment may be provided by the same applicator's electrode(s) providing other RF therapy treatment (e.g. removing adipose tissue, heating of collagen fibers etc.) and/or by specific RF electrodes designed for pre-heating purpose.

RF thermal stimulation results in micro inflammatory stimulation of fibroblasts, which produce new collagen (neocollagenesis) and/or new elastin (neoelastogenesis), as well as other cells to enhance dermal structure.

Treatment by electromagnetic field and a spacing object enables create gradients across the soft tissue of the patient. Targeting of a thermal gradient by applied electromagnetic field and continuous but more preferably sequential heating and/or cooling of the patient surface by the spacing object and/or by other above mentioned method may improve the effect of the treatment and minimize health risk.

RF thermal stimulation of adipose tissue is also believed to result in a thermal-mediated stimulation of adipocyte metabolism and augmented activity of lipase-mediated enzymatic degradation of triglycerides into free fatty acids and glycerol. Induction of apoptosis and/or necrosis of fat cells are another proposed mechanism for removing of fat.

RF therapy can be applied to the soft tissue in various manners. The treatment system may use bipolar electrodes, where electrodes alternate between active and return function and where the thermal gradient beneath electrodes is during treatment almost the same. The system may alternatively use monopolar electrodes, where the so called return electrode has larger area than so called active electrode. The thermal gradient beneath the active electrode is therefore higher than beneath the return electrode

A unipolar electrode may also optionally be used. During unipolar energy delivery there is one electrode, no grounding pad, and a large field of RF emitted in an omnidirectional field around a single electrode.

The electromagnetic field used for heating the soft tissue may be a radiofrequency field or microwave field, typically in a range of 0.1 MHz to 25 GHz. Waves of the RF therapy may be delivered preferably in range from 100 kHz to 3 500 kHz or 6 765 to 6 795 kHz or 13 553 to 13 567 kHz or 26 957 kHz to 27 283 kHz or 40.66 to 40.7 MHz or 433.05 to 434.79 MHz or 902 to 928 MHz or 2 400 to 2 500 MHz or 5 725 to 5 875 MHz or 24 to 24.25 GHz or 61 to 61.5 GHz or 122 to 123 GHz or 244 GHz to 246 GHz or optionally at other frequencies as well.

RF electrodes may be in contact with the patient's body and/or may be spaced from the patient's body contact with air gap and/or by spacing object or other material.

Energy flux density of RF therapy is preferably in the range of 0.01 mW·mm⁻² to 10 000 mW·mm⁻², 0.1 mW·mm⁻² to 5 000 mW·mm⁻², or 0.5 mW·mm⁻² to 1 000 mW·mm⁻².

Energy flux density (energy flux density on the electrode surface) of the electromagnetic field in noncontact mode, where electrodes providing RF signal are spaced from the patient body by an air gap may be preferably in range between 0.01 mW·mm-2 and 10 W·mm-2, more preferably in range between 0.01 mW·mm-2 and 1 W·mm-2, most preferably in range between 0.01 mW·mm-2 and 400 mW·mm-2.

Energy flux density of the electromagnetic field in contact mode (including the direct contact of electrodes coated by thin layer of insulator) may be preferably in range between 0.01 mW·mm-2 and 2 000 mW·mm-2, more preferably in range between 0.01 mW·mm-2 and 500 mW·mm-2, most preferably in range between 0.05 mW·mm-2 and 280 mW·mm-2.

Energy flux density of the electromagnetic field in noncontact mode where electrode is spaced from the patient body by spacing object or other material with beneficial dielectric parameters e.g.: bolus filled with water, silicon and/or other materials) may be preferably in range between 0.01 mW·mm-2 and 500 mW·mm-2, more preferably in range between 0.01 mW·mm-2 and 240 mW·mm-2 or even more preferably in the range between 0.01 mW·mm-2 and 60 mW·mm-2 or the most preferably in range between 0.05 mW·mm-2 and 12 mW·mm-2.

The source of RF waves and/or electrotherapy may be at least one electrode. When the only one electrode is applied, the electrode may serve as both the RF and the electrotherapeutic source. The therapies may be applied together, successively or in overlap. The electrode may consist of electrode itself and coating, wherein the coating may not cover the whole surface of electrode.

The soft tissue is heated to 10-70° C. more preferably to 20-60° C., most preferably to 30-50° C.

The main effects of electrotherapy are: analgesic, myorelaxation, iontophoresis, and at least partial muscle stimulation causing at least partial muscle fiber contraction and anti-edematous effect.

Each of these effects may be achieved by one or more types of electrotherapy: galvanic current, pulse direct current and alternating current.

Galvanic current (or “continuous”) is a current that may have constant electric current and/or absolute value of the electric current is in every moment higher than 0. It may be used mostly for iontophoresis, or its trophic stimulation (hyperemic) effect is utilized. At the present invention this current may be often substituted by galvanic intermittent current. In some preferred embodiment galvanic component may be about 95% but due to interruption of the originally continuous intensity the frequency may reach 5-12 kHz, in more preferred embodiment 5-9 kHz, in the most preferred embodiments 5-8 kHz.

The pulse direct current (DC) is of variable intensity but only one polarity. The basic pulse shape may vary. It includes e.g. diadynamics, rectangular, triangular and exponential pulse of one polarity. Depending on the used frequency and intensity it may have stimulatory, tropic, analgesic, myorelaxation, iontophoresis, at least partial muscle contraction and anti-edematous effect and/or other.

Alternating Current (AC) where the basic pulse shape may vary—rectangular, triangular, harmonic sinusoidal, exponential and/or other shapes and/or combination of mentioned above. It can be alternating, symmetric and/or asymmetric. Use of alternating currents in contact electrotherapy implies much lower stress on the tissue under the electrode. For these types of currents the capacitive component of skin resistance is involved, and due to that these currents are very well tolerated by the patients.

AC therapies may be differentiate to five subtypes: TENS, Classic (four-pole) Interference, Two-pole Interference, Isoplanar Interference and Dipole Vector Field. It also exist some specific electrotherapy energy variants and modularity of period, shape of the energy etc.

Due to interferential electrotherapy, different nerves and soft tissue structures by medium frequency may be stimulated preferably in a range of 500 Hz to 12 kHz or in amore preferred embodiment in a range of 500 to 8 kHz, or 500 to 6 kHz, creating pulse envelopes with frequencies for stimulation of the nerves and tissues e.g. sympathetic nerves (0.1-5 Hz), parasympathetic nerves (10-150 Hz), motor nerves (10-50 Hz), smooth muscle (0-10 Hz), sensor nerves (90-100 Hz) nociceptive fibres (90-150 Hz).

Electrotherapy may provide stimulus with currents of frequency in preferred embodiment in the range from 0 Hz to 12 kHz or in more preferred embodiment from 0 Hz to 8 kHz or in the most preferred embodiment in range from 0 Hz to 6 kHz.

Time between two pulses and/or time between two band of pulses (burst) may be variable depend on some function and adjustable to type of therapy and type of the patient.

According to one embodiment an analgesic effects may be achieved. The analgesia is beneficial during the treatment of high dose RF therapy and in order to make therapy more comfortable. Some oversensitive individuals may have uncomfortable and/or painful feelings during the treatment therapy event if the treatment runs within the range of safe threshold limits. If the delivered energy would be in comfortable limits for such oversensitive individuals, treatment therapy would be inefficient. Therefore, the analgesic effect of electrostimulation may be desirable. Another beneficial effect is that if patient feels pain, the patient usually increases muscle tone in this area. Long lasting muscle contraction may cause pain in the muscle part for several days and/or damage of muscle fibers. Long lasting muscle contraction is therefore not only uncomfortable but it also may affect the blood and lymph circulation. Whereas the treatment may be improved by sufficient fluid circulation during and/or after the treatment.

Pain is a multi-factor phenomenon and there are several mechanisms through which the analgesic effect of electrotherapy is achieved.

It is possible to distinguish several pain management approaches. One of them is called gate-control theory based on a premise that the pain is transmitted through a “gate” in substantia gelatinosa in spinal dorsal horn. Stimulation of large-diameter fibers Aβactivates inhibitory spinal interneurons which prevent the passage of information by activated thin Aδ and C nerve fibres to the brain. If signal from activated Aδ and C nerve fibers is not inhibited such signal results in pain in the brain. Another pain theory is pattern theory premises that the pain excitement is transmitted from the peripheral receptor to the CNS in a pattern coded energy and the pain is interpreted by decoding the energy in CNS.

The last pain management theory is called release of endogenous opioids based on the effect of endorphins, enkephalins and dynorphins. The secretion of these three endogenous opioids may be caused of nerve fiber stimulation by low repetition rate in range 5 Hz to 20 Hz or by high repetition rate in range 110 Hz to 150 Hz time-varying magnetic and/or electric field or by the low repetition rate envelope.

Pain is usually simply defined as an unpleasant sense and emotional experience, connected with actual or potential damage of the tissue. We usually distinguish between acute and chronic pain. Acute pain is short-lasting (maximum several days or weeks). It is caused by mechanical damage of the tissue or by a disease, comes immediately after the painful stimulus and subsides after its ending. The intensity of acute pain depends on the intensity of stimulation. On the other hand, chronic pain is long-lasting (more than 3 months) or recurrent. Its intensity does not depend on the intensity of stimulation; emotions particularly play a leading role.

Effects of electrotherapy it is important to understand especially the modulating factors influencing the perception and transfer of the painful stimulus. An analgesic effect may occur by stimulation of type Aβ nerve fibres by frequency 50-150 Hz and/or type C-thin fibers by frequency 2-8 Hz.

For most of analgesic effect it is possible to choose several types of currents e.g. diadynamic current, currents changing in long lasting period, bipolar amplitude modulated medium frequency currents, TENS and/or, other of interferential currents (in range of 0.1-1 kHz). Frequencies of the currents are described above.

A myorelaxation effect may be achieved. Myorelaxation effect causes at least partially decrease the muscle fiber tone. Myorelaxative effect may be beneficial for improving homogeneity of delivered RF therapy and/or faster regeneration of the soft tissue and/or more comfortable therapy also. Long lasting permanent muscle contraction may slower body fluid circulation e.g. lymph and blood circulation, that has crucial therapy effect. Long lasting muscle contraction is also very exhausting. For better results the therapy should be comfortable because the psychological state of the patient influences human metabolism.

In order to provide myorelaxation, the amplitude modulated medium frequency currents with frequency of the pulse envelope in a range of 5-300 Hz or 10-200 Hz or 10-150 Hz may be used. It is also possible to use TENS and/or other.

Muscle fibers stimulation may be achieved, increasing muscle tone, muscle strengthening, restoration of feeling the muscle, relaxation of the musculature and/or stretching musculature.

Muscle fiber stimulation by electrotherapy may be important during and/or as a part of treatment provided RF therapy. Muscle stimulation increases blood flow and lymph circulation. It may improve removing of treated cells and/or prevent of hot spots creation. Moreover internal massage stimulation of adjoining tissues improves homogeneity of tissue and dispersing of the delivered energy. Another beneficial effect is for example during fat removing with the RF therapy. RF therapy may change structure of the fat tissue. The muscle fiber stimulation may provide internal massage, which may be for obese patient more effective than classical massage.

Muscle stimulation may be provided by e.g. intermittent direct currents, alternating currents (medium-frequency and TENS currents), faradic current as a method for multiple stimulation and/or others. Frequency of the currents and/or its envelope is typically in the range from 0.1 Hz to 200 Hz in preferred embodiment or from 0.1 Hz to 150 Hz in more preferred embodiment or from 0.1 to 140 Hz in the most preferred.

Muscle stimulation may be at least partial muscle contraction, e.g.: gluteus maximus, gluteus medius, gluteus minimus, sartorius muscle, rectus femoris muscle, vastus lateralis muscle, vastus intermedius muscle, vastus medialis muscle, biceps femoris muscle, semitendinosus muscle and semimembranosus muscle, pectineus muscle, external obturator muscle, gracilis muscle, adductor longus muscle, adductor brevis muscle and adductor magnus muscle, tensor fasciae latae muscle, latissimus dorsi muscle, abdominal internal oblique muscle, abdominal external oblique muscle, transverse abdominal muscle, pyramidalis muscle, biceps brachii muscle, brachialis muscle, coracobrachialis muscle, triceps brachii muscle, pectoralis muscle, spinal muscles, thoracic muscles. Muscles in pelvic and/or adjacent to pelvic floor may also be stimulated, helping to resolve problems with incontinence, improve sex life and/or restore relaxed muscles after birth.

A trophic effect may be achieved. A trophic effect created by electrotherapy may have beneficial influence on homogeneity, energy dissipation, creating of hot spots and/or other. Trophic effect may eliminate the risk of hyperthermia injury and/or panniculitis, which are possible to occur during RF treatments. It is also believed that a trophic effect also improves the cell metabolism (e.g. fat cell) that may have with delivered RF therapy synergic effect and better result namely for treating of fat tissue, removing of the cellulite.

Since the mechanism of hyperemia in various types of therapies is different, it is necessary to take these mechanisms into account to be able to select a suitable therapy. Generally, galvanization can be recommended. Other recommended frequency may be especially longitudinal (capillary hyperemia, vessel eutonization), low-frequency currents of the frequency 30-60 Hz or 10-100 Hz. The trophic effect may be partly caused by bringing energy into the organism and energy is used by cells (or other structures) for their activity. The trophic hyperemic effect is also usually connected with the analgesic effect.

An anti-edematous effect may be achieved. Anti-edematous effect may be practically connected with hyperemia, vessel eutonisation and higher capillary permeability. Therefore the therapies referred to as trophic are also anti-edematous. This could be beneficial for stimulation of lymph and blood circulation and removing of treated cells during, before and/or after treatment therapy include RF therapy (e.g. fat removing).

Described frequencies are just examples of the most frequently used frequencies in some embodiments. Described ranges of frequencies are not limited. The individual embodiments may be applied to the tissue simultaneously, successively and/or in overlay.

The electrostimulation may be provided in a combined manner where various treatments with various effects may be achieved. As an illustrative example, the electromagnetic stimulation may be dosed in trains where the first train of stimulation may achieve different effect than second or other successive train of stimulation. Therefore, the treatment may provide muscle fibers stimulation followed by relaxation, during continual or pulsed radiofrequency thermal heating.

Absolute value of voltage between the electrotherapy electrodes operated in bipolar, unipolar mode (electric current flow between more than two electrodes) and/or provided to at least one electrotherapy electrode may be in range between 0.8 V and 10 kV; or in range between 1 V and 1 kV; or in range between 1 V and 300 V or in range between 1 V and 100 V.

Current density of electrotherapy for non-galvanic current may be in range between 0.1 mA·cm⁻² and 30 mA·cm⁻², or in range between 0.1 mA·cm⁻² and 10 mA·cm⁻², or in range between 0.1 mA·cm⁻² and 4 mA·cm⁻², or in range between 0.1 mA·cm⁻² and 2 mA·cm⁻²; for galvanic current may be preferably in range between 0.05 mA·cm⁻² and 3 mA·cm⁻², or in range between 0.1 mA·cm⁻² and 1 mA·cm⁻², or in range between 0.01 mA·cm⁻² and 0.5 mA·cm⁻².

Electrostimulation may be provided by monopolar or bipolar mode.

During bipolar electrotherapy mode two or more electrodes may be used. If polarity of at least one electrode has a non-zero value in a group of the electrodes during bipolar mode, the group of the electrodes has to include at least one electrode with opposite polarity value. Absolute values of both electrode polarities may or may not be equal. In bipolar electrostimulation mode stimulating signal passes through the soft tissue between electrodes with opposite polarities.

Distance between two electrodes operating in bipolar mode may be in range between 0.1 cm and 40 cm or in range between 1 cm and 30 cm, or in range between 1 cm and 20 cm.

During monopolar electrotherapy mode stimulating signal may be induced by excitement of action potential by changing polarity of one electrode that change polarization in the nerve fiber and/or neuromuscular plague.

During electrotherapy may be combined bipolar and monopolar electrotherapy mode or may be used just one of them.

A handheld applicator may include one or more electrodes providing electrotherapy. Providing effective electrotherapy e.g. muscle stimulation and/or analgesic with movable one or more electrodes during the treatment may be complicated. In order to provide effective analgesic and/or muscle stimulation treatment after placing applicator's head into contact with the patient's body, applicator may create one or more electric testing pulses provided to the patient's soft tissue.

Testing pulses may have increasing repetition rate, increasing intensity or may be predefined according other criteria in the treatment protocol. Testing pulses may be monitored. Feedback information from testing pulses, measurable values on the electrodes or soft tissue under or between the electrodes e.g. changed impedance of at least part of the soft tissue or changed potential in the soft tissue, may be evaluated and optimal treatment parameters in order to cause physiological effect by electrotherapy (e.g. creating nerve action potential excitation and muscle contraction) may be sets up and electrotherapy may starts.

Testing pulses may be one or more pulses. Testing pulses for actual applicator and/or electrode(s) position may last between several picoseconds to several seconds. Testing pulses may be applied every time applicator change location on the patient's body, target area or soft tissue parameters changed more than is sets up in the treatment protocol. Testing pulses may be also applied with defined time delay which is defined in the treatment protocol.

Testing pulses may be used to automatically choose an area on the patient's body where electrotherapy may be provided and/or may be used for setting optimal parameters for chosen type of applied electrotherapy (e.g. intensity, repetition rate, type of pulse sequence, shape of provided pulses and/or other parameters).

An optimal area on the patient body for electrotherapy may be saved into the device memory and testing pulses may not be provided every time when treated area is the same.

Recognition of the same treated area on the patient's body may recognize by tracing applicator moves and/or by other mechanism.

At least one electrode for electrotherapy may be included in the handheld applicator and at least other one electrode for electrotherapy may be located attached to the patient's body. Electrostimulation according such device embodiment may be based on moving with the applicator according treatment pattern across the patient surface.

Treatment patterns may be based on circular moves, curvilinear moves and/or linear moves creating treatment pattern.

All electrodes providing electrotherapy may be located outside of the handheld applicator in contact with the patient's body. Such electrode may communicate with the applicator and may adjust electrotherapy according to moving with the applicator.

Electrodes providing electrotherapy may be connect to the rest of the device by wire and/or may have its own power supply 101 (e.g. at least one batteries) and also may communicate with the device (control unit 102) wirelessly.

A wireless electrode may include its own power supply (e.g. battery) and may include hardware and/or software equipment in order to be able to communicate with control unit 102 of the device, other electrode(s) and be able to provide treatment. Wireless electrode may be attached to patient's body and provide any type of treatment therapy (e.g. RF therapy and/or electrotherapy) without wire connection with the rest of the device.

Communication, attaching applicator(s) to patient's body, provided treatment patterns and/or other features may be used as described in U.S. Provisional Application No. 62/375,796 incorporated herein by reference.

Placing the stationary electrodes providing electrotherapy may be based on operator experience, by observing physiological effect (e.g. muscle contraction) and/or may be based on impedance changes and/or specific electric potential changes as was described above.

In FIG. 1 is captured one exemplary schematic diagram of a proposed system. The system may comprise power supply 101, control unit 102, user interference 103, one or more sensors 105 and applicator 104 providing RF therapy and/or electrotherapy.

Electrodes that may provide RF therapy and also electrotherapy may be switching between these two types of therapies during one treatment session. If the treatment protocol defines switching between RF therapy and any electrotherapy on one electrode at least once during 20 second provided RF therapy last at least 40%, or 50%, or 70% or 90% of time when the electrode provides any kind of therapy.

Power supply 101 may be managed by control unit 102. Regulation of delivered energy may be controlled by control unit 102. The control unit 102 may also evaluate feedback information from one or more sensors 105, and/or treatment parameters from user interface 103. Control unit 102 may contain one or more cooperating units. Control and cooperation units are elements of the device that has influence on treatment parameters of the therapy (e.g. therapy time, amount of delivered energy, burst timing, frequency of provided energy, intensity of energy, controlling switching on/off different group of electrode/s, shape of the pulses and others).

The user interface may allow the operator to change and/or set up the treatment parameters. Treatment parameters may be set up in the range of safe thresholds (e.g. individually for each therapy). Threshold treatment parameters may be operatively changed depending on therapy and/or detected parameters from the feedback sensors. Safe dosage of the delivered energy and/or dependence of each parameter may be pre-set. Course of treatment may be provided by computer and/or operator. Treatment may be guided manually, automatically and/or semi-automatically where some of the treatment parameters were set up manually. A computer may change inappropriately set up parameters and/or alert the operator.

If treatment parameters are evaluated as safe, therapy may start. It may be possible to adjust parameters of the therapy or add therapy types e.g. galvanic current, pulse direct current and alternating current. Treatment may be time limited and stopped by if values of one or more detected parameters reached their limits e.g. time, time and temperature. Safe thresholds may be dependent on treated body part or target area. The constitution of the treated soft tissue is important. This may be classified by e.g. ultrasound, from the information of backscattered radiofrequency wave.

Treatment therapy may be guided with partially or fully predetermined treatment protocol or without predetermined protocol where the operator may adjust some or all parameters of the treatment. The system may provide information to the control unit about electrode(s) connected and ready to participate in the treatment.

Treatment may be guided automatically without need of an operator. Treatment is guided according a defined treatment protocol. During such treatment feedback information from one or more sensors may be evaluated in control unit 102 and according feedback information treatment parameters may be regulated in order to provide safe treatment.

The device may have one or more sensors 105 providing feedback information in order to improve efficiency of the treatment and minimized health risk. Based on feedback treatment information therapy parameters could be manually or automatically or semi-automatically optimized or therapy could be interrupted (as was mentioned above). The device may contain different types of sensors 105 for monitoring device parameters and/or monitoring of body biological, physical, chemical and/or other parameters (e.g. a reactive sensor; an electrochemical sensor; a biosensor; a biochemical sensor; a temperature sensor; sensor for measuring distance of applicator from the patient surface, from some area of the patient soft tissue and/or from other applicator; a sorption sensor; a pH sensor; a voltage sensor; a detector of moving velocity, gyroscope detecting moves and/or change of position; photo sensor; sensor measuring viscosity; a camera; a sensor measuring fluorescence of the patient surface; a sound detector; a current sensor; sensor for measuring of specific heat capacity of human/animal tissue; sensor for measuring impedance; permittivity; conductivity; susceptibility, value of electric field, magnetic field and/or any suitable sensor or sensors measuring biological parameters and/or combination thereof e.g.: sensor for measuring dermal tensile forces; sensor for measuring the activity of the muscle; a muscle contraction forces; skin elasticity). The device may also include at least one contact sensor for monitoring of applicator and/or electrode or more electrodes contact with body surface.

Each sensor 105 may provide feedback information to control energy delivery and/or other treatment parameters to improve efficiency of a treatment and/or minimized health risk and/or discomfort during the treatment. The treatment therapy parameters may be manually or automatically or semi-automatically optimized based on feedback information. If the treatment parameters are evaluated as not-safe, the treatment maybe stopped or the values treatment parameters may be changed.

Treatment therapy may be guided with partially or fully predetermined treatment protocol or without predetermined treatment protocol. Result of this is that the treatment may be carried automatically (allowing treatment without operator), semi-automatically and/or by operator. Operator may set up and/or adjust any parameter of treatment therapy before and/or during the treatment.

The applicator may contain a suction unit to create negative pressure and may be attached to patient's body. The applicator may contain plug-in connector for connecting one or more electrodes.

At least one spacing object may be provided between the applicator and patient's skin surface. A spacing object is shown in FIG. 3. Spacing object 1 may improve transfer of electromagnetic field into the soft tissue. This could be provided by the spacing object itself and/or filler inside of the spacing object and/or thanks to design of the object. Various materials having suitable dielectric constant, density and/or other parameters may be used in order to prevent backscattering of the electromagnetic wave and improve transfer of electromagnetic wave to the soft tissue and improve effectiveness of the treatment. Backscattering may occur at the interface of the materials with different physical parameters, analogous to optical phenomenon at the interface of different refractive indexes.

Inner space of the spacing object 1 may be separated or partly separated into one or more chambers 4a-4d by walls 5a-5c. Each chamber may include one or more cells which may be provide optimal ducting for the flowing substance and/or which may strengthen the walls of chamber in order to preserve the shape of the chamber and object. Each part of the spacing object inner space may have different filler and therefore function. Filling of the inner space of the spacing object 1 may be done during the manufacturing process. According to another embodiment the inner space may be filled and/or circulated during the therapy through one or more inlet/outlet valves 6a-6d. Changing and/or removing of the inner substance of the object may be provided through the inlet/outlet valve 6a-6d also.

The spacing object 1 and/or filler inside may have advantageous dielectric constants (permittivity, permeability, conductivity) and/or other parameters and constants (thermal conductivity, specific heat capacity . . . etc.). and may be used as focusing element, absorbing element, polarizing element, dispersing element, transmitting element, massaging element, reflecting element of backscattered waves, for transfer electromagnetic wave, cooler, heater and/or creator of thermal gradient in the soft tissue of the patient

Filler of the spacing object may be gaseous, liquid and/or from solid material. Spacing object may be composed of any kind of ceramics, plastic material, rubber, textile material, metal, polymeric materials and/or other material that improve any therapy parameter/s. In some embodiment may be important to choose material and/or construction of the object to provide stable form and/or shape of the spacing object. Spacing object may be flexible and/or rigid and may imitate curves of the body contour.

Filler of the spacing object may provide polarization and/or reflection and/or may focus delivered electromagnetic energy and/or may be used as a filter of electromagnetic wave and/or may adjust orientation of the wave vector of the electromagnetic wave as was mentioned below. Polarization of the electromagnetic wave has different impact on different molecules and environments, so polarization may influence absorption, dispersion, penetration, targeting and/or reflection of electromagnetic wave. Polarization of the electromagnetic wave may be created by anisotropic arrangement of dielectric films (e.g. by poly(vinyl alcohol) doped by iodine or other substances based on dichroic polarizers principle) and/or by principle of the phase retardation plate and/or by material and/or geometry of the antenna. Some polarization and reflection element may have crucial influence to prevent creating hot spots due to changing of the orientation of the wave vector end selective modification of the component of the electromagnetic wave.

Treatment by electromagnetic field and spacing object enabling changing of temperature and/or other parameters (permittivity, permeability, conductivity and/or their parameters) and/or its one or more component may create temperature gradients across the soft tissue of the patient. This is important because tissue dielectric parameters (e.g. impedance, conductivity and/or other related dielectric parameters) change with different temperature and frequency of applied electromagnetic waves. Targeting of thermal gradient by applied electromagnetic field and continuous but more preferably sequential heating and/or cooling of the patient surface by the spacing object may improve the effect of the treatment and minimize health risk.

Spacing object 1 may prevent harmful influence of edge effects in connection with delivering energy by electrodes. Preventing the edge effect is achieved via dispersion of the electromagnetic energy, cooling and/or changing orientation of the Poyting's vector of the electromagnetic field in the object. Object 1 may also cause the higher homogeneity of the electromagnetic field.

Cooling or heating of tissue may be provided by a spacing object filled with a suitable substance (mostly liquid or gaseous substance e.g. water, water doped NaCl, ethanol, air, N2, CO2, air and others). The parameters of the substance such as temperature, viscosity, flow etc. may be monitored by one or more sensors (e.g. temperature and/or viscosity sensors and/or sensor measure inducted currents or chemical changes of the substance). Monitored parameters may provide feedback information to control unit for regulate flow of the substance through the spacing object. Object 1 may be extended by complementary connection of other one or more chambers. Extension of spacing object may share filler or may have different function e.g. protection of different area from overheating, over-radiation and/or other influences, different cooling program, modulation of the delivered energy to the patient (polarizing, filtering etc.) and/or other functions (focusing etc.).

Thermal gradients are represented in FIG. 2. In some embodiment it is possible to create a thermal gradient by heating and/or cooling surface of the patient skin with highest or lowest temperature on the skin surface FIG. 2a) and/or it is possible to create temperature gradient with highest or lowest temperature beneath the surface of the soft tissue FIG. 2b). The effect described at FIG. 2b) may be provided by sequential heating/cooling of the patient surface and/or by focusing of delivered electromagnetic and/or thermal energy.

In one method, the patient's surface (epidermis) temperature may be maintained in a range between 20° C. to 44° C., or in range between 30° C. to 44° C., or in range between 30° C. to 40° C. Such treatment method may maintain lower temperature of the patient's epidermis than is temperature in the treated patient's adipose tissue.

The increase of the temperature in the dermal and the sub dermal tissues also affects the triple-helix structure of collagen fibers contained in such tissues. This may result in remodeling and rejuvenation of collagen, increase of skin density and dermal thickening

Spacing 1 located between the patient's soft tissue surface and the treatment energy source may have specific properties and influence parameters of treatment energy as described in U.S. Provisional Application No. 62/331,072, incorporated herein by reference.

In one aspect the device is designed as a belt that may be modularly modified by adding and/or removing one or more part of the device (e.g.: applicators, treatment units and/or others) before and/or during the treatment. The belt is designed to fit to any type and size of treated patient body area. In one preferred embodiment the belt is in touch with patient's body surface matches the curvature of patient's body. Size of the belt may be variable by stretching and/or by plugging and/or removing of one or more parts of the belt.

In another embodiment the belt may be considered as a block of at least two treatment applicators attached in optimal working distance to the patient's body. Optimal working distance may be any distance from the skin of the patient or in direct contact with the skin of the patient. Applicators may have various sizes and shapes.

One or more treatment applicators may communicate with each other and/or with one or more control units via cables, wireless and/or via connection through the belt. Transfer of the information through the cable may be based on conductive mechanism and/or via mechanism used in an optical fibers and/or as a wave guide provide transfer of different types of the energy (e.g.: sonic, electric, electro-magnetic, pressure by liquid or gas substances and/or other). The communication may provide information about locations and/or type of the applicator/applicators, treatment protocol, treatment parameters and other information. In some embodiments it is possible to provide treatment between multiple applicators, (e.g.: multiple monopolar, unipolar and/or multipolar apparatus) or focusing of some energy sources (e.g.: RF, ultrasound, light), that may improve some treatment (e.g.: removing of fatty tissue).

Large scale modularity by changing hardware and/or treatment pattern by placing of at least one applicator and/or other parts of the device, (e.g.: adding, removing, reorganization and/or changing of spacing between of at least one applicator and/or other part of the device) before and/or during the treatment allows actualization of the device and prevents obsolescence of the device. The belt may or may not contain supporting matrix. The belt may be flexible, whole or partly elastic and may be adapted to patient surface of arbitrary size and shape. This characteristic helps to provide optimal energy transfer from an applicator to the patient soft tissue. Improved contact with the patient skin or surface may decrease or prevent an edge effect, backscattering of delivered energy and/or provides better conditions for collecting feedback information. Supporting matrix may also be connected to upper side of the applicator, keep one or more applicators in touch with the patient surface, and not be in touch with the patient.

A treatment pattern creates pattern by switching between applicators and/or treatment elements providing one or more types of the therapy across the patient surface. A treatment pattern may include different types of switching sequences, and also include at least one of: a specific treatment therapy is applied; a selection of applicators and/or treatment elements applying specific treatments; timing of the applied therapy; the distance between at least two applicators; duration of the treatment therapy applied; body location where the treatment therapy applied; cycle of applying one or more specific treatment therapies.

A treatment pattern may provide information about applying one or more types of the treatment therapies and their manner (e.g.: simultaneous, sequential and/or applying of one or more treatment therapies with some overlay). A treatment pattern may simulate moving of the one or more applicators guided by an operator by switching between applicators and/or treatment elements of one or more applicators and/or one or more treatment therapies. Simulated moves may be circular, zig-zag, spiral, other geometrical pattern, scanning and/or other pattern that may be created by moving the applicator guided by operator. A treatment pattern may also be used for scanning of the patient soft tissue.

A hardware pattern is a composition of the device and placement of the parts of the device. A hardware pattern also includes placement of the applicators which is in some embodiments not limited (e.g.: in the supporting matrix, on the patient surface etc.), placement of the treatment unit, and/or other devices adjacent/at working distance to the soft tissue (which includes direct, indirect or no contact).

The belt may be a block of more than one applicator with and/or without supporting matrix and/or with or without spacing object. Location of individual applicators (optionally including different types of applicators) creates a hardware pattern. A computer and/or operator may choose several treatment therapies and procedures that can work simultaneously, with some overlay and/or sequentially during the treatment time and/or adjust one or more parameters of the procedure before and/or during the treatment.

According another embodiment applicator may also create treatment pattern by switching on/off of some treatment elements included in the applicator. In FIG. 6 element number 62 is the applicator's active surface with multiple treatment elements 63. Applicator may contain different shapes of the treatment elements and number of the treatment elements in one applicator is not limited. Spacing between treatment elements may be different across the applicator's active surface. Treatment elements may also be movable during the treatment and/or spacing between treatment elements may also be variable during the time of the treatment. Switching on/off of some treatment elements during the time may be defined by protocol of the treatment procedure and may create multiple different types of the treatment pattern that may change during one treatment procedure. All of the treatment elements in one applicator may provide one therapy or in some other embodiment of the applicator, treatment elements of one applicator may provide different types of the therapies. Treatment pattern created by one applicator may also be created by moving of one or more treatment elements included in the applicator.

In another embodiment parts of the device may be attached to patient body and/or to other parts of the device by a sticky layer between contact surfaces and/or by high adhesive layer applied on one or more contacts surfaces. Contact between parts of the device and/or between one or more parts of the device and patient surface may be provided by gravitational force, by high roughness of the contact surfaces, by electric forces, by magnetic forces, by rails, by elastic, partially elastic and/or non-elastic stripes, by Lace, by Velcro, zipper, by tacks, by creating lower air pressure between contact surfaces by suction mechanism, by interaction between polar and/or non-polar group of the contact surface, by fastening mechanism described below and/or by other physical, chemical, mechanical interaction between parts of the device and/or between patient surface. Some parts of the device may also be connected to each other by individual elements of a scaffold.

The belt may include supporting matrix that can hold one or more applicators and/or its treatment elements in touch with patient's body surface and/or it may also hold one or more applicators at an optimal working distance from the patient surface. The patient surface is typically the skin of the patient. However, the patient body surface may alternatively be some spacing object e.g.: clothing worn over the skin, a sheet, pad or other thin (0.1-2 mm) covering over the skin, and/or a thicker spacing object.

Spacing object may be located between any parts of the device and/or between patient and some parts of the device. Because of mechanical, structural, physical and/or chemical properties of this spacing object, spacing object may provide and/or improve attachment of any parts of the device and/or some parts of the device and patient body surface together.

The belt may encircle the patient's torso and/or limb, and optionally including a fastening mechanism that may have various embodiments and may help to fixe applicator(s) to supporting matrix.

The supporting matrix may include fastening mechanism for attaching applicators to supporting matrix, for attaching some parts of the supporting matrix together, for attaching supporting matrix to spacing object and/or to patient's body and/or for attaching other parts of the device together. Fastening mechanism may also provide attaching one or more applicators to spacing object and/or to patient's body. Fastening mechanism may be e.g.: snap, clamp, some rails, adhesive polymer, pre-prepared holes, Velcro, zipper and/or other implemented fastening mechanisms and/or snap mechanisms) and/or may be provided by electromagnetic field, by magnetic field, by pressure lower than atmospheric pressure, by adhesive material, by interaction of chemical bounding interaction (interaction between polar and nonpolar groups) and/or others methods similar to method described above and/or other mechanisms.

The supporting matrix may contain fastening mechanism which may be permanent or removable from the supporting matrix. Position of the fastening mechanism may be variable and/or fixed before, during and/or after treatment. Fastening mechanisms may have various spacing between each other, different shapes, sizes and/or mechanism, how to be attached some of the applicators and/or how to be attached to supporting matrix and/or how to provide other types of the connection described above (based on physical, chemical and/or mechanical interaction). Fastening mechanism may be attached to supporting matrix and/or to arbitrary other part of the device at arbitrary location by similar manner as it is described above—attachment of the applicator to patient's body and/or to spacing object. Fastening mechanism may be also attached to supporting matrix and/or other parts of the device by mechanical connection.

One applicator may be attached across multiple fastening mechanisms (e.g.: applicators provide mechanical massage with movable and/or static element, RF therapy and/or other applicators provided different and/or multiple types of the therapies). It is not necessary that supporting matrix encircling whole patient torso and/or limb etc. In some embodiments applicators may be attached to both sides of the supporting matrix.

The belt may comprise applicators applied on the patient surface and/or a thin and/or a thicker spacing object and fixed by textile, polymeric and/or other strips. The strips may be at least partially elastic. The applicator(s) may be attached at the right working distance by one or more stripes located in front and/or back side of the applicator. Suitable elastic materials are elastomers or also elastic fabrics. The elastic belt material also adapts to respiratory movements and/or other movement of the patient.

The applicators may have different sizes and shapes, to improve treatment results and/or flexibility of the belt. Each applicator may be fixed to supporting matrix at arbitrary position e.g.: by inserting an applicator into the pocket in the support matrix, by Velcro and loop tape, by one or more magnets, by tacks or fasteners, fastening straps and/or by other fastening mechanism 51 as may be seen in FIG. 5 and/or by other manner described above.

The supporting matrix may be attached to the patient by different way described above and/or by encircling patient body and connect some parts of supporting matrix to each other and/or by external positive pressure acting on supporting matrix in direction to the patient surface. Supporting matrix may be designed as one or combination of more pieces where at least one piece has elastic properties. Supporting matrix may be designed as elastic clothes (e.g. elastic trousers, sleeves, shirt etc.) to fix one or more applicators at optimal location on the patient body and/or at optimal working distance with the patient body at the right position. Supporting matrix may be fixed at specific body location of the patient body and/or may be movable along the patient body.

Some parts of the supporting matrix may be created of flexible, elastic and/or rigid materials e.g.: polymeric materials, ceramics, textile materials, conductive parts and/or other materials. The supporting matrix may be at least partially flexible and/or elastic to provide improved contact with the patient body and/or set appropriate working distance for one or more applicators.

The support matrix may also contain apertures of different sizes and shapes. The support matrix may contain cooling/heating elements, massage elements that may move across the belt area and/or one or more sensors. In some embodiment mechanism for moving with attached applicators and/or other part of the belt may be provided according defined pattern. A track or path for the applicator may be created by rails (e.g.: applicator may be moved along them by mechanical forces based on pressure and/or tensile forces) and/or by a path created from conductive elements and applicators may be moved along them by electric, magnetic and/or electromagnetic forces.

Moving of one or more applicators and/or other parts of the belt across the patient body may also be provided by moving of the supporting matrix. Move of the supporting matrix may be provided by expansion and/or shrinking of some parts of the supporting matrix and/or by moving with the supporting matrix along the spacing object (e.g. by mechanic, electric, magnetic and/or combination of these forces) and/or by attaching supporting matrix to an another movable parts of the device (e.g.: mechanical arm, construction on rails).

The supporting matrix may have several embodiments. One of such embodiment is depicted in FIG. 5 where the support matrix consists of guiding scaffold 52, with the one or more applicators 53 attachable to the scaffold 52 by fastening mechanism 51. The supporting matrix may include conductive parts that may provide communication between applicators, communication between applicators and central control unit and/or communication between at least one applicator and treatment unit. Conductive parts in the supporting matrix may also provide power supply to the applicator(s). Applicator may also include one or more rechargeable batteries as a source of energy. These batteries may be recharged through the supporting matrix and/or through the spacing object.

In another embodiment belt may be a flexible textile and/or polymeric sheet. This sheet may contain conductive elements that may provide communication, power supply, determine of one or more applicators location and type, contact with the supporting matrix and/or patient surface, provide information about treatment protocol as was mentioned above and/or other features. In some embodiments supporting matrix may also include cooling and/or heating components. This embodiment of the belt may also include spacing object.

As a result, so-called plug and play methods may be used to modify hardware pattern of the applicators attached to patient and/or to supporting matrix (sorting and/or choosing of the applicators). This plug and play method provides a large scale of modularity. The supporting matrix also may recognize which applicator is positioned or fixed in which slot in the supporting matrix and the control unit may assign and/or accept predefined treatment protocols. Recognition of the applicator may also be provided by one or more central control units and/or by any other one or more control units. Localization of the applicator may be provided by some specific sensors described below.

Several applicators may cooperate with each other. FIG. 4 describes cooperation of multiple applicators 41a, 41b, 41c that may provide some treatment therapy (e.g. multipolar RF therapy symbolized by field lines 42 and/or others) to the patient 43. Cooperation of multiple units may be used for different therapies (e.g.: RF, ultrasound, light, massage, cooling/heating, electrotherapy, magneto-therapy and/or other therapies) in order to provide bipolar and/or multipolar treatment across large patient area, better targeting of delivered therapy, better focusing of delivered signal, creating of some gradient in the soft tissue (e.g. thermal gradient, etc.), better homogeneity of provided therapy across large patient area and/or volume of the soft tissue.

Cooperation of multiple applicators and/or treatment elements may enlarge treatment variability (e.g. treatment depth, focusing), since the electrode of each applicator and/or treatment element may represents one pole of multipolar treatment.

RF energy and electrostimulation may help with drug delivery through the skin of the patient. The present system and method may also involve an application of the substance and/or mixture of substances causing a physiological change in the body of the patient. In addition, the mixture (e.g. green tea extract) may include not yet characterized substances. Application of the substance and/or mixture of the substances may provide patient with a more comfort and/or improve the performance of the system.

In one embodiment, the substance may modulate normal metabolism and/or basal metabolism rate of the patient's body. It may provide acceleration to the metabolism related to the apoptotic cells. Such substances may include alkaloids (e.g. xanthines), antithyroid agents, metformin, octreotide and a like.

Substances may modulate efferocytosis, which is the process by which dying cells are removed by phagocytic cells. This may provide acceleration and improvement in the dead cells removal. Such substance may include prostaglandins and their analogues, modified lipids (e.g. lysophosphatidylserine, lipoxins, resolvins, protectins and/or maresins), lipoprotein lipase inhibitors, nitric oxide secretion stimulators, alkaloids (e.g. xanthines), aspirin, antioxidants (e.g. ascorbic acid), derivatives of carbohydrates and a like.

Delivered substances may modulate lipolysis rate. In case of application of electromagnetic energy to the adipocytes it may provide another way of removal of the adipose cells, which may be independent from the treatment method. Such substances may include terpens (e.g. forskolin), catecholamins, hormons (e.g. leptin, growth hormone and/or testosterone), alkaloids (e.g. synephrin), phosphodiesterase inhibitors (e.g. xanthins), polyphenols, peptides (e.g. natriuretic peptides), amino acids and a like.

Delivered substances may modulate hydration of the patient. Such substances and/or mixtures may include xanthines, lactated Ringer's solution, physiological saline solution and a like.

Delivered substances may modulate circulatory system of the patient. This may provide the higher rate of blood circulation, which may result in faster cooling rate of the skin. Such substances may include catecholamines, alkaloids (e.g. xanthins), flavanols and a like.

Delivered substances may induce the reversible decrease or absence of sensation in the specific part of the patient's body. This may provide a certain level of comfort to heat-sensitive patient. Such substances may include lidocaine, benzocaine, menthol and a like.

Delivered substances may shield the electromagnetic radiation from the patient's body. This effect may be used for protection of sensitive parts of the human body. Such substances may include mixture containing metal nanoparticles, mixture containing polymer particles and a like.

Delivered substances may modulate the effect the electromagnetic radiation applied on the patient's body. This may accelerate removal of the desired tissue, for example by heating of the tissue and/or increasing the effect of the applied radiations. Such substances may include carotens, chlorophylls, flavanols and a like.

Delivered substances may be used singularly or in various combinations with at least one suitable substance, which may be not listed as an example. For example, lidocain providing a local anesthesia may be combined with prilocaine to provide improved effect. The substance and/or mixture of the substances may be administered in different time related to the tissue treatment. It may be administered before the treatment, during the treatment and after the treatment.

Delivered substances may be administered in order of seconds, hours or even days to accumulate in the desired tissue. The subsequent application of the electromagnetic radiation may modulate the action of the accumulated substance and/or be modulated by the action of the substance. According the example of this embodiment, the chromophore may be accumulated in the treated tissue, such as adipocytes, before the treatment. Chromophore may then absorb electromagnetic radiation and heat the tissue nearby. Presented active agents or in this text called substances may have significant influence to treatment therapy as is described in U.S. Provisional Application No. 62/331,060 incorporated herein by reference.

Delivered substances may be applied to the particular part of the tissue, which is not a target of the therapy. It may change the blood perfusion, conductivity, hydration and other characteristics of the non-targeted tissue. In another embodiment, the targeted tissue may be adipose tissue and the non-targeted tissue may be any other soft tissue.

Substances mentioned above may by delivered to patient's body before, during and/or after treatment session.

The present methods and devices provide for improving skin viability, skin and body rejuvenation, skin tightening, scar removing, spider veins removing, restoring and restructuring collagen in the soft tissue body shaping (e.g. butt lifting, breast lifting etc.), body contouring, circumferential reduction, cellulite removing, adipose tissue reduction, adipose tissue removing, muscle relaxation, relaxation of muscle tone, muscle building, muscle strengthening, treating and stimulating pelvic floor tissue and adjacent muscles, remodeling of outer part of genitals treat sexual dysfunctions, treat or reduce incontinence problems, accelerate neocolagenesis, improving blood flow, lymph flow, stimulation of lymph nodes, movement of the vessels, bruising removing, reduce swelling, enhancing vitamin D metabolism, restoring nerve signal transfer, accelerate body metabolism, accelerate cell metabolism, pigmentation disorders, tattoos removal, stress relive, micro-dermal abrasion, hair removal, shortening of recovery time after injury and/or other skin and body affliction using application of RF energy and electrical stimulation to the soft tissue.

Special treatment may be targeted to areas near human genitals (e.g.: improve pigment homogeneity, downsizing of pubic lips and/or other target area) and/or treatment may be targeted inside of the human cavities as anus or vagina in order to treat pelvic floor and/or other areas inside the patient's body.

During treatment of human cavities at least part of the applicator and/or treatment energy source may be inserted inside of human cavity and may be there placed stationary or may be moved with circular and/or linear moves according any Cartesian coordinate.

According other embodiments an applicator is used for treating of human cavities and it may also be designed to treat outer side of genitals simultaneously with treating inside area of human cavity.

Part of an applicator for human cavity treatment may have a changeable volume. Such part may be inflated, deflated and/or stretch in order to provide optimal contact with soft tissue in the human cavity and so provide optimal energy transfer from at least one treatment energy source to the patient's soft tissue. Changing volume of at least part of the applicator may be by inflating/deflating such part with air or liquid and/or such volume changing applicator's part may change its volume and/or shape by properties of the material based on humidity or temperature changes and/or by changing geometry inside of the applicator caused by electromotor.

Treatment energy source providing electrotherapy in human cavity may be located on or near the applicator's surface and treatment energy source providing RF therapy may be located inside and or on the surface of the applicator.

An applicator and treatment effects, treated tissues and/or other features are described in U.S. patent application Ser. No. 15/478,943, incorporated herein by reference.

One treatment session may last between 1 minute to 120 minutes, or between 5 minutes to 40 minutes, or between 10 minutes to 30 minutes or between 10 to 20 minutes

Recommended delay between two treatment sessions may be influence by provided intensities of delivered energy to the patient's body, provided therapies and/or provided active substances. Recommended delay between two treatment sessions may be in range 1 hour to 20 days, or in range 8 hours to 14 days, or in range 24 hours to 7 days.

The device and method may be used for treating patients for patients with BMI in range between 18 to 40 and/or with subcutaneous adipose tissue layer thickness in range between 1 mm to 15 cm, or between 3 mm to 7 cm, or between 3 mm to 3 cm.

Thus, novel methods and devices have been shown and described. Various changes and substitutions may of course be made without departing from the spirit and scope of the invention. The invention, therefore, should not be limited, except by the following claims, and their equivalents.

Claims

1. A device for providing treatment by radiofrequency field and electric current to a patient, the device comprising: a first applicator configured to be in a stationary position during the treatment and to be attached to a body part of the patient by a flexible belt or by an adhesive material, the first applicator comprising: a radiofrequency electrode configured to provide a radiofrequency field to heat tissue within the body part of the patient;a second applicator, comprising: an electrotherapy electrode configured to provide electric current to stimulate a muscle of the body part of the patient; anda control unit configured to: control the radiofrequency field; andcontrol the electric current.

2. The device of claim 1, further comprising a substance configured to be applied on the body part under the first applicator or the second applicator and to cause a physiological change in the body part of the patient during the treatment.

3. The device of claim 2, wherein the substance is configured to provide hydration of the body part.

4. The device of claim 1, wherein the second applicator is configured to be attached to the body part of the patient, and wherein the electrotherapy electrode is configured to be in contact with the body part, when the second applicator is attached to the body part.

5. The device of claim 4, wherein the second applicator is configured to be attached to the body part of the patient by a second flexible belt or by a second adhesive material.

6. The device of claim 4, wherein the electric current is provided within a series of envelopes, and wherein the envelopes repeat with a frequency in a range of 0.1 Hz to 140 Hz.

7. The device of claim 4, wherein the radiofrequency electrode is one of one or more bipolar radiofrequency electrodes, and wherein the radiofrequency field has a frequency in a range of 0.1 MHz to 25 GHz.

8. The device of claim 4, wherein the electric current has a current density in a range of 0.1 mA/cm2 to 30 mA/cm2, wherein the stimulation of the muscle causes a contraction of the muscle, andwherein the radiofrequency field has an energy flux density on a surface of the radiofrequency electrode in a range of 0.5 mW/mm2 to 1 W/mm2.

9. A device for providing treatment by radiofrequency field and electric current to a patient, the device comprising: a first applicator configured to provide a radiofrequency field, the first applicator comprising: a radiofrequency electrode configured to provide the radiofrequency field having a frequency in a range of 0.1 MHz to 25 GHz to a body part of the patient to heat the body part of the patient;a second applicator configured to provide electric current, the second applicator comprising: an electrotherapy electrode located on an outer side of the second applicator and configured to be placed in contact with the body part of the patient,wherein the electrotherapy electrode is configured to provide the electric current having a frequency in a range of 0 Hz to 12 kHz to the body part to stimulate a muscle of the body part of the patient;a control unit configured to control the radiofrequency field and the electric current based on one or more treatment protocols; anda user interface configured to allow an operator of the device to select the one or more treatment protocols.

10. The device of claim 9, wherein the electric current is pulsed electric current having a frequency of pulses in a range of 0.1 Hz to 200 Hz and a current density in a range of 0.1 mA/cm2 to 30 mA/cm2.

11. The device of claim 9, wherein the control unit is configured to recognize the first applicator coupled to the control unit, wherein the control unit is configured to recognize the second applicator coupled to the control unit, andwherein the control unit is configured to provide information about the coupling of the first applicator or the second applicator with the control unit to the user interface and to provide the one or more treatment protocols to be selected by the operator based on this information.

12. The device of claim 9, wherein the first applicator and the second applicator are configured to be attached to the body part of the patient by an adhesive material.

13. The device of claim 9, wherein the first applicator and the second applicator are configured to be attached to the body part of the patient by a flexible belt, and wherein the body part comprises an abdomen, a buttock, saddlebags, or an arm.

14. The device of claim 13, wherein the control unit is configured to provide the radiofrequency field by the first applicator before or after providing the electric current by the second applicator.

15. The device of claim 9, further comprising a sensor configured to provide feedback information indicating an impedance of the body part.

16. A device for providing treatment by radiofrequency field and electric current to a patient, the device comprising: an applicator configured to be attached to a body part of the patient by an adhesive material or by a belt, comprising: a first electrode located on an outer side of the applicator and configured to: be placed in contact with the body part of the patient during the treatment;provide a radiofrequency field having a frequency in a range of 0.1 MHz to 25 GHz to heat the body part of the patient; andprovide electric current to stimulate a muscle of the body part of the patient; anda control unit configured to control the radiofrequency field and the electric current.

17. The device of claim 16, wherein the control unit is configured to control the radiofrequency field to heat the body part to a temperature in a range of 30° C. to 50° C.

18. The device of claim 16, further comprising a substance configured to be applied on the body part under the applicator and to provide hydration of the body part.

19. The device of claim 16, wherein the applicator is configured to be attached to the body part of the patient by the adhesive material comprising an adhesive polymer.

20. The device of claim 16, further comprising the belt, wherein the belt is flexible, andwherein the applicator is configured to be in a stationary position during the treatment and to be attached to the body part of the patient by the belt.

21. The device of claim 16, wherein the first electrode is configured to change between providing the radiofrequency field and the electric current during the same treatment, wherein the electric current is pulsed electric current having a current density in a range of 0.1 mA/cm2 to 30 mA/cm2 and a pulse shape of rectangular, triangular, or exponential, andwherein a voltage provided to the first electrode when providing the electric current is in a range of 1 V to 100 V.

22. The device of claim 16, wherein the applicator further comprises: a second electrode configured to provide the electric current to the body part of the patient and configured to have opposite polarity than the first electrode when providing the electric current.

23. The device of claim 22, wherein a distance between the first electrode and the second electrode is in a range of 0.1 cm to 40 cm.

24. A device for providing treatment by radiofrequency field and electric current to a patient, the device comprising: an applicator, comprising: a radiofrequency electrode configured to provide a radiofrequency field having a frequency in a range of 0.1 MHz to 25 GHz to heat a body part of the patient; andan electrotherapy electrode located on an outer side of the applicator and configured to: be placed in contact with the body part of the patient; andprovide electric current to stimulate a muscle of the body part of the patient,wherein a distance between the radiofrequency electrode and the electrotherapy electrode is in a range of 0.1 cm to 40 cm; anda control unit configured to control the radiofrequency field and the electric current.

25. The device of claim 24, wherein the control unit is configured to provide a series of pulses of the electric current, and wherein the series of pulses repeat with a frequency in a range of 0.1 Hz to 140 Hz.

26. The device of claim 24, wherein the radiofrequency field is configured to heat the body part to a temperature in a range of 30° C. to 50° C.

27. The device of claim 24, further comprising a substance configured to be applied on the body part of the patient under the applicator, wherein the substance causes a physiological change in the body part during the treatment.

28. The device of claim 27, wherein the substance is configured to provide hydration of the body part.

29. The device of claim 24, wherein the electric current has a current density in a range of range of 0.1 mA/cm2 and 30 mA/cm2, wherein a voltage provided to the electrotherapy electrode when providing the electric current is in a range of 1 V to 300 V,wherein the stimulation of the muscle causes a contraction of the muscle, andwherein the radiofrequency field has an energy flux density on a surface of the radiofrequency electrode in a range of 0.01 mW/mm2 to 10 W/mm2.

30. The device of claim 29, wherein the muscle comprises at least one of gluteus maximus, gluteus medius, gluteus minimus, sartorius muscle, rectus femoris muscle, vastus lateralis muscle, vastus intermedius muscle, vastus medialis muscle, biceps femoris muscle, semitendinosus muscle and semimembranosus muscle, pectineus muscle, external obturator muscle, gracilis muscle, adductor longus muscle, adductor brevis muscle and adductor magnus muscle, tensor fasciae latae muscle, latissimus dorsi muscle, abdominal internal oblique muscle, abdominal external oblique muscle, transverse abdominal muscle, pyramidalis muscle, biceps brachii muscle, brachialis muscle, coracobrachialis muscle, triceps brachii muscle, pectoralis muscle, spinal muscles, or thoracic muscles.