BR102023027618A2 - SYSTEMS INCLUDING PORTABLE DEVICES TO DELIVER MICROCURRENTS AND/OR KINESIOLOGICAL SCULPTURE, USEFUL IN SKIN CARE - Google Patents

Abstract

“SYSTEMS INCLUDING PORTABLE DEVICES FOR DELIVERING MICROCURRENTS AND/OR KINESIOLOGICAL SCULPTURE USEFUL IN SKIN CARE” A system advantageously includes a portable device having a body with two pairs of electrodes mounted on or carried by respective arms extending from the portable body, wherein at least one pair of arms is movable (e.g., pivotable, rotatable) relative to the body and therefore relative to the other pair of arms. The movable arms can be tilted toward an unrotated position or orientation, applying a tension to body tissue via the movable arms when rotated away from the unrotated position or orientation. The system optionally includes circuitry integral to the handheld device, or integral to a console to which the handheld device is coupled, the apparatus being operable to deliver microcurrent signals through two separate channels and through interferential signals between the two separate channels, to facilitate the application of kinesiology facial sculpting in combination with the delivery of microcurrent signals, which may be employed in cosmetic applications.

Description

FIELD

[001] This disclosure relates generally to skin care and cosmetic treatments and in particular to systems that include wearable devices and treatments that deliver microcurrents through skin and muscle tissue and/or that also have the ability to provide kinesiological sculpting by stretching or tensing and/or compressing or pinching body tissue (e.g., skin and muscles, including tendons), for example by lengthening and/or shortening body tissue.

BACKGROUND DESCRIPTION OF RELATED TECHNIQUE

[002] Microcurrent technology for cosmetic use is based on the same mechanism of action as medical microcurrent, which triggers a massive increase in adenosine triphosphate (ATP) through stimulation of mitochondria. As with medical microcurrent, the availability of up to 500% more ATP accelerates the healing properties of injured or damaged tissues and muscles and also helps to maximize the condition of existing tissues and muscles. As people age, they experience a significant reduction in collagen and elastin, particularly in the face and neck, which leads to the appearance of fine lines, wrinkles and sagging skin. People also experience muscle atrophy, which further deteriorates their aesthetic visual appearance. This aging process is directly related to the depreciation of mitochondrial activity, which ultimately reduces the availability of ATP to the skin and muscles, for example, of the face and neck. Age typically leads to the body's inability to maintain real-time maintenance requirements due to the lack of ATP. The damage that builds up is what we perceive as the visual effects of aging.

BRIEF SUMMARY

[003] Applicant has pioneered a microcurrent technology used to provide cosmetic services and provided under the trade name Bio-Therapeutic. For example, Bio-Therapeutic offers two microcurrent facial toning systems, namely the Bio-Ultimate® Platinum Microcurrent Facial Toning System and the bt-nano® Microcurrent Facial Toning System. Each of the microcurrent facial toning systems includes a console and two ergonomic hand-held probes (i.e., Azul™ Ergonomic Hand-Held Probes). In use, one of the hand-held probes is held in each hand of the service provider and used to apply microcurrents to body tissue (e.g., facial skin tissue) in the performance of cosmetic services. The cosmetic service typically comprises two distinct operations. The first operation is called sculpting and the second operation is called skin work.

[004] Applying the specified microamperage, frequencies and waveforms to a portion of the body (e.g., the face), can advantageously stimulate mitochondria, thereby increasing ATP. The applicant has determined that various movements (e.g., sculpting movements) of the handheld probes or electrodes thereof on body tissue (e.g., skin tissue and/or underlying muscles and/or tendons of the face) can advantageously alter or improve muscle tone (e.g., tone of the muscles and/or tendons underlying the skin tissue), which in turn alters the visual appearance and contour of a specific body part (e.g., the face) receiving the cosmetic service. The difference can be compared to the effect seen on the body after a good physical workout. With weight lifting, the muscles of the body become tense, eventually creating microtears in the muscles. As a defense, the muscles contract. As the muscles heal, they become healthier and stronger. If weightlifting continues consistently, the body will be in a continuous cycle of evolution: tearing, contracting, healing, and becoming stronger. While microtears are, by definition, harmful, there is no disruption to the activity of the mitochondria or the Krebs cycle.

[005] To be clear, the application of microcurrents differs significantly from electrical muscle stimulation (EMS) technology. EMS typically involves the delivery of currents in the range of 500 μA to 5,000 μA. In contrast, the microcurrents used in Bio-Therapeutic® technology are typically less than or equal to 400 μA. The relatively higher amperage associated with EMS is damaging to mitochondria and the Krebs cycle and tends to disrupt ATP production. EMS typically involves enough energy to cause a visual and physical contraction of the muscle resulting from the application of electrical current. In short, the amperage is sufficient to make the muscle jump and contract. The body immediately recognizes this energy as damaging and contracts the muscles to prevent them from twitching. The high energy level associated with EMS confuses the mitochondria (Krebs cycle) and the muscles, causing the tissues to use their remaining energy to defend the body by contracting the muscles. A user may initially perceive the contraction as a positive result. However, when ATP stores are depleted after a few days, the muscles become limp. In response, the user often shocks the muscles again, causing them to contract again. The limpness of the muscles now returns more quickly. By the third or fourth time the muscles are shocked, they are completely depleted of ATP and have no ability to move (i.e. contract). The muscles now feel limp. In addition to the muscles being depleted of ATP, the other tissues of the body are also depleted of ATP. This rapidly accelerates the perceived aging process as the collagen and elastin in the skin tissue break down.

[006] True microcurrent signals (<400 μA) advantageously do not have enough energy to cause a visual or physical contraction of the muscle due to the electrical current. Microcurrents advantageously provide enough energy to benefit mitochondrial activity, producing over 500% more cellular energy from ATP, without triggering muscle contraction.

[007] The first operation (i.e. sculpting) may involve performing facial sculpting movements to physically lengthen and shorten muscles as the mechanism of action (kinesiology). Similar in some respects to massage, body tissue can be physically manipulated to move muscles into shorter or longer positions or states and the muscles respond instantly. This is why a 45 minute massage can relax (lengthen) muscles and provide an incredible sense of relief, increased range of motion and increased flexibility. The applicant has realized that similar techniques can be applied to, for example, the face, however, focusing on shortening the bulk of the muscles (e.g. facial muscles, tendons) as these muscles normally lengthen over time. The muscles (including tendons) respond to the manipulation, and the increased ATP levels induced by the delivery of microcurrent signals give the muscles the endurance to remain in this new position or state for a longer period of time - than could be achieved without microamperage stimulation. Repeating the movements 2 to 3 days later, accompanied by the delivery of microcurrent signals, reinforces the new contour of the muscles and continues to increase ATP levels, strongly encouraging the new contour, as well as simultaneously energizing the synthesis of collagen and elastin.

[008] The second operation (i.e. work on the skin) focuses on stimulating mitochondria and circulatory benefits, for example by sliding the electrodes around the face and neck.

[009] Body tissue responds to specific frequencies or frequency ranges and therefore to specific signaling mechanisms. The applicant has developed technology that employs microcurrent signals with specific waveforms that act as a mechanism for delivering specific frequencies to different depths of muscles, including tendons, and other body tissues (e.g., skin). Certain frequencies are particularly effective for cellular activation.

[010] Although Applicant has established a robust catalog of successful frequencies over many years of experience, this does not change the fact that each person has a unique frequency. Accordingly, Applicant has developed a technology that increases the total number of different microcurrent signals delivered during use.

[011] Applicant's two microcurrent facial toning systems include two separate handheld probes. One of the handheld probes represents channel 1 and channel 2. The other handheld probe represents channel 1 and channel 2. The microcurrent signal employs a modulated biphasic square wave.

[012] Thus, there are two fully independent channels, each with its own frequency. Applicant's unique approach also employs interferential channels, which allows two independent channels to operate at completely different frequencies than the primary channels. The two frequencies collaborate when run in parallel, creating two additional frequencies, for a total of four frequencies. This approach provides four (4) times the ability to achieve a desired result (e.g., increasing the probability of at least approximately matching any given person's frequencies) and makes Applicant's technology more consistently successful due to this increased range of coverage.

[013] Most of the wearable technology on the market is effectively EMS. EMS achieves the limited results it can by delivering shocks to motor nerve points. These EMS devices typically operate with two electrodes that are spatially fixed relative to each other and have no ability to do anything other than shock the muscles. These EMS devices are generally not capable of performing kinesiological movements.

[014] As noted previously, Applicant's own microcurrent systems employ a console and two separate handheld probes to apply microcurrents during cosmetic treatments.

[015] In operation, microcurrent flows into the skin from an electrode on one probe, acts on the skin and muscles (including tendons), and then returns through an electrode on the other probe. Applicant realized that it would be advantageous to be able to keep the electrodes of the two handheld probes within a range of approximately one inch to approximately two (1-2) inches of each other. To do this, one could attempt to place both electrodes on a single handheld probe. However, a single-handled probe would make it difficult, if not impossible, to perform the desired sculpting movements.

[016] Systems are described herein that combine two pairs of electrodes in a handheld device, while maintaining two independent channels and interferential technology. At least one of the electrode pairs is movable relative to the body of the handheld device and relative to the other pair of electrodes, facilitating use for full kinesiological sculpting (e.g., facial sculpting), e.g., movable within a defined range of motion (e.g., defined range of rotation or spacing). This allows for picking and grasping muscle (including tendons) with one pair of electrodes (e.g., a lower pair of electrodes) and then grasping tissue with the other pair of electrodes (e.g., an upper pair of electrodes), while keeping the electrodes of one pair within a defined range of distance from the electrodes of the other pair. This not only allows for one-handed operation, but may also provide other advantages. For example, an amount of tension or force may be controlled via a biasing mechanism (e.g., spring). A range of spacing or angle between electrodes can be controlled, for example by having a minimum spacing or angle and/or a maximum spacing or angle. This can advantageously ensure that the electrodes are within a specified distance or angle of each other to ensure a desired or specified delivery of microcurrent signals.

[017] The electrodes are electrically conductive. The electrodes may comprise a material (e.g. stainless steel) which may advantageously have a relatively low amount of nickel or even be nickel-free (e.g. 420 stainless steel). The electrodes may advantageously have a rough outer surface.

[018] The electrodes may be supported by respective arms. One pair of arms, or both pairs of arms, may be directed into a standard configuration. For example, the arms may be pressed by means of one or more tension springs, with or without the respective lever. The portable device may include one or more stops to advantageously limit an amount of displacement of the movable arms and, therefore, of the electrodes carried by these movable arms.

BRIEF DESCRIPTION OF THE VARIOUS VIEWS OF THE DRAWINGS

[019] In the drawings, identical reference numerals identify similar elements or acts. The sizes and relative positions of the elements in the drawings are not necessarily drawn to scale. For example, the shapes of various elements and angles are not necessarily drawn to scale, and some of these elements may be enlarged and positioned arbitrarily to improve the legibility of the drawing. Furthermore, the specific shapes of the elements drawn are not necessarily intended to convey any information concerning the actual shape of the specific elements and may have been selected solely for ease of recognition in the drawings.

[020] Figure 1A is a top plan view of a system comprising a wearable device with integral circuitry, the system operable to deliver microcurrents through skin and muscle tissue, including tendons, and/or to provide kinesiological sculpting, in accordance with an illustrated implementation.

[021] Figure 1B is a front elevational view of the portable device of Figure 1A.

[022] Figure 1C is a rear elevational view of the portable device of Figure 1A.

[023] Figure 1D is an isometric view of the handheld device of Figure 1A.

[024] Figure 1E is a right side elevation view of the handheld device of Figure 1A showing a second pair of arms in an unrotated orientation or configuration relative to a first pair of arms.

[025] Figure 1F is a left side elevational view of the handheld device of Figure 1A showing the second pair of arms in a non-rotated orientation or configuration relative to the first pair of arms.

[026] Figure 1G is a left side elevation view of the handheld device of Figure 1A showing the second pair of arms in a fully rotated orientation or configuration relative to the first pair of arms.

[027] Figure 2A is a cross-sectional view of the handheld device of Figure 1A showing the second pair of arms in the non-rotated orientation or configuration relative to the first pair of arms.

[028] Figure 2B is a cross-sectional view of the handheld device of Figure 1A showing the second pair of arms in the fully rotated orientation or configuration relative to the first pair of arms.

[029] Figure 3A is a first exploded view of the portable device of Figure 1A, according to an illustrated deployment.

[030] Figure 3B is a second exploded view of the handheld device of Figure 1A, according to an illustrated deployment.

[031] Figure 4A is a schematic diagram showing a portion of a circuit operable to generate microcurrents for delivery through skin tissue and muscle, including tendons, that may be employed with the portable device of Figure 1A, according to an illustrated implementation.

[032] Figure 4B is a schematic diagram showing a portion of the circuitry of Figure 1A, according to an illustrated implementation.

[033] Figure 4C is a schematic diagram showing a portion of the circuitry of Figure 1A, according to an illustrated implementation.

[034] Figure 5 is a schematic diagram showing a system comprising a console and a handheld device communicatively coupled to the console, the console comprising circuitry for generating microcurrents and the handheld device including two pairs of electrode arms, at least one pair of arms movable within a defined range of motion relative to the other pair of arms, the system being operable to deliver microcurrents through skin and muscle tissue, including tendons, and/or to provide kinesiological sculpting, in accordance with an illustrated implementation.

DETAILED DESCRIPTION

[035] In the following description, certain specific details are presented in order to provide a complete understanding of various disclosed implementations. However, one skilled in the relevant art will recognize that the implementations may be practiced without one or more of these specific details, or with other methods, components, materials, etc. In other instances, well-known structures associated with power supplies, electrodes, circuits, and user interfaces have not been shown or described in detail to avoid unnecessarily obscuring the descriptions of the implementations.

[036] Unless the context otherwise requires, throughout the specification and claims that follow, the word "comprising" is synonymous with "including" and is inclusive or open-ended (i.e., does not exclude additional, unmentioned elements or method acts).

[037] Reference throughout the specification to “one (1) deployment” or “one deployment” means that a particular feature, structure, or characteristic described in connection with the deployment is included in at least one deployment. Therefore, the appearance of the phrases “in one (1) deployment” or “in one deployment” in various places throughout this specification do not necessarily all refer to the same deployment. Furthermore, the features, structures, or characteristics may be combined in any suitable manner in one or more deployments.

[038] As used in this specification and the appended claims, the singular forms of “a,” “an,” “the,” and “the” include plural referents unless the context clearly indicates otherwise. It should also be noted that the term “or” is generally used in its sense that includes “and/or,” unless the context clearly indicates otherwise.

[039] As used in this specification and the appended claims, the terms “muscle” or “muscles” are expansive and include tendons as well as tissues that are strictly defined as muscles.

[040] The headings and Disclosure Summary provided herein are for convenience only and do not interpret the scope or meaning of the disclosures.

[041] Figures 1A, 1B, 1C, 1D, 1E, 1F, and 1G show a system 101 in the form of a wearable device 100 that is operable to deliver microcurrents (e.g., signals with amperage at or below about 400 μA) through body tissue (e.g., skin tissue, muscle including tendons) and/or that can also provide kinesiological sculpting by stretching or tensing and/or compressing or pinching body tissue (e.g., skin, underlying muscles including tendons), in accordance with at least one illustrated implementation.

[042] The portable device 100 comprises a body 102 having a first end 104 and a second end 106, the second end 106 being spaced from the first end 104 along a length 108 of the body 102. The body 102 may have a head 110 at the first end 104, a tail 112 at the second end 106, and a grip portion 114 intermediate the head 110 and the tail 112. The grip portion 114 has dimensions designed to be grasped with one hand of a user with average-sized hands, therefore, the portable device 100 is referred to as being handheld. The body 102 may have an upper surface 116 and a lower surface 118, the lower surface 118 generally opposing the upper surface 116 through a thickness 120 of the body 102. The body 102 may have a somewhat arched profile along its length 108, which may facilitate retention and positioning of the head 110 relative to body tissue for cosmetic treatment. The body 102 may have a width 122, which is generally laterally transverse to the length 108. The width 122 may vary in dimension as the length 108 is transverse. Likewise, the thickness 120 may vary in dimension as the length 108 is transverse.

[043] The portable device 100 includes a first pair of arms 124a, 124b that extend outward from the head 110 at the first end 104 of the body 102. The arms 124a, 124b of the first pair of arms 124a, 124b are spaced laterally apart from each other relative to the width 122 of the body 102. Each of the arms 124a, 124b of the first pair of arms 124a, 124b has a respective terminus 126a, 126b at a distal end 128a, 128b of the arm 124a, 124b. Each of the arms 124a, 124b of the first pair of arms 124a, 124b has or supports or otherwise carries a respective electrode 130a, 130b positioned at least proximate to the respective terminal 126a, 126b of the arm 124a, 124b. The electrodes 130a, 130b are preferably attached to the respective arm 124a, 124b. In some implementations, the electrodes 130a, 130b may be replaceably removable from the respective arms 124a, 124b.

[044] The portable device 100 includes a second pair of arms 132a, 132b that extend outward from the head 110 at the first end 104 of the body 102. The arms 132a, 132b of the second pair of arms 132a, 132b are spaced laterally apart from each other relative to the width 122 of the body 102. Each of the arms 132a, 132b of the second pair of arms 132a, 132b has a respective end 134a, 134b at a distal end 136a, 136b of the arm 132a, 132b. Each of the arms 132a, 132b of the second pair of arms 132a, 132b has or carries or otherwise carries a respective electrode 138a, 138b positioned at least proximate to the respective terminal 134a, 134b of the arm 132a, 132b. The electrodes 138a, 138b are preferably attached to the respective arm 132a, 132b to move therewith. In some implementations, the electrodes 138a, 138b may be replaceably removable from the respective arms 132a, 132b.

[045] The arms 132a, 132b of the second pair of arms 132a, 132b are movable relative to the arms 124a, 124b of the first pair of arms 124a, 124b. For example, arms 132a, 132b of the second pair of arms 132a, 132b are movable relative to arms 124a, 124b of the first pair of arms 124a, 124b to vary a spacing 140 (best seen in Figures 1F and 1G and 2A and 2B) between electrodes 138a, 138b supported or otherwise carried by arms 132a, 132b of the second pair of arms 132a, 132b and electrodes 130a, 130b supported or otherwise carried by arms 124a, 124b of the first pair of arms 124a, 124b. Also, for example, arms 132a, 132b of the second pair of arms 132a, 132b are pivotable relative to arms 124a, 124b of the first pair of arms 124a, 124b to vary an angle 142 (best seen in Figures 1F and 1G and 2A and 2B) between electrodes 138a, 138b supported or otherwise carried by the second pair of arms 132a, 132b and electrodes 130a, 130b supported or otherwise carried by arms 124a, 124b of the first pair of arms 124a, 124b.

[046] In at least one implementation, one pair of arms (e.g., the first pair of arms 124a, 124b) are fixed or otherwise non-movable relative to the body 102, while the other pair of arms (e.g., the second pair of arms 132a, 132b) are movable relative to the body 102, e.g., pivotable relative thereto. In other implementations, both pairs of arms 124a, 124b; 132a, 132b may be movable relative to the body 102 and thus relative to each other. In at least some implementations, the arms 124a, 124b that are fixed or non-rotating may each have a length of about 28.4 plus or minus 0.5 millimeters from the base to the geometric center of the electrode 130a, 130b. In at least some implementations, the arms 132a, 132b that are movable or articulable may each have a length of about 27.7 plus or minus 0.5 millimeters from the base to the geometric center of the electrode 138a, 138b.

[047] In at least some implementations, each of the electrodes 130a, 130b, 138a, 138b has a generally frustro-conical shape, e.g., with a profile of a truncated paraboloid or otherwise bullet-shaped, e.g., having an axis of symmetry or revolution that extends predominantly laterally relative to the length 108 of the body 102. The axis of symmetry or revolution may optionally bias slightly in a direction from a front to a rear of the handheld device 100, such that the electrodes 130a, 130b, 138a, 138b slope or angle slightly toward a centerline of the handheld device 100. In at least some implementations, each of the bullet-shaped electrodes 130a, 130b, 138a, 138b has a width (i.e., measured laterally) of about 20.76 millimeters plus or minus 0.5 millimeters. In at least some implementations, each of the bullet-shaped electrodes 130a, 130b, 138a, 138b has an outer portion (facing laterally outward relative to the body 102) with a diameter of about 13.85 millimeters plus or minus 0.5 millimeters. For each electrode pair 130a, 130b; 138a, 138b, a lateral separation (i.e., measured from inner edge to inner edge) between the electrodes of electrode pairs 130a, 130b; 138a, 138b may, for example, be about 8.47 plus or minus 1.0 millimeters.

[048] In at least some implementations, each of the electrodes 130a, 130b, 138a, 138b has a respective geometric center and a distance between the geometric centers of the electrodes of the second electrode pair 138a, 138b and those of the electrodes of the first electrode pair 130a, 130b is approximately 34.8 millimeters plus or minus 0.5 millimeters in the unrotated orientation and is approximately 45.0 millimeters in the fully rotated orientation plus or minus 0.5 millimeters. In at least some deployments, each of the electrodes 130a, 130b, 138a, 138b has a respective geometric center and an angle between the electrodes of the second electrode pair 138a, 138b and the corresponding electrodes of the first electrode pair 130a, 130b is approximately 63.4 degrees plus or minus 0.5 degrees in the unrotated orientation (Figure 1F, Figure 2A) and is approximately 88.5 degrees plus or minus 0.5 degrees in the fully rotated orientation (Figure 1G, Figure 2B).

[049] Electrodes 130a, 130b, 138a, 138b are electrically conductive. For example, electrodes 130a, 130b, 138a, 138b may advantageously comprise a stainless steel (e.g., 420W) that is nickel-free or has a low nickel content relative to other stainless steels (e.g., austenitic stainless steels). In at least some implementations, electrodes 130a, 130b, 138a, 138b of at least one pair of arms 124a, 124b; 132a, 132b, and preferably both pairs of arms 124a, 124b, 132a, 132b, each advantageously have a roughened exposed surface. Electrodes 130a, 130b, 138a, 138b may, for example, have an outer surface that has been blasted with an abrasive to create the exposed rough surface. The surface roughness of electrodes 130a, 130b, 138a, 138b may vary from electrode to electrode and/or vary between portions of a given electrode 130a, 130b, 138a, 138b. Some sample measurements of surface roughness may include a depth of roughness of about 0.29 microns to about 1.15 microns, inclusive.

[050] As best illustrated in Figure 1A, the portable device 100 may optionally include a user interface 150 accessible from an exterior 152 of the body 102. The user interface 150 may, for example, be carried on the upper surface 116 of the body 102. The user interface 150 may include various user-selectable controls (e.g., buttons, keys, switches) that may be actuated to operate the portable device 100. For example, the user interface 150 may include a power button 154 to, for example, toggle the portable device 100 between an ON or powered state and an OFF or de-powered state. Also, for example, the user interface 150 may include a first mode button (LIFT) 156 to, for example, cause the wearable device 100 to enter a first operational mode in which facial sculpting movements are performed using the wearable device 100 to physically lengthen and shorten muscles as a mechanism of action (kinesiology). Successive activations of the first mode button (LIFT) 156 may successively cycle through a set of microcurrent amplitude or magnitude levels, to control an amplitude or magnitude of microcurrent signals delivered through the electrodes 130a, 130b, 138a, 138b while operating in the first mode. Also, for example, the user interface 150 may include a second mode button (SKIN) 158 to, for example, cause the wearable device 100 to enter a second operational mode in which the device stimulates mitochondria and achieves circulatory benefits. Successive activations of the first mode button (SKIN) 158 may successively cycle through a set of amplitude or magnitude levels of microcurrent signals, to control an amplitude or magnitude of microcurrent delivered through electrodes 130a, 130b, 138a, 138b during operation in the second mode.

[051] The user interface 150 may include a number of components or output devices (e.g., lights, LEDs, speakers) to, for example, provide visual and/or auditory cues to the user. For example, the user interface 150 may include a pair of operational mode indicators 160a, 160b that indicate an operational mode in which the handheld device 100 is currently operating. Operating mode indicators 160a, 160b may be incorporated into respective of the first and second mode buttons 156, 158. Further, for example, user interface 150 may include a charge level indicator 162 that indicates a charge condition of a power source (e.g., secondary battery) of portable device 100, for example on a scale of 1 to 5. Also, for example, user interface 150 may include a pair of continuity indicators 164a, 164b that indicate a presence or absence of continuity between electrodes 130a, 130b, 138a, 138b when in contact with the skin and in an ON or powered operational state. This advantageously provides the user with a clear indication that the handheld device 100 is correctly applied to the skin and operable to deliver the microcurrent signals through the two electrode pairs 130a, 130b, 138a, 138b.

[052] Figure 2A illustrates the handheld device 100 of Figure 1A showing the second pair of arms 132a, 132b in an unrotated orientation or configuration relative to the first pair of arms 124a, 124b. Figure 2B illustrates the device of Figure 1A showing the second pair of arms 132a, 132b in a fully rotated orientation or configuration relative to the first pair of arms 124a, 124b.

[053] As best illustrated in Figures 2A and 2B, the portable device 100 further comprises at least one biasing mechanism 200 housed by the body 102. The at least one biasing mechanism 200 is coupled to bias the respective ends 134a, 134b of the arms 132a, 132b of the second pair of arms 132a, 132b toward the respective ends 126a, 126b of the arms 124a, 124b of the first pair of arms 124a, 124b. In at least some implementations, the at least one biasing mechanism 200 comprises a respective biasing mechanism 200 for each of the arms 132a, 132b of the second pair of arms 132a, 132b. Alternatively, a single biasing mechanism 200 may be employed to bias both arms 132a, 132b of the second pair of arms 132a, 132b.

[054] Each biasing mechanism 200 may, respectively, include at least one spring 202 (e.g., coil spring, leaf spring, tension spring) and, optionally, a lever 204, the spring 202 being coupled between the respective lever 204 and an anchor feature 206 of the body 102. The at least one biasing mechanism 200 biases the respective terminals 134a, 134b and electrodes 138a, 138b of the arms 132a, 132b of the second pair of arms 132a, 132b toward an unrotated orientation or configuration (Figures 1F, 2A) in which the respective terminals 134a, 134b and electrodes 138a, 138b of the arms 132a, 132b of the second pair of arms 132a, 132b are oriented in a non-rotated orientation or configuration (Figures 1F, 2A) wherein ... 132b are at a minimum allowable distance from the respective terminals 126a, 126b and electrodes 130a, 130b of the arms 124a, 124b of the first pair of arms 124a, 124b. In at least some implementations, the spring 202 (e.g., tension spring) may have a proportional constant or K value of, for example, about 1881.95 kgf/mm to about 1.95 kgf/mm. This advantageously applies tension to body tissue (e.g., skin tissue, muscles underlying skin tissue, including tendons) during use when the second pair of electrodes 138a, 138b is displaced from a standard non-rotated position or orientation, to stretch and/or compress body tissue to induce a kinesiological effect. Note that in at least some instances during use, the second pair of arms 132a, 132b may be partially rotated between the unrotated orientation or configuration (Figures 1F, 2A) and the fully rotated orientation or configuration (Figures 1G, 2B). In use, as the second pair of electrodes 138a, 138b engages with (e.g., grips) the muscle, the spring 202 allows the second pair of electrodes 138a, 138b to remain in contact with the tissue while the body 102 of the handheld device 100 is upright. Once extension (e.g., full extension) of the second pair of arms 132a, 132b is reached, the electrodes 130a, 130b of the first pair of arms 124a, 124b are gently brought into contact with the tissue (e.g., face). Because the electrodes 138a, 138b of the second pair of arms 132a, 132b are under tension, they continually push the muscle upward with a specific force to facilitate kinesiological sculpting.

[055] As best illustrated in Figures 2A and 2B, the device may further include one or more stops 208 that limit the travel of the second pair of arms 132a, 132b as they move away from the unrotated orientation or configuration (Figure 1F) to define a fully rotated orientation or configuration (Figure 1G) in which the respective terminals 134a, 134b and electrodes 138a, 138b of the arms 132a, 132b of the second pair of arms 132a, 132b are at the greatest allowable distance and/or greatest allowable angle relative to the respective terminals 126a, 126b and electrodes 130a, 130b of the arms 124a, 124b of the first pair of arms 124a, 124b.

[056] Figure 3A illustrates the device of Figure 1A in a first exploded view further illustrating an upper housing 300a. Figure 3B illustrates the device of Figure 1A in a second exploded view further illustrating a lower housing 300b.

[057] The body 102 may be formed as an enclosure, e.g. a multi-part enclosure, e.g. comprising an upper enclosure 300a, a lower enclosure 300b, and an optional intermediate enclosure 300c, with an interior 302 for housing circuitry 304, a power source 306, a resilient pad 305 for holding the power source 306 in a snug position, recharging circuitry 307, etc. In some implementations, the upper enclosure 300a is coupled to the intermediate enclosure 300b by means of one or more fasteners 309 (only one named, e.g., screws, bolts) with the intermediate enclosure 300c positioned therebetween. In other implementations, the intermediate enclosure 300c may be omitted. The body 102 may include a portion that provides an electrically insulating enclosure protecting a user from potential contact with various circuit components and/or providing environmental protection for the circuit components (e.g., printed circuit board (PCB), power source (e.g., chemical battery cells, fuel cells, super or ultracapacitors), wiring, lights, speakers, haptic motor), and/or mechanical structures. For example, the body 102 may include an inner enclosure 308a, 308b, 308c formed from an electrically insulating material, e.g., an injection molded plastic enclosure (e.g., ABS plastic). The body 102 may optionally include an outer enclosure 310a, 310b, e.g., a metal enclosure that overlaps those of the inner enclosure 308a, 308b (e.g., inner plastic enclosure). This may advantageously increase wear resistance and/or provide some mass to facilitate physical manipulation of the handheld device 100 with controlled movements. Thus, in at least some implementations, the upper housing 300a is comprised of the outer housing 310a and the inner housing 308a, while the lower housing 300b is comprised of the outer housing 310b and the inner housing 308b. The handheld device 100 may include a plurality of seals (e.g., gaskets, O-rings) 144, for example, at each location 146 where the first pair of arms 124a, 124b and/or the second pair of arms 132a, 132b join or enter the body 102 to improve environmental protection. There is a joint 148 located at least at the locations where the second pair of arms 132a, 132b joins or enters the body 102, allowing the second pair of arms 132a, 132b to move (e.g., pivot, rotate) relative to the body 102 and relative to the first pair of arms 124a, 124b.

[058] The portable device 100 optionally includes circuitry 304 that is communicatively coupled to electrodes 130a, 130b of the first pair of arms 124a, 124b and electrodes 138a, 138b of the second pair of arms 132a, 132b. The circuitry 304 is operable and provides at least one microcurrent signal through electrodes 130a, 130b; 138a, 138b supported by the first and second pairs of arms 124a, 124b; 132a, 132b. Circuitry 304 may be housed by body 102. As noted previously, a portion of body 102 may provide an electrically insulating enclosure protecting a user from potential contact with various circuit components and/or providing environmental protection for circuitry 304, e.g., an inner enclosure 308a, 308b, 308c formed from an electrically insulating material, e.g., an injection molded plastic (ABS plastic) enclosure.

[059] Circuitry 304 may, for example, be operable to provide: i) a first microcurrent signal between a first electrode of the first pair of electrodes 130a, 130b and a first electrode of the second pair of electrodes 138a, 138b, ii) a second microcurrent signal between a second electrode of the first pair of electrodes 130a, 130b and a second electrode of the second pair of electrodes 138a, 138b, iii) a third microcurrent signal between the first electrode of the first pair of electrodes 130a, 130b and the second electrode of the second pair of electrodes 138a, 138b, and iv) a fourth microcurrent signal between the second electrode of the first pair of electrodes 130a, 130b and the second electrode of the second pair of electrodes 138a, 138b. In at least some implementations or configurations, circuitry 304 is operable to deliver the first microcurrent signal, the second microcurrent signal, the third microcurrent signal, and the fourth microcurrent signal simultaneously with one another. Circuitry 304 may, for example, be operable to adjust an amplitude or magnitude of the microcurrent, for example, based on input received through user interface 150 (Figure 1A).

[060] In at least some implementations or configurations, circuitry 304 is operable to provide the first microcurrent signal having a first set of frequencies and provide at least one of a second microcurrent signal, a third microcurrent signal, or a fourth microcurrent signal having a second set of frequencies, the second set of frequencies different from the first set of frequencies.

[061] In at least some implementations or configurations, circuitry 304 is operable to deliver the first microcurrent signal having a first set of frequencies, deliver the second microcurrent signal having a second set of frequencies, deliver the third microcurrent signal having a third set of frequencies, and deliver the fourth microcurrent signal having a fourth set of frequencies, the second set of frequencies being different from the first set of frequencies, the third set of frequencies being different from the first and second sets of frequencies; and the fourth set of frequencies being different from the first, second, and third sets of frequencies.

[062] Circuitry 304 may include a frequency generator, a pulse generator, a pulse envelope generator, and a controller for providing controlled current in each channel from about 20 μA to about 400 μA at up to 300 Hz. Circuitry 304 is electrically coupled to a power source or power source to receive electrical power therefrom. Two or more frequencies are used to provide interferential waveforms.

[063] Figure 4A shows circuitry 400 of system 101 (Figures 1A-1G), 501 (Figure 5), in accordance with at least one illustrated implementation. Circuitry 400 may form a portion of circuitry 304 (Figure 3A).

[064] Circuitry 400 includes a microprocessor control unit ("MCU") 402. MCU 402 receives inputs from various switches, e.g., via keys, buttons 159, 156, 158, or other user input devices of user interface 150 (Figures 1A), and provides signals to various indicators (e.g., LEDs, LCD, speakers) 160a, 160b, 162, 164a, 164b, 166, or other output devices of user interface 150 (Figures 1A). MCU 402 receives inputs from various sensors (e.g., continuity sensors, current sensors, voltage sensors), as well as receiving power from a power source 306 (Figure 3A).

[065] Circuitry 400 includes a driver circuit 404, which, as explained below, may have two distinct portions. In use, MCU 402 provides a pulse width modulated (VOL PWM) signal to driver circuit 404 which is depicted in more detail in Figures 4B and 4C, respectively. Driver circuit 404 receives VCC power from a power source and provides microcurrent signals (A/B; C/D) to electrodes 406 (shown collectively for ease of illustration). Driver circuit 404 may also monitor the A/B microcurrent signals, providing status signals (EMS_STATUS-A; EMS_STATUS-B) to MCU 402.

[066] Figure 4B shows in detail a first portion 404a of the drive circuit 404 of the system 101 (Figures 1A-1G), 501 (Figure 5), in accordance with at least one illustrated implementation. The first portion 404a of the drive circuit 404 may form a portion of the circuitry 304 (Figure 3A).

[067] The first portion 404a of the drive circuit 404 includes a bridge 408a formed by four transistors Q102, Q103, Q104, Q105, which is driven by gate drive signals A, A-, B, B- to provide microcurrent signals through nodes or terminals T7, T8, which are coupled to ground through capacitors C102, C111. Extra nodes or terminals (e.g., T6) may optionally be included to provide additional channels of microcurrent signals. The gate drive signals A, A-, B, B- provide frequency modulation of the microcurrent signals.

[068] The first portion 404a of the drive circuit 404 includes a magnitude adjustment circuit 410a comprised of a transistor Q001 that is coupled to ground through a resistor R122 and a capacitor C115, which provides a sensed current output I_SENSA. The transistor Q001 is driven by gate drive signals generated through an output terminal 1 of a voltage comparator U001 that are applied to a gate of the transistor Q001 through a resistor R105. The voltage comparator U001 compares a pulse width modulated (PWM) signal VOL_PWM supplied by the comparator U001 compares a pulse width modulated (PWM) signal VOL_PWM supplied to an input terminal 3 of the comparator U001 with the sensed current I_SENSA supplied to another input terminal 4 of the comparator U001. The comparator U001 can be implemented through an operational amplifier, with a sampling value of the voltage I_SENS input to an inverting terminal, to be compared with a standard VOL_PWM, and the output terminal coupled to control the gate of transistor Q001, to achieve precise control of the current. level of the microcurrent signal. A network of resistors R139, R140, R141, R112, R113 and capacitors C118, C119 couples the PWM signal VOL_PWM and the detected current I_SENSA to the comparator U001.

[069] The first portion 404a of the drive circuit 404 includes a status monitoring circuit 412a that provides the status signal (EMS_STATUS-A) to the MCU 402 (Figure 4A). The status monitoring circuit 412a employs a comparator U007 to monitor the microcurrent output of the main channel (A).

[070] Figure 4C shows in detail a second portion 404b of the drive circuit 404 of the system 101 (Figures 1A-1G), 501 (Figure 5), in accordance with at least one illustrated implementation. The second portion 404b of the drive circuit 404 may form a portion of the circuitry 304 (Figure 3A).

[071] The second portion 404b of the drive circuit 404 includes a bridge 408b formed by four transistors Q107, Q109, Q110, Q111, which is driven by gate drive signals C, C-, D, D- to provide microcurrent signals through nodes or terminals T11, T12, which are coupled to ground through capacitors C112, C113. Extra nodes or terminals (e.g., T9) may optionally be included to provide additional channels of microcurrent signals. The gate drive signals C, C-, D, D provide frequency modulation of the microcurrent signals.

[072] The second portion 404b of the drive circuit 404 includes a magnitude adjustment circuit 410b comprised of a transistor Q002 that is coupled to ground through a resistor R159 and a capacitor C128, which provides a sensed current output I_SENB. The transistor Q002 is driven by gate drive signals generated through an output terminal 1 of a voltage comparator U002 that are applied to a gate of the transistor Q002 through a resistor R160. The voltage comparator U002 compares a pulse width modulated (PWM) signal VOL_PWM supplied to an input terminal 3 of the comparator U002 with the sensed current I_SENSB supplied to another input terminal 4 of the comparator U002. The comparator U002 can be implemented through an operational amplifier, with a sampling value of the voltage I_SENS input to an inverting terminal, to be compared with a standard VOL_PWM, and the output terminal coupled to control the gate of the transistor Q002, to achieve precise control of the current. level of the microcurrent signal. A network of resistors R161, R162, R163, R164, R165 and capacitors C130, C131 couples the PWM signal VOL_PWM and the detected current I_SENSB to the comparator U002.

[073] The second portion 404b of the drive circuit 404 includes a status monitoring circuit 412b that provides the status signal (EMS_STATUS-B) to the MCU 402 (Figure 4A). The status monitoring circuit 412b employs a comparator U003 to monitor the microcurrent output of the main channel (B).

[074] Circuitry 400 provides low frequency and amplitude waveforms to aid fluid flow in a subject's body tissue to increase ATP production and thus tissue repair. Device 100 provides pulsed microcurrent energy envelopes with a mandatory pause between pulses. The waveforms are preferably modulated by a fifty percent duty cycle square wave.

[075] Circuitry 400 may, for example, include a microprocessor control unit ("MCU") that controls analog output circuitry and instrumentation circuitry, a power supply, a user interface (e.g., a control panel with a display or visual indicators (e.g., LEDs) and buttons and keys), and optionally an audio speaker. Analog output circuitry includes a plurality of output conductors 11 for transferring microcurrent signals to electrodes. The MCU may include a microprocessor, volatile memory, e.g., random access memory ("RAM"), non-volatile memory, e.g., read-only memory ("ROM") or FLASH memory, analog-to-digital conversion ("ADC"), digital-to-analog conversion ("DAC"), computing, timing, and communication components.

[076] The power source may take the form of a switching power supply that can generate plus or minus 32 volts for high voltage output operational amplifiers (not shown), plus or minus 9 volts for an instrumentation operational amplifier, plus 5 volts for the microprocessor. Power may be supplied by batteries with a nominal working voltage of 12 volts or by any other source. Power is switched on by a push button and preferably automatically switched off after about six minutes if no waveforms are being generated. The microprocessor may also control the ON-OFF status of the power source.

[077] The analog output circuitry is used to provide current through a channel under control of the MCU. The circuitry may be similar to that illustrated and described in U.S. Patent No. 5,817,138 or European Patent No. 1,009,478, which are incorporated herein by reference. The output stages may comprise operational amplifiers (op-amps) in a voltage-controlled constant-current configuration with a maximum current capability of 180 μA at 30 volts.

[078] The MCU controls the voltage with a DAC that connects to the op amp to set the op amps output current. The DAC allows programmable current boost. An in-line voltage multiplier controls the on/off status and polarity of the output stage. Output current flow is controlled only with the op amp circuitry, after the voltages are set.

[079] The user interface or control panel allows for the selection or entry of desired parameters and pre-programmed treatment settings which are groups of predetermined parameters for specific treatments, and for displaying various treatment parameters such as time, current, voltage, etc. for turning on the device and entering parameters and settings.

[080] The microprocessor can output waveforms with selected envelopes, modulating frequencies, and polarity. Each channel can be independently controlled. Each output channel is a separate operational op-amp circuit, with signal wiring physically isolated from the other channels using, for example, 1 Meg ohms between channels.

[081] The electrical output of the microcurrent device is a waveform, representing the current measured in a 10k ohm resistor. The waveform is typically a complex waveform. In general, all waveforms consist of a selectable, predetermined waveform envelope, which is then modulated with a duty square wave of 50% of the selected frequency.

[082] In one implementation, a standard (two full cycle) waveform consists of a 2.0 second negative square wave envelope with a 0.5 second pause, and then a positive waveform for 2.0 seconds. For example, this waveform envelope may be modulated by a 50% duty cycle signal of 2.2 Hz frequency. The modulating frequency of the 2.2 and 1.3 Hz signal is referred to as the output waveform frequency and is selectable, i.e., other modulation frequencies may be selected. The waveform envelope does not change due to frequency and is always fixed at a 2.0 second square wave with a 0.5 second pause, then another 2.0 second square wave with a 0.5 second pause, etc. e.g., a negative polarity waveform envelope or a positive polarity waveform envelope.

[083] The MCU 10 provides the intelligence to operate the system 101 (Figure 1A), 501 (Figure 5). In addition to control functions, the MCU receives inputs from the user interface and provides outputs to the user.

[084] The MCU configures the H-Bridge circuitry to deliver a user-selected amount of current. The current is controlled in constant mode by the H-Bridge feedback circuitry. The amplitude or magnitude of the current can, for example, be selected in five discrete steps - 40 μA, 80 μA, 100 μA, 160 μA, and 180 μA by setting the control voltage to the H-Bridge op-amp. This can be achieved through an associated op-amp feedback circuit. The current cannot exceed the selected set value or a specified maximum value (e.g., 180 μA) under any circumstances using the circuitry to ensure safety.

[085] A waveform envelope is controlled by an MCU "PWM" pulse width modulator and filter circuit that feeds analog switches, which set the maximum current output. This means that after a maximum current is selected (by the switches), it can be reduced as needed to control the waveform by the microprocessor using its PWM output.

[086] The MCU provides control of the H-bridges through output circuits for one A channel and one B channel. The device basically has four channels for outputting current signals according to each of the illustrated A and B channels. All channels with output "A" are the same and all channels with output "B" are the same.

[087] The polarity of the output current is controlled in the H-bridge by inverting the connections of the output transistor to the analog switches in the output circuit. The output frequency is controlled by turning these two switches on and off as the chosen frequency may require. Typically, one switch is ON and the other OFF for current flow.

[088] All controlled H-Bridge circuits produce the same current selected by the user, for example, between 40 and 180 micro amps.

[089] All channels on side A are driven by the same signal and all channels on side B are driven by a different signal. Thus, the outputs on side A produce different output frequency characteristics than the outputs on side B. Each channel can be programmed individually, if desired, so that each channel has different output frequency characteristics. Typically, four channels (side A) have one output frequency characteristic and the other four channels (side B) have a second frequency characteristic.

[090] Figure 5 shows a system 501 comprising a handheld device 500 and a console 502, the handheld device 500 communicatively coupled to the console 502, the system 501 operable to deliver microcurrents through skin and muscle tissue, including tendons, and/or to provide kinesiological sculpting, in accordance with an illustrated implementation.

[091] The console 502 may include all or some of the circuitry and/or electronics (e.g., circuitry 304, Figure 3A; circuitry 400, Figures 4A-4C) that generate and deliver the microcurrent signals to the electrodes 130a, 130b, 130c, 130d of a portable device 500 for application to the skin or other body tissue. Accordingly, the portable device 500 may omit all or some of the circuitry and/or electronic components of the previously described implementations, for example, where such circuitry and/or electronic components are included in or housed by the console 502. The portable device 500 includes a body 102, head 110, and arms 124a, 124b of the first pair of arms 124a, 124b and arms 132a, 132b of the second pair of arms 132a, 132b, together with electrodes 130a, 130b, 130c, 130d, wherein at least one pair of arms 124a, 124b; 132a, 132b is movable (e.g., articulable) relative to the other pair of arms 124a, 124b; 132a, 132b similar to the deployment of Figures 1A-1G, 2A, 2B and 3A. In particular, at least one portion of arms 132a, 132b is movable within a defined range of motion (e.g., defined range of rotation or spacing) relative to the other pair of arms 124a, 124b.

[092] The console 502 may, for example, include a microprocessor control unit (“MCU”) similar or identical to the MCU 402 (Figure 4A). The console 502 may, for example, include a driver circuit similar or identical to the driver circuit 404 (Figure 4A). The console 502 may, for example, include various switches (e.g., keys, buttons, actuators) or other user input devices of a user interface 506, e.g., a power switch 508, a pause switch 510, a level or magnitude decrease switch 512, a level or magnitude increase switch 514, a mode selection switch 516, a program selection switch 518, and an option selection switch 520). The console 502 may, for example, include various indicators (e.g., LEDs, LCD, speakers) or other user interface output devices 150, for example, a display panel 522 and speaker 524. Alternatively, the handheld device 500 may carry one, more, or all of the switches and/or indicators. The console 502 may, for example, include various sensors (e.g., continuity sensors, current sensors, voltage sensors). Alternatively, the handheld device 500 may include one, more, or all of the sensors (e.g., continuity sensors, current sensors, voltage sensors).

[093] The handheld device 500 may be communicatively coupled to the console 502 via one or more wires or cables 526. For example, the console 502 and/or the handheld device 500 may include one or more ports 528a, 528b (e.g., wired ports, e.g., USB-C compatible ports or connectors) to which one or more wires or cables 526 are detachably or permanently coupled. Wires or cables 526 may, for example, deliver microcurrents from console 502 to electrodes 130a, 130b, 130c, 130d of handheld device 500. Wires or cables 526 may, for example, optionally deliver signals from handheld device 500 to console 502, e.g., signals indicative of continuity, current, and/or voltage to sensors housed by console 502 or from sensors housed by handheld device 500. Additionally or alternatively, radios, transmitters, receivers, and/or transceivers may communicatively couple handheld device 500 to console 502. For example, in some implementations, radios, transmitters, receivers, and/or transceivers may be employed to transmit sensed information between handheld device 500 and console 502.

[094] Described herein are implementations and embodiments of a device advantageously taking the form of a portable body with two pairs of electrodes mounted or carried by respective arms extending from the portable body, wherein at least one pair of arms is movable (e.g., pivotable, rotatable) relative to the portable body and therefore relative to the other pair of arms, operable to deliver microcurrent signal via two separate channels and via interferential signals between the two separate channels, to facilitate the application of kinesiology facial sculpting.

[095] It should be apparent that the method described above may include additional acts, omit some acts, and/or perform acts in a different order.

[096] The foregoing detailed description has presented various implementations of the devices and/or processes through the use of block diagrams, schematics, and examples. To the extent that such block diagrams, schematics, and examples contain one or more functions and/or operations, it will be understood by those skilled in the art that each function and/or operation within such block diagrams, flowcharts, or examples may be implemented, individually and/or collectively, by a wide variety of hardware, software, firmware, or virtually any combination thereof. In one implementation, the present subject matter may be implemented through Application Specific Integrated Circuits (ASICs). However, those skilled in the art will recognize that the implementations disclosed herein, in whole or in part, can be equivalently implemented in standard integrated circuits, as one or more computer programs running on one or more computers (e.g., as one or more computer programs running on one or more computer systems), as one or more programs running on one or more controllers (e.g., microcontrollers), as one or more programs running on one or more processors (e.g., microprocessors), as firmware, or as virtually any combination thereof, and that designing the circuitry and/or writing the code for the software and/or firmware would be well within the skill of a person of ordinary skill in the art in light of this disclosure.

[097] Those skilled in the art will recognize that many of the methods or algorithms set forth herein may employ additional acts, may omit some acts, and/or may perform acts in an order other than that specified.

[098] Furthermore, those skilled in the art will appreciate that the mechanisms taught herein are capable of being distributed as a program product in a variety of forms, and that an illustrative implementation applies equally regardless of the particular type of signal-carrying media used to actually carry out the distribution. Examples of signal-carrying media include, but are not limited to, the following: recordable-type media such as floppy disks, hard disk drives, CD-ROMs, digital tape, and computer memory.

[099] The various implementations described above may be combined to provide additional implementations. To the extent not inconsistent with the specific teachings and definitions contained herein, all U.S. patents, U.S. patent application publications, U.S. patent applications, foreign patents, foreign patent applications, and non-patent publications referenced in this specification, including: U.S. Patent No. 5,817,138; International Patent Application Publication WO1998023326 A1; EP Patent No. EP1009478 B1; and U.S. Patent Application No. 18/148,140 are hereby incorporated by reference in their entirety. Aspects of the implementations may be modified as necessary to employ systems, circuits, and concepts from the various patents, applications, and publications to provide still other implementations.

[100] These and other changes may be made to the implementations in light of the detailed description above. In general, in the following claims, the terms used should not be construed to limit the claims to the specific implementations disclosed in the specification and claims, but should be construed to include all possible implementations together with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.

Claims (27)

1. System CHARACTERIZED by the fact that it comprises: a body having a first end and a second end, the second end being spaced from the first end along a length of the body; a first pair of arms extending outwardly from the first end of the body, the arms of the first pair of arms being spaced laterally from each other, wherein each of the arms of the first pair of arms has a respective termination at a distal end of the arm and each of the arms of the first pair of arms carries a respective electrode positioned at least proximate to the respective end of the arm; and a second pair of arms extending outward from the first end of the body, the arms of the second pair of arms being spaced laterally apart, wherein each of the arms of the second pair of arms has a respective termination at a distal end of the arm and each of the arms of the second pair of arms carries a respective electrode positioned at least proximate to the respective end of the arm, wherein the arms of the second pair of arms are movable relative to the arms of the first pair of arms to vary a spacing between the electrodes supported by the arms of the second pair of arms and the electrodes supported by the arms of the first pair of arms. 2. System, according to claim 1, CHARACTERIZED by the fact that the second pair of arms is pivotally coupled to the body. 3. The system of claim 2, further comprising: at least one biasing mechanism housed by the body, the at least one biasing mechanism being coupled to bias respective arm ends of the second pair of arms toward respective arm ends of the first pair of arms. 4. The system of claim 3, wherein the at least one biasing mechanism comprises at least one spring. 5. The system of claim 3, wherein the at least one biasing mechanism biases the respective arm ends of the second pair of arms toward an unrotated orientation in which the respective arm ends of the second pair of arms are at a smaller allowable distance from the respective arm ends of the first pair of arms. 6. The system of claim 5, further comprising: a stop that limits the travel of the second pair of arms when moving away from the unrotated orientation to define a fully rotated orientation in which the respective arm ends of the second pair of arms are at the greatest allowable distance from the respective arm ends of the first pair of arms. 7. The system of claim 5, wherein each electrode has a respective geometric center and a distance between the geometric centers of the electrodes of the second pair of electrodes and corresponding electrodes among the electrodes of the first pair of electrodes is approximately 34.8 millimeters plus or minus 0.5 millimeters in the unrotated orientation and is approximately 45.0 millimeters in a fully rotated orientation plus or minus 0.5 millimeters. 8. The system of claim 1, wherein the electrodes supported by the first pair of arms and the electrodes supported by the second pair of arms each have an irregular exposed surface. 9. The system of claim 1 further comprising: a circuit, the circuit being communicatively coupled to the electrodes supported by the first pair of arms and to the electrodes supported by the second pair of arms, wherein the circuit is operable to deliver a microcurrent through the electrodes supported by the first and second pairs of arms. 10. The system of claim 9, wherein the circuit is operable to provide: i) a first microcurrent signal between a first electrode of the first pair of electrodes and a first electrode of the second pair of electrodes, ii) a second microcurrent signal between a second electrode of the first pair of electrodes and a second electrode of the second pair of electrodes, iii) a third microcurrent signal between the first electrode of the first pair of electrodes and the second electrode of the second pair of electrodes, and iv) a fourth microcurrent signal between the second electrode of the first pair of electrodes and the second electrode of the second pair of electrodes. 11. The system of claim 10, wherein the circuit is operable to provide the first microcurrent signal, the second microcurrent signal, the third microcurrent signal, and the fourth microcurrent signal simultaneously with each other. 12. The system of claim 10, wherein the circuit is operable to provide the first microcurrent signal having a first set of frequencies and provide at least one of the second microcurrent signal, the third microcurrent signal, or the fourth microcurrent signal having a second set of frequencies, the second set of frequencies being different from the first set of frequencies. 13. The system of claim 10, wherein the circuit is operable to provide the first microcurrent signal having a first set of frequencies, provide the second microcurrent signal having a second set of frequencies, provide the third microcurrent signal having a third set of frequencies, and provide the fourth microcurrent signal having a fourth set of frequencies, the second set of frequencies being different from the first set of frequencies, the third set of frequencies being different from the first and second sets of frequencies; and the fourth set of frequencies being different from the first, the second, and the third set of frequencies. 14. The system of claim 9, wherein the body, the first pair of arms, and the second pair of arms comprise a portable device and the circuitry is housed by the body of the portable device. 15. The system of claim 9, wherein the body, the first pair of arms, and the second pair of arms comprise a portable device and further comprise: a console to which the body is communicatively coupled, wherein the circuitry is housed by the console. 16. The system of claim 1, wherein the body has a grip portion having dimensions designed to be held in one hand by a user with average-sized hands, and a user interface accessible from an exterior of the body. 17. System CHARACTERIZED by the fact that it comprises: a body having a first end and a second end, the second end being spaced from the first end along a length of the body; a first pair of arms extending outwardly from the first end of the body, the arms of the first pair of arms being spaced laterally from each other, wherein each of the arms of the first pair of arms has a respective termination at a distal end of the arm and each of the arms of the first pair of arms has a respective electrode positioned at least proximate to the respective end of the arm; a second pair of arms extending outward from the first end of the body, the arms of the second pair of arms being spaced laterally apart, wherein each of the arms of the second pair of arms has a respective termination at a distal end of the arm and each of the arms of the second pair of arms has a respective electrode positioned at least proximate to the respective end of the arm, wherein the arms of the second pair of arms are pivotable relative to the arms of the first pair of arms to vary an angle between the electrodes of the arms of the second pair of arms and the electrodes of the arms of the first pair of arms; and at least one biasing mechanism coupled to bias the arms of the second pair of arms toward an unrotated orientation in which an angle between the arms of the second pair of arms and the corresponding arms of the first pair of arms is the smallest achievable angle therebetween. 18. The system of claim 17, wherein the at least one biasing mechanism comprises at least one spring. 19. The system of claim 17, wherein the at least one biasing mechanism applies a voltage to body tissue when the electrodes of the first and second pairs of arms are applied to skin tissue to achieve a kinesiological effect. 20. The system of claim 17, further comprising: a stop that limits rotation of the second pair of arms relative to the first pair of arms to a fully rotated orientation in which an angle between the arms of the second pair of arms and the corresponding arms of the first pair of arms is the largest achievable angle. 21. The system of claim 17, wherein each of the electrodes has a respective geometric center and an angle between the electrodes of the second pair and the corresponding electrodes of the first pair is approximately 63.4 degrees plus or minus 0.5 degrees in the unrotated orientation and is approximately 88.5 degrees plus or minus 0.5 degrees in a fully rotated orientation. 22. The system of claim 17, wherein the electrodes supported by the first pair of arms and the electrodes supported by the second pair of arms each have an irregular exposed surface. 23. The system of claim 17 further comprising: a circuit, the circuit communicatively coupled to the electrodes supported by the first pair of arms and the electrodes supported by the second pair of arms, the circuit operable to provide a microcurrent through the electrodes supported by the first and second pairs of arms, wherein the circuit is operable to provide: i) a first microcurrent signal between a first electrode of the first pair of electrodes and a first electrode of the second pair of electrodes, ii) a second microcurrent signal between a second electrode of the first pair of electrodes and a second electrode of the second pair of electrodes, iii) a third microcurrent signal between the first electrode of the first pair of electrodes and the second electrode of the second pair of electrodes, and iv) a fourth microcurrent signal between the second electrode of the first pair of electrodes and the second electrode of the second pair of electrodes. 24. The system of claim 23, wherein the circuit is operable to deliver the first microcurrent signal, the second microcurrent signal, the third microcurrent signal, and the fourth microcurrent signal simultaneously with each other, and the first microcurrent signal has a first set of frequencies, the second microcurrent signal has a second set of frequencies, the third microcurrent signal has a third set of frequencies, and the fourth microcurrent signal has a fourth set of frequencies, the second set of frequencies being different from the first set of frequencies, the third set of frequencies being different from the first and second sets of frequencies; and the fourth set of frequencies being different from the first, second, and third sets of frequencies. 25. The system of claim 23, wherein the body, the first pair of arms, and the second pair of arms comprise a portable device and the circuitry is housed by the body of the portable device. 26. The system of claim 23, wherein the body, the first pair of arms, and the second pair of arms comprise a portable device and further comprise: a console to which the body is communicatively coupled, wherein the circuitry is housed by the console. 27. The system of claim 17, wherein the body is a grip body having dimensions sized to be held in one hand by a user with average-sized hands, and a user interface accessible from an exterior of the body.