The adoption of wearable consumer electronics, or “smart clothing,” is currently on the rise. Biosensing garments, a subset of wearable electronics, are designed to interface with a wearer of the garment, and to determine information such as the wearer's heart rate, rate of respiration, activity level, body positioning, etc. Such properties can be measured via a sensor assembly that contacts the wearer's skin and that receive signals from the wearer's body. Through these sensor assemblies, signals are transmitted to one or more sensors and/or microprocessors for transduction, analysis, etc. A drawback of many biosensing garments on the market today, however, is that they do not achieve acceptable signal quality (e.g., the signal is too noisy). Also, many biosensing garments contain bulky electronic hardware, wires, and other components that can make them uncomfortable to the wearer. As such, there is a general need for biosensing garments with improved performance and/or that are more comfortable to wear.
Embodiments described herein relate generally to devices, systems and methods for optimizing and masking compression in a biosensing garment. In some embodiments, a biosensing garment includes a first fabric portion and a second fabric portion. The first fabric portion has a first compression rating and an inner surface of the first fabric portion incudes a sensor assembly configured to be placed in contact with the skin of the user. The second fabric portion extends from the first fabric portion and has a second compression rating that is less than the first compression rating. In some embodiments, a third fabric portion extends from the first fabric portion and has a third compression rating that is less than the first compression rating. In some embodiments, the second compression rating is substantially similar to the third compression rating.
Embodiments described herein relate generally to devices, systems and methods for optimizing and masking compression in a biosensing garment. In some embodiments, a biosensing garment includes a first fabric portion and a second portion. The first fabric portion has a first compression rating, and an inner surface of the first fabric portion includes a sensor assembly configured to be placed in contact with the skin of the user (for example, disposed about a circumferential region of a user). The second fabric portion extends from the first fabric portion and has a second compression rating that is less than the first compression rating. In some embodiments, a third fabric portion extends from the first fabric portion and has a third compression rating that is less than the first compression rating. In some embodiments, the second compression rating is substantially the same as the third compression rating.
In some embodiments described herein, a biosensing garment is a shirt, a bra, or a tank top that includes a main chest portion configured to apply compression to at least a perimeter of a chest of a user. An upper chest portion is disposed above the main chest portion when worn by the user, and is configured to apply compression to the user in a region above a perimeter of the chest of the user. An upper abdominal portion is disposed below the main chest portion when worn by the user, and is configured to apply compression to at least a perimeter of an upper abdomen of the user. A lower abdominal portion is disposed below the upper abdominal portion when worn by the user, and is configured to apply compression to a region below at least a perimeter of the upper abdomen of the user. A sensor assembly is disposed on an interior surface of at least one of the main chest portion, the upper chest portion, the upper abdominal portion, and the lower abdominal portion, and is configured to make contact with the user's skin. In such embodiments, each of the main chest portion, the upper chest portion, the upper abdominal portion, and the lower abdominal portion is configured to apply a respective amount of compression to the user that varies across the main chest portion, the upper chest portion, the upper abdominal portion, and the lower abdominal portion, for example when worn by an appropriately-sized user.
As described herein, biosensing garments are a subset of “wearable electronics” that are designed to interface with a wearer (also referred to herein as a “user”) of the biosensing garment and to capture data and/or determine information about the wearer based upon the body's own output (e.g., movement, electrical signals, chemicals present on the skin, temperature, etc.). This information can be captured in “real time,” for example, when the wearer is exercising, sleeping, at rest, or when the wearer wishes to check one or more of the wearer's vital signs (the vital signs including, but not limited to, heart rate, respiration/breathing rate, temperature, blood pressure, etc.). A wearer may also wish to track his or her activity level, body positioning, geographical location, etc., for example, over time to enable viewing of compiled information at a later time. The wearer's physiological properties are often measured via sensors (also referred to herein as “sensor assemblies”) of the biosensing garment (e.g., sensors can be embedded therein, integrally-formed therewith, applied thereto, and/or attached thereto). These sensors are often designed to contact the wearer's skin and to receive signals (e.g., electrical, acoustic, temperature, and/or chemical data, and/or the like) from the wearer's body and/or to convert physical phenomena into electrical signals. Through these sensors, signals can be transmitted to one or more sensors and/or microprocessors for transduction, analysis, etc. For example, in some embodiments, the sensors can be substantially similar to or the same as the sensors and/or electrodes included in U.S. Patent Publication No. 2014/0343390, titled “Textile Blank With Seamless Knitted Electrode,” (“the '390 Publication”), the disclosure of which is incorporated herein by reference in its entirety.
There are a number of drawbacks of biosensing garments on the market today. For example, many biosensing garments do not achieve good signal quality because of noise (e.g., the signal-to-noise ratio is below a desirable or optimal level). Such noise can originate, for example, as a result of the environment (lack of moisture, low salinity, etc.) and/or due to motion of the wearer (e.g., friction or breaking contact with the skin of the wearer). These environmental and motion factors can result in the degradation and/or disruption of the contact between the sensor assembly and the wearer's skin, and thus the transmission and/or fidelity of the transmitted signal(s). As a result, downstream signal processing may be significantly more complicated and/or take longer to process, and/or the data may not correlate well with the physiological parameters that the device is designed to measure. In addition, many biosensing garments (for example, wearable therapeutic devices) fail to function properly unless they are sufficiently “tight,” particularly in the vicinity of the sensor assembly. To ensure proper functioning, many biosensing garment manufacturers include straps, cinches, and/or other mechanical implements that can be adjusted until the proper degree of “tightness” is achieved. In other cases, biosensing garments are designed and/or manufactured to have a tight fit in the location(s) where the sensor assembly is located, while the remainder of the garment is much looser. For example, starting with a design for a traditional (i.e., non-“smart”) garment having a “standard” fit, a plan is made for the introduction of electronic components into one or more locations on the garment, and only those regions of the garment are correspondingly modified so that they will fit more snugly, while the remainder of the garment design remains unchanged. Such designs can lead to unwanted shifting of the garment during activities such as running. Additionally, some biosensing garments require a user to “pre-wet” the garment (e.g., with plain water) if immediate measurements are desired and the user is not yet sweating. One example of a heart rate monitoring chest strap requiring pre-wetting in the absence of sweat is the chest strap accessory for the XBR55 Fitness Bike sold by Spirit Fitness. The Owner's Manual for the XBR55 Fitness Bike instructs users that sweat is the best conductor to measure “very minute heart beat electrical signals,” but that plain water can also be used to “pre-wet” the electrodes. Specifically, it is suggested that the user pre-wet two ribbed oval areas on the reverse side of the belt, and on both sides of a transmitter that is positioned in the middle of the user's torso, facing away from the user's chest.
Embodiments of a biosensing garment described herein provide several advantages over known biosensing garments on the market today such as: improved continuity and consistency of signal, reduced noise (and, correspondingly, higher signal-to-noise ratio), a lower propensity for sensing regions of the garment to shift, improved overall comfort and wearability, and reduced irritation and/or injury due to friction or cutting of the edges of compressive regions into a wearer's skin.
Although in some instances increasing the compression rating (e.g., “tightness”) of a biosensing garment can improve signal quality and other design considerations, it can also have some of the negative consequences described above, including, for example, friction-induced noise and discomfort to the wearer. In other words, when only certain portions of a garment are tight fitting the wearer feels the discontinuity in “compression” of the garment (e.g., an abrupt change between a “tight” region and a “loose” region), and he correspondingly perceives that it is uncomfortable to wear. This perceived low level of comfort on the part of the wearer may stem, in part, from objective physical discomfort, and/or in part due to the psychological and/or neuropsychological implications of the biosensing garment's intrusion of the wearer's personal space (e.g., peripersonal space). There is therefore a tradeoff between a design of the biosensing garment that has the best electrical or “functional” performance, and a design that attains the highest level of comfort to the wearer.
In some embodiments, the present disclosure seeks to strike a balance between these two categories of consideration, in order to obtain an optimized biosensing garment that is both adequately functional as well as comfortable. Specifically, the present disclosure is directed to optimizing the compression levels used for sensing purposes (i.e., in the vicinity of the sensor assembly and/or associated electronics, such that good contact and good signal quality are achieved) while also optimizing the distribution of compression across the garment so that the wearer is comfortable. The more comfortable the biosensing garment is to wear, the more likely a user is to wear it, thus improving its marketability as well as market adoption, consumer satisfaction, patient compliance (e.g., in medical applications), etc.
Biosensing garments according to the present disclosure have applicability in a wide of range of applications and industries. For example, biosensing garments of the present disclosure may include athletic apparel (e.g., shirts, jerseys, vests, jackets, pants, shorts, sports bras, brassieres, swimsuits, hats, helmets, goggles, socks, shoes, footwear, headsets, watches, bracelets, underwear, athletic supporters, gloves, collars, neckbands, headbands, visors, scarves, mittens, arm sleeves, arm bands, leg sleeves, leg bands, head bands, waist bands, chest plates, tights, and/or the like). Embodiments of the present disclosure may also be used in medical applications (e.g., shirts, pants, hats, vests, bracelets, watches, undergarments, diapers, hospital gowns, bandages, smocks, girdles, blankets, and/or the like). Embodiments of the present disclosure may also be used in body re-contouring applications for aesthetic purposes.
Embodiments described herein seek to optimize the “comfort” (and/or “wearability”) of a biosensing garment, as perceived by a wearer. The “comfort level” of a given biosensing garment, as generally perceived by a wearer, may depend on one or more of the following factors: absolute compression level (e.g., as measured in mmHg), relative compression level (e.g., with respect to one or more adjacent regions of the garment having a different compression level), rate of change of compression level (e.g., compression drop-off, compression variation, and/or compression gradient), number of compression regions on the garment, discrete vs. gradient nature of the compression variation, method of achieving the compression (e.g., circular knitting, application of elastomers to the surface of the textile, weave pattern, and/or choice of fiber or other raw material. In some embodiments, the “comfort level” and/or “optimization” of the biosensing garment of the present disclosure may (in addition to, or as an alternative to, the compression level engineering described above) also be customizable to a particular user. For example, the perceived “comfort level” of a biosensing garment may depend upon one or more of the following: size of the wearer, proportionality and/or body shape of the wearer, age of the wearer, gender of the wearer, medical condition(s) of the wearer (e.g., pregnancy, hypertension, circulation problems, respiratory problems, superficial wounds or injuries, claustrophobia, etc.), sensitivity of the wearer, type of activity for which the garment is designed, the activity level of the target wearer (e.g., sedentary, moderate activity, high-impact aerobic activity, etc.), the wearer's lung capacity, the wearer's propensity to sweat (e.g., wearers having hyperhidrosis vs. those that do not), and/or the wearer's personal preference.
In designing garments of the disclosure for optimal compression distribution, a number of factors should be taken into account, including the sizing of the garment as it relates to the body shape and size of the intended wearer. Size charts may be developed for specific body types, shapes and sizes. Differences in body type, shape and/or size (e.g., wide shoulders or “V-shape,” deviations in waistline, muscle mass, fat mass, body mass index (BMI), abnormal body shapes, and/or the like) each may cause variation in the degree of fit of the garment. The height of a wearer can also affect the fit of a garment, for example in that a “chest” region of a biosensing shirt will be positioned higher on the chest of a tall wearer (when worn) than it would on a shorter wearer (when worn), for the same biosensing shirt.
Referring now to
In some embodiments, the sensor assembly 120 includes one or more biosensing electrodes, one or more sensing elements/components, interconnect, control circuitry, and/or the like can be configured to make contact with a wearer's skin and is electrically coupled to an interconnect (not shown) such as, for example, wires, metal traces, and/or conductive fibers. The interconnect may be protected by an adjacent, electrically-insulating layer. The interconnect electrically connects the sensing elements to one or more connectors for coupling to a “controller” or “processing module,” configured to analyze the electrical signals received from the sensing elements and correlate the signals to one or more physiological parameters of the user. In some embodiments, the processing module may include a transmitter configured to wirelessly communicate raw and/or processed sensor data to a remote location for display and/or further processing, said remote location including, for example, a wristwatch, smartphone (e.g., via an app), PDA, PC, GPS network, “the cloud,” etc. The processing module may also include one or more of: a memory, a processor (e.g., a microprocessor, a microcontroller, an ASIC chip, an ARM chip, and/or a programmable logic controller (PLC)), a transimpedance amplifier circuit configured to convert current to an amplified voltage, an analog to digital converter (ADC) configured to digitize a received voltage, a filtering circuit (e.g., low-pass, high-pass, band pass, and/or combination thereof). Where the processing module comprises a processor, the processor may be programmed to execute algorithms, e.g., to perform signal processing.
As described herein, the sensor assembly 120 of the biosensing garment 100 can be positioned substantially within a circumferential region of a user U such as, for example, the circumferential region of at least a portion of the wearer's chest as well as his or her upper back. Such positioning can be desirable, for example, in embodiments where signals from the heart are measured (e.g., in electrocardiography, or “EKG” or “ECG” applications), since such signals are traditionally “transthoracic” (across the thorax or chest). Such configurations are also useful when measuring the electrical activity of chest and/or back muscles. In some embodiments contemplated by the present disclosure, the sensor assembly 120 can be positioned in other regions of a wearer's anatomy, for example including (but not limited to) the thigh, ankle, waist, neck, arm, ankle, head, feet, wrist, finger, palm, etc. In some embodiments, positioning of the sensor assembly in one or more of the aforementioned regions can be favorable over other locations with regard to signal quality, reliability, and/or relevance, depending upon what is being measured. For example, in some embodiments, a thigh strap may include the sensor assembly, for purposes of measuring activity of the wearer's quadriceps and hamstring muscles. In some embodiments, the sensor assembly 120 can include other types of sensors including, for example, electrical sensors (e.g., bio-potential, breath rhythm, sweat conductivity, etc.), electrochemical sensors (e.g., pH, ion, etc.), organic sensors (e.g., protein detection, etc.), electrocardiogram (ECG or EKG) sensors, heart rate sensors, breathing rate sensors, temperature sensors and/or other physical biosensors, chemical sensors, acoustic wave sensors, IR sensors, UV sensors, humidity sensors, moisture sensors, ion sensors (e.g., capable of detecting the presence of chloride, sodium, potassium, calcium, magnesium, etc.), motion sensors, accelerometers, glucose detectors, pressure sensors, and/or the like. In some embodiments, the sensor assembly 120 may be configured to perform skin conductance measurements in order, for example, to determine an Electrodermal Response (EDR) and/or an Electrodermal Level (EDL). The sensor assembly 120 can include more than one sensing elements/components, interconnects, control circuitry, and/or the like.
The biosensing garment 100 also includes a second fabric portion 130 extending from the first fabric portion 110 and having a second compression rating that is less than the first compression rating. For example, in an embodiment where the biosensing garment 100 is a shirt and the first fabric portion 110 is configured to be positioned about the chest of the user, the second fabric portion 130 can extend downward from the first fabric portion 110 such that it is configured to be positioned about an abdominal region of the user. The second compression rating of the second fabric portion 130 may be selected such that a “comfort level” of the biosensing garment 100, as perceived by a user U, is increased. The comfort level may be improved, for example, by a less abrupt change in compression between adjacent fabric portions of the biosensing garment 100 due to the selection of the first and second compression ratings. The less abrupt change can result in a lower perceived intrusion of a user's U personal space (e.g., peripersonal space), or a reduced irritation and/or injury from friction or cutting of the edges of compressive regions into a wearer's skin. The comfort level, as described above, may also depend upon one or more of the following: size of the wearer, proportionality and/or body shape of the wearer, age of the wearer, gender of the wearer, medical condition(s) of the wearer (e.g., pregnancy, hypertension, circulation problems, respiratory problems, superficial wounds or injuries, claustrophobia, etc.), sensitivity of the wearer, type of activity for which the garment is designed, the activity level of the target wearer (e.g., sedentary, moderate activity, high-impact aerobic activity, etc.), the wearer's lung capacity, the wearer's propensity to sweat (e.g., wearers having hyperhidrosis vs. those that do not), and/or the wearer's personal preference.
In some embodiments, the biosensing garment 100 can include a third fabric portion 140 extending from the first fabric portion 110 and having a third compression rating that is less than the first compression rating. For example, in an embodiment where the biosensing garment 100 is a shirt and the first fabric portion 110 is configured to be positioned about the chest of the user, the third fabric portion 140 can extend upward from the first fabric portion 110 such that it is configured to be positioned about an upper chest portion of the user U. In some embodiments, the third compression rating can be substantially similar to the second compression rating so that the user U “feels” a uniform compression gradient extending away from the first fabric portion 110.
In some embodiments, the biosensing garment 100 can include a fourth fabric portion 150 extending from the second fabric portion 130 and having a fourth compression rating that is less than the second compression rating. For example, in an embodiment where the biosensing garment 100 is a shirt and the second fabric portion 130 is configured to be positioned about the abdominal region of the user, the fourth fabric portion 150 can extend downward from the second fabric portion 130 such that it is configured to be positioned about a waist region of the user U. In some embodiments, the fourth compression rating can be less than the second compression rating so that the user U “feels” a “gradual” compression gradient extending away from the first fabric portion 110, through the second fabric portion 130, and to the fourth fabric portion 150. In some embodiments, the fourth compression rating can be substantially less than the second compression rating so that the user U can more easily put the shirt on and take the shirt off. Said another way, since the bottom portion of a shirt has to fit over the shoulders of the user U when the shirt is being put on and taken off, the bottom portion can be designed to be relatively looser to increase usability of the shirt without sacrificing the compression “masking” or the signal quality of the biosensing garment 100. In further embodiments (not shown), any number of additional fabric portions may be included in the biosensing garment 100 to achieve the desired “masking” result, as disclosed herein. Techniques for knitting biosensing garments of the disclosure can be found, by way of example, in the '390 Publication incorporated by reference above. In some embodiments of the disclosure, including the biosensing shirt of
As described herein, the sensor assembly 120 of the biosensing garment 100 can be positioned substantially within a circumferential region of a user U such as, for example, the circumferential region of at least a portion of the wearer's chest as well as his or her upper back. Such positioning can be desirable, for example, in embodiments where signals from the heart are measured (e.g., in electrocardiography, or “EKG” or “ECG” applications), since such signals are traditionally “transthoracic” (across the thorax or chest). Such configurations are also useful when measuring the electrical activity of chest and/or back muscles. In some embodiments contemplated by the present disclosure, the sensor assembly 120 can be positioned in other regions of a wearer's anatomy, for example including (but not limited to) the thigh, ankle, waist, neck, arm, ankle, head, feet, wrist, finger, palm, etc. In some embodiments, positioning of the sensor assembly in one or more of the aforementioned regions can be favorable over other locations with regard to signal quality, reliability, and/or relevance, depending upon what is being measured. For example, in some embodiments, a thigh strap may include the sensor assembly, for purposes of measuring activity of the wearer's quadriceps and hamstring muscles. In some embodiments, the sensor assembly 120 occupies a single fabric portion (e.g., the first fabric portion 110). In other embodiments, the sensor assembly 120 occupies multiple fabric portions of the biosensing garment 100 (e.g., two or more of the first fabric portion 110, the second fabric portion 130, the third fabric portion 140, the fourth fabric portion 150, and/or any number of additional fabric portions). For example, a sensor of the sensor assembly 120 may be positioned in the first fabric portion 110, the sensor being electrically coupled to wiring or “interconnect” (also part of sensor assembly 120) extending from the first fabric portion 110 through the second fabric portion 130 to the fourth fabric portion, where the wiring or “interconnect” are electrically coupled to one or more connectors (also part of sensor assembly 120) which may subsequently be used for making connection to a controller or “processing module.”
In some embodiments, a biosensing garment 100 is configured to “mask” (i.e., to obscure or render less perceivable) the presence of the sensor assembly 120, such that the user U is unaware or less aware of its presence (e.g., so that the garment is more comfortable). This masking may be accomplished by fabricating the garment such that it exerts a substantially uniform amount of compression to the wearer across all portions of the garment, thereby making it difficult or impossible for the user to “feel” the edge(s) of the sensor assembly. In some embodiments, masking may be accomplished by fabricating the garment such that it exerts a maximum amount of compression in the first fabric portion 110 including at least a portion of the sensor assembly 120, and the regions of the garment immediately adjacent to the first fabric portion 110 (e.g., the second fabric portion 130 and optionally the third fabric portion 140) are configured to exert an amount of compression that is slightly lower than the compression exerted by the first fabric portion 110 (i.e., for the same user U). In still further embodiments, masking may be accomplished by fabricating the garment such that it exerts a maximum amount of compression in the first fabric portion 110 including at least a portion of the sensor assembly, and the regions of the garment immediately adjacent to the first region (e.g., the second fabric portion 130 and optionally the third fabric portion 140) are configured to exert an amount of compression that varies along one or more axes extending away from the first region.
The variation in compression may, for example, include a linear reduction (from the maximum value, immediately adjacent to the first region, to a different, lower value, at a predetermined distance away from the first region). In other embodiments, the variation in compression may be in the form of a “compression gradient.” As used herein, a compression gradient refers to a progressive and/or gradual (i.e., “degressive”) change of one or more properties from a first location to a second location of the biosensing garment (e.g., from a proximal end to a distal end of the biosensing garment). The change may be an increase or a decrease. In other embodiments, the reduction may be non-linear, step-wise, or any other suitable pattern that eliminates any abrupt transition from the first region, having the maximum compression value, to any other region of the garment. The amount of compression (i.e., the compression “rating”) may vary: (1) substantially linearly, both from the electrode assembly upward (e.g., from the chest upward, in the direction of the neck of the user), as well as from the electrode assembly down (e.g., from the chest downward, in the direction of a lower hem of the garment); (2) non-linearly in any direction (e.g., laterally, longitudinally, or radially); (3) linearly in any direction; and/or (4) by a certain pre-determined percentage or absolute value. In some embodiments, the compression rating varies in different ways in different directions in a single biosensing garment. For example, the compression rating may gradually decrease from the chest in the direction of the shoulders along a first distance, then steeply drop off to a minimum value at the shoulders, and then gradually increase along the sleeves of the biosensing garment, moving from the shoulder downward to the wrists of the user U. In some embodiments, a combination of the above compression variation schemes is used in the manufacture of a single biosensing garment.
In some embodiments, garment compression can be measured with a pneumatic measuring device (also “compression tool”) that is equipped with a flat probe into which 2 cc of air are inflated before each measurement. The probe is placed between the skin and the garment at different locations on the body, and compression values and/or changes (e.g., when a wearer is breathing) for various body positions and movements can thus be determined. In some embodiments, the compression measurement is made under an electrocardiography (ECG) electrode pad. Compression values or “ratings” may be measured in mmHg. Compression ratings may correspond to one or more “comfort levels” as perceived by a wearer. For example, if the chest area is noticeably tighter to a user than the rest of the garment, the comfort rating is lower than when the overall garment has tighter compression that ‘masks’ the feel of tightness of the band. The signal quality of a biosensing element within garments of varying compression configurations may also be measured and analyzed. For example, a correlation between compression ratings and quality of a transduced signal may be determined. This correlation may be used to calculate an optimum range of compression ratings for a particular garment that gives an optimum signal quality yet remains comfortable to wear.
Methods of imparting levels of compression (compression “ratings”) and/or gradients to biosensing garments of the disclosure include (but are not limited to): circular or “tubular” knitting (e.g., on a cylindrical knitting machine), flat knitting (e.g., flat bed knitting) and/or other compressive stitching, cut-and-sew techniques, the application of flexible materials such as elastomers (e.g., silicone) to the garment (e.g., in patterns such as bands, either before or after the garment has been formed), the use of compressive yarns, straps, materials, zippers and/or other fasteners, the use of bladder systems inflatable by gaseous or liquid means, the selection of thread denier (e.g., of a laid-in thread or core material), the choice of one or more materials (e.g., the combination of core-spun yarn with a laid-in elastomeric thread, the combination of two or more yarn types, etc.), adjusting the tension (e.g., pre-tension) of one or more integrated threads, variation of a stitch size, variation of loop tightness, variation of knit type (e.g., compressive stitch, overlap stitch, moss type stitch, non-run stitch), variation of cross-sectional area (e.g., of a tubular knit), the use of elastics, the use of reinforcing materials (e.g., yarn), and/or the like. Embodiments of the present disclosure may incorporate one or more different techniques for imparting the disclosed compression ratings to a single biosensing garment. In some embodiments, compression ratings are inherent to a base textile used in the fabrication of a biosensing garment. In some embodiments, compression ratings are achieved at least in part by modifying a base textile by one or more of the techniques herein described.
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As indicated by the differences in shading throughout
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With further reference to Table 1 below,
In some embodiments, a compression rating of 0 mmHg is qualitatively described as having “no compression,” and/or a “lowest” value of compression; a compression rating of from 1-2 mmHg is qualitatively described as having “low” compression; a compression rating of from 3-4 mmHg is qualitatively described as having “moderate” compression; a compression rating of from 5-6 mmHg is qualitatively described as being in a “functional range”; a compression rating of from 7-8 mmHg is qualitatively described as having “high” compression; and a compression rating of 9 mmHg or greater is qualitatively described as having “very high” compression.
Although the compression ratings provided in Table 1 above, and described with reference to
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As described herein, the first fabric portion 910 has a first compression rating and an inner surface that includes at least a portion of the sensor assembly 920 configured to be placed in contact with the skin of the user U. The sensor assembly 920 is disposed on the inner surface of the biosensing bra 900 and is positioned substantially within an inner circumferential region of the biosensing bra 900 such that, when worn, the electrodes of the sensor assembly 920 make contact with the chest and/or back regions of the user's U body. As described above, such a configuration is suitable, for example, in ECG applications to monitor a user's heart rate.
The biosensing bra 900 includes a second fabric portion 930 extending from the first fabric portion 910, configured to be positioned near the bottom regions of the cups in the biosensing bra 900 so as to support the breasts of the user U. In some embodiments, the second fabric portion 930 has a second compression rating that is less than the first compression rating. In some embodiments, the second compression rating that is greater than the first compression rating. In some embodiments, the second compression rating is substantially equal to the first compression rating. The biosensing bra 900 also includes a third fabric portion 940 extending from the second fabric portion 930 to the sides of the cups of the biosensing bra 900 so as to extend the compression region from the second fabric portion 930. In some embodiments, the third fabric portion 940 has a third compression rating that is less than the second compression rating. In some embodiment, the third compression rating is greater than the second compression rating. In some embodiments, the third compression rating is substantially equal to the second compression rating. The biosensing bra 900 also includes a fourth fabric portion 950, which extends upwards from the second fabric portion 930 and third fabric portion 940. The second fabric portion 930, the third fabric portion 940, and the fourth fabric portion 950 are configured to impart a gradual transition from a relatively higher compression regions of the cups of the biosensing bra 900 where support is desirable, to regions of relatively lower compression regions of the cups of the biosensing bra 900 where support is not necessary. In some embodiments, the fourth fabric portion 950 has a fourth compression rating that is less than the second compression rating and/or the third compression rating. In some embodiments, the fourth compression rating is substantially equal to the second compression rating and the third compression rating. The biosensing bra 900 also includes a fifth fabric portion 960 on the straps having a fifth compression rating, and a sixth fabric portion 980 on the back having a sixth compression rating. In some embodiments, the fifth and sixth compression ratings can be very low in terms of absolute compression rating. In some embodiments, the fifth compression rating can be greater than the sixth compression rating. In some embodiments, the fifth compression rating can be less than the sixth compression rating. In some embodiments, the fifth compression rating is substantially equal to the sixth compression rating. In some embodiments, the fifth and sixth compression ratings can be essentially zero meaning that the fabric is “form fitting,” but does not apply any compression to the skin of the user. As shown in
As indicated by the differences in shading throughout
In some embodiments, the intermediate regions 915a and 915b (collectively, intermediate regions 915) can be the regions of fabric with compression ratings that are in-between those of the conjoining fabric portions. For example, the first fabric portion 910 and the second fabric portion 930 can include an intermediate region 915a such that the compression ratings can gradually change from the first fabric portion 910 to the second fabric portion 930. This means the compression rating of the intermediate region 915a can be somewhere between the compression ratings of the first fabric portion 910 and the second fabric portion 930. In some embodiments, the two third fabric portions 940 in the middle of the biosensing bra 900 (i.e., between the two cups) can include an intermediate region 915b such that the compression ratings can gradually go from the compression rating of the third fabric portion 940 to the other third fabric portion 940. In this case since both the third fabric portions 940 have the same compression rating, the compression rating of the intermediate region 915b can be the same or substantially as the compression rating of the third fabric portion 940. In some embodiments, the intermediate regions 915 can have a compression rating that is substantially similar to adjacent fabric portions to provide a relatively gradual compression gradient throughout the bra 900 to maximize comfort for the user U.
In some embodiments, the intermediate regions 915a and 915b can have a substantially low compression rating. For example, the two third fabric portions 940 in the middle of the biosensing bra 900 (i.e., between the two cups) can include an intermediate region 915b such that the compression ratings can gradually go from the compression rating of the third fabric portion 940 to the other third fabric portion 940. But since the intermediate region 915b can have a relatively low compression rating, the compression can be discontinuous. In another word, the two cups of the biosensing bra 900 can be substantially compressive, yet they can be independently compressive, where the compression of the two cups can be isolated from each other by having the intermediate region 915b with a relatively low compression rating in between.
In some embodiments, the biosensing bra can include one or more compression modification systems 970a and/or 970b (collectively, compression modification system 970). As described above, the first fabric portion 910 is configured to be disposed about a torso of a user U, and is configured to exert a first level of compression (corresponding to the first compression rating) to the user U when the biosensing bra 900 is worn by the user U in a first configuration. The compression modification system 970a can allow the user U to tighten or loosen the chest band 912 to transition the biosensing bra 900 to a second configuration to exert a second level of compression. The second level of compression can be greater than or less than the first level of compression. The compression modification system 970a can allow the user U to modify the biosensing bra 900 to achieve a more comfortable fit and/or to improve signal quality from the sensor assembly 920. Similarly, the compression modification system 970b can allow the User to modify the compression in the cup region of the biosensing bra to achieve a more comfortable fit and/or to improve support.
Exemplary test data comparing a properly fitting biosensing shirt according to some embodiments with a biosensing shirt that is too large for a user (“User 1”) is provided in Table 2 below. In both cases, the same user (User 1) is wearing the shirt under test, and each of the XS and the S shirt employ the same sensor type. User 1 is normally an XS (i.e., XS is the size that properly fits User 1), while a size S is too large for User 1 (i.e., it fits “loosely”). As shown in Table 2, the signal quality for the XS biosensing shirt, when worn by User 1, is higher than the signal quality for the S biosensing shirt, when worn by User 1.
In some embodiments, biosensing garments may comprise one or more textiles (e.g., cloths, fabrics etc.) consisting of a network of natural or synthetic fibers. The textiles may derive from one or more sources, including plant sources (e.g., cotton, flax, hemp, jute, modal, bamboo, piria, ramie, milkweed stalk, lyocell, polyamide, etc.), animal sources (e.g., wool, silk, milk proteins, etc.), mineral sources (e.g., asbestos, glass fibres, etc.), and/or synthetic sources (e.g., nylon, polyester, polyamide, acrylic, aramid fibre, spandex, polyurethane, olefin fibre, ingeo, polylactide, lurex, carbon fibre, etc.). Strands from which the textiles are composed may include coatings such as waxes. Such textiles may be formed from one or more processes, including (but not limited to): weaving, knitting (e.g., circular knitting), crocheting, forming from tow, braiding, felting, thermal and/or mechanical bonding, and/or the like. When a textile is formed by knitting, any suitable knitting pattern can be used, for example, circular knitting (also known as “knitting in the round,” creating a seamless tube), single, double, jersey, interlocked, mock rib, ribbed, two-way stretch, or any other suitable knitting pattern or combination thereof.
Although embodiments described herein and depicted in the figures show placement of electrodes in the vicinity of a wearer's chest, other locations (i.e., corresponding with other portions of a user's anatomy) can also be suitable, and are contemplated by this disclosure. By way of non-limiting example, one or more electrodes may be positioned on a shoulder region, arm region, wrist region, abdominal region, torso region, back region, side region, or any other location on a biosensing garment that allows for the detection of biosignals.
Although embodiments described herein and depicted in the figures show particular exemplary distributions of compression regions (e.g., in “bands”), other shapes and positioning of compression regions (whether substantially uniform in compression value or variable in compression value) are also contemplated by this disclosure. By way of non-limiting example, compression regions of the disclosure may have an asymmetric, circular, polygonal, circumferential, patch, or any other suitable shape. Also, by way of non-limiting example, compression regions of the disclosure may be positioned on a shoulder region, arm region, wrist region, abdominal region, torso region, or any other location on a biosensing garment
As used herein, the term “electrode” refers to a conductor whose function is to interact with a part of a circuit. In some embodiments, the electrode can be knitted from a conductive yarn such as, for example, XSTATIC® silver metallized yarn, stainless steel thread, polyaniline yarn, and/or any other suitable conductive yarn. In some embodiments, the electrode comprises SCHOELLER® wool. The electrode of the present disclosure may comprise any suitable electrical conductor, including metals such as (but not limited to) copper, silver, steel (e.g., stainless steel), tin, lead, tin/lead (SnPb), gold, platinum, aluminum, nickel, zinc, combinations or alloys thereof, and/or the like, carbon (including metallized, non-metallized, mediated and non-mediated), electroceramics, and/or conductive polymers. Electrodes of the present disclosure may take the form of inks, films (e.g., screen-printed, vacuum-deposited, painted, and/or the like), foils, plates, thin films, thick films, rivets, connectors (e.g., snaps), threads, wires, combinations thereof, and/or the like. In some embodiments, electrodes of the present disclosure may include “chemically modified electrodes” (CMEs), “ion-selective electrodes” (ISEs), and/or any electrode suitable for use in electrochemical applications. In some embodiments, the electrode itself may serve as and/or comprise a sensing element.
The electrodes of the present disclosure can have any suitable size or shape such as, for example, square, rectangular, circular, elliptical, oval, polygonal, or any other suitable shape. In some embodiments, a padding member can be disposed on the outer surface of a fabric layer adjacent to an electrode. The padding member can be formed from any suitable material such as, for example, rubbery foam, a sponge, memory foam, a 3-D knitted porous fabric (e.g., a 3-D knitted mesh or 3-D spacer knit), any other suitable material or combination thereof. The padding member can, for example, be configured to urge the electrode towards the skin of the user, for example, to enable efficient contact of the electrode with the skin of the user. In some embodiments, the padding member can be also be configured to prevent rubbing of the electrode against the fabric layer adjacent to the electrode, thereby reducing noise. In some embodiments, the padding member can be disposed between a fabric layer and an adjacent electrode.
In some embodiments, biosensing garments described herein may be designed to include and/or interface with one or more sensors or sensor assemblies, including (but not limited to) electrical sensors (e.g., bio-potential, breath rhythm, sweat conductivity, etc.), electrochemical sensors (e.g., pH, ion, etc.), organic sensors (e.g., protein detection, etc.), electrocardiogram (ECG or EKG) sensors, heart rate sensors, breathing rate sensors, temperature sensors and/or other physical biosensors, chemical sensors, acoustic wave sensors, IR sensors, UV sensors, humidity sensors, moisture sensors, ion sensors (e.g., capable of detecting the presence of chloride, sodium, potassium, calcium, magnesium, etc.), motion sensors, accelerometers, glucose detectors, pressure sensors, strain sensors, on-skin sensors, and/or the like. In some embodiments, the sensor assemblies described herein are configured to perform skin conductance measurements in order, for example, to determine an Electrodermal Response (EDR) and/or an Electrodermal Level (EDL). Sensors according to the present disclosure may be in the form of discrete parts mounted to, embedded in, or located apart from the biosensing garment. In some embodiments, sensors according to the present disclosure may comprise a coating on at least a portion of the textile material and/or on the fibers from which the textile or “fabric” material is formed.
In some embodiments, biosensing garments described herein, by virtue of the operation of their respective sensor assemblies and, optionally, with further processing of signals received and transmitted by the sensor assemblies, determine quantitative data about a user/wearer, such as (but not limited to): heart rate, heart rate variability, activity level, activity schedule, sleep schedule, calorie expenditure, breathing rate, blood pressure, blood sugar, VO2 max, oxygen saturation, hydration level, skin temperature, and/or other physiological data. In some embodiments, biosensing garments described herein, by virtue of the operation of their respective sensor assemblies and, optionally, with further processing of signals received and transmitted by the sensor assemblies, determine one or more qualitative properties of a user/wearer, such as (but not limited to): state of health, physiological condition (e.g., hydration, sleep deficit, sleep patterns), cognitive mental state, tension, and/or emotional mental state (e.g., happiness, sadness, concentration, confusion, frustration, disappointment, hesitation, cognitive overload, focus, degree of engagement, attentiveness, boredom, confidence, trust, delight, satisfaction, worry, curiosity, and/or the like).
As used herein, the terms “about” and “approximately” generally mean plus or minus 10% of the value stated, for example about 250 μm would include 225 μm to 275 μm, about 1,000 μm would include 900 μm to 1,100 μm.
As used herein, the term “knit” or “knitted” refers to layers, portions, or components included in a textile-based electrode system that are formed by interlacing yam or threads in a series of connected loops with needles.
As used herein, the term “electrode” refers to an electrical conductor configured to contact a non-metallic surface including a skin of a user (e.g., a human or an animal) and measure electrical signals corresponding to one or more physiological parameters of the user.
As used herein, the terms “continuously,” “seamless” and “seamlessly” refer to the integration of layers, portions, or components included in a textile-based electrode system without any seams, interruptions, transitions, or indications of disparity resulting in a visually appealing appearance which improves a user comfort by reducing chafing and pressure on the skin that are usually caused by seams.
While various embodiments of the system, methods and devices have been described above, it should be understood that they have been presented by way of example only, and not limitation. Where methods and steps described above indicate certain events occurring in a certain order, those of ordinary skill in the art having the benefit of this disclosure would recognize that the ordering of certain steps may be modified and such modification are in accordance with the variations of the invention. Additionally, certain of the steps may be performed concurrently in a parallel process when possible, as well as performed sequentially as described above. The embodiments have been particularly shown and described, but it will be understood that various changes in form and details may be made.
This application is a division of U.S. Non-Provisional patent application Ser. No. 15/052,263, filed Feb. 24, 2016 and titled “Apparatus, Systems and Methods for Optimizing and Masking Compression in a Biosensing Garment,” which claims priority to, and the benefit of, U.S. Provisional Patent Application Ser. No. 62/126,134, filed Feb. 27, 2015 and titled “Apparatus, Systems and Methods for Optimizing and Masking Compression in a Biosensing Garment,” the entire disclosures of each of which are hereby incorporated herein by reference in their entireties for all purposes.
Number | Date | Country | |
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62126134 | Feb 2015 | US |
Number | Date | Country | |
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Parent | 15052263 | Feb 2016 | US |
Child | 16855844 | US |