A clip (10) is provided with a body (12,14) that can house a device (16) such as a breathing monitor and that can attach to a garment. The body (12,14) forms a fixed jaw (18) and has a pivot jaw (24) that can pivot to grip the garment between fixed jaw(18) and pivot jaw (24). The clip (10) also has a pivoting lock (38) with a detent (42) that locks the pivot jaw (24) in a closed position, when the lock (38) is in a lock position.

A notification device is provided that includes a sensor pad, and an electronics module generates one or more notifications in response to signals received from the sensor pad. In a first embodiment, the sensor pad includes a pressure sensor for sensing pressure applied by a patient and generating a pressure signal, and conductive tracings for sensing moisture due to incontinence and generating a moisture detection signal when moisture is detected. In another embodiment, an absorbent sensor pad includes a sensor pad for sensing moisture and includes an absorbent chuck having a moisture-impermeable sheet with an absorbent material on an upper surface thereof, wherein the moisture-impermeable sheet has an aperture for receiving the sensor pad. The absorbent sensor pad may be provided in the form of a diaper.

A smart patch including multi-component strands integrated into clothing or other textiles where the strands of the smart patch include sensory elements that can simultaneously measure tactile forces, moisture/wetness, and other signals, such as biopotentials. A sensing system comprising: a first set of strands including a plurality of first multi-component strands, each of the first multi-component strands including a conductive portion and a non-conductive portion; and a second set of strands including a plurality of second multi-component strands, each of the second multicomponent strands including a conductive portion and a non-conductive portion, and a plurality of third multi-component strands, each of the third multicomponent strands including a conductive portion and a non-conductive portion, the third multi-component strands being different than the first multi-component strands and the second multi-component strands.

Provided is an electrolyte sensor that uses conductive elastomer electrodes. Examples of the intended analytes for sensor use include those found in urine, saliva, blood, feces, and spinal fluid, although other analytes exist for electrolyte detection. Conductive elastomer trace electrodes are separated by a channel or gap which can be bridged by an electrolyte and thereby complete an electrical circuit to an alarm or other circuitry. Channel or gap distances vary the level of electrical resistance associated with detecting certain analytes.

The disclosed wireless digital monitor, if is used in a residence for one patient, comprises a detector, a pager, a video camera VC, one or more door detectors DD and a computer PC. Said detector comprises a three axis accelerometer ACC, a sensor for body temperature Tb, a sensor for surrounding temperature Te, a temperature sensor TD for urine detection in diaper, microphone with amplifier MIC, an oximeter with pulse detection and blood pressure meter, two microcontrollers working with software control data from all sensors above and transmit it to a transmitter or a transceiver. Another two temperature sensors TD1 and TD2 for detection of urine and feces are connected to detector. If said monitor is used in a health care facility it comprises a multitude of detectors identical as ones used in a residence, a multitude of pager identical to ones used in a residence, a multitude of door detectors and video cameras, a PC connected to Internet and to all phone lines. Said detector works affixed on diaper if wetness detection in diaper is needed or on pants elastic for all other features. Said pager has a display DSP, a beeper and a vibrator. Most simple monitor contains a said detector and a said pager. Said pager receiver or transceiver receives data from said detector and displays it. In monitor who comprises detector(s), pager(s) and a PC, detector transmits data to PC through its interface I. Then PC transmits its data to said pager(s). Interface I receives data from said door detectors and said video cameras. A door detector comprises two identical units located above on each side of the door. Each unit comprises an optical motion detector MD, a microcontroller and a transceiver TR.

A device and methods for using a device, for determining a passing of flatus is described. The device comprises a sleeve comprising a first porous gas-permeable surface, a second surface attached to the first porous gas-permeable surface defining a pocket within the sleeve, and a flatus detector inserted within the pocket of the sleeve and positioned between the first porous gas-permeable surface and the second surface. The flatus detector may be a dry-surface carbon dioxide detector that irreversibly changes colour upon contact with increased concentrations of CO.sub.2 gas, a chemiresistor, or a near field communication tag. The chemiresistor or near field communication tag may be modified for detecting target gases. The device may be a patch that is affixed to a patient or attached to a garment that is worn by the patient, or a capsule, with a detector disposed therein.

A monitoring system includes a wearable appliance; and a processor coupled to the wearable appliance to analyze vital data or wellness data.

A magnetically held diaper monitor comprises a power supply part and a control part. The power supply part comprises a lower shell, and a battery and a power circuit board embedded in the lower shell. The power circuit board is provided with a plurality of lower magnetic electrodes and two lower magnetic terminals. The control part comprises an upper shell and a control circuit board embedded in the upper shell. The control circuit board is provided with upper magnetic electrodes which are in one-to-one correspondence to the lower magnetic electrodes, and upper magnetic terminals which correspond to the lower magnetic terminals. A diaper sensor is clamped between the power supply part and the control part which are combined into a whole by attraction by means of a magnetic force and is connected to the control part via the magnetic electrodes. The control part obtains a power supply via the magnetic terminals.

A method for collecting and analyzing urine at the time it is released uses a urine collecting tube joined with a canister. Suction is produced in the collecting tube to join the tube with a penis or to the exterior surface of a female urethra orifice. Once suction is achieved the collecting tube stays in place by suction action. When urine flows into the urine collecting tube a sensor triggers a vacuum pump to produce a higher level of suction to flush the urine into the canister where a level sensor determines the quantity of urine received. Various sensors in the canister determine levels of non-urine partials such as occult blood, drugs, salt, and other substances. When urine is no longer detected within the urine tube, the vacuum pump is turned off and a low-level vacuum remains to assure interconnection with the urine tube.

A sensor device includes: a first protective layer; at least one pad positioned on an upper part of at least a part of the first protective layer; at least one sensing pattern layer positioned on an upper part of at least a part of the first protective layer and electrically connected to one of the at least one pad; a flexible body layer positioned on upper parts of the at least one pad and the at least one sensing pattern layer; and a shield plate layer positioned on an upper part of at least a part of the flexible body layer.