Aspects of the present disclosure include a sensor emitter including a reflective cavity for re-directing light to a tissue site. By reflecting light towards the tissue site, the amount of light reaching the tissue site is increased. The increased light can improve parameter measurements taken by a non-invasive physiological sensor by producing a stronger and/or cleaner signal. In an embodiment, the reflective cavity is formed on one or more lead frames of the sensor emitter, wherein the lead frames are capable of transmitting electrical signals to emitting elements coupled to the lead frames. Aspects of the present disclosure also include a sensor component configured to protect connection points of wires to conductive leads on the sensor components by inhibiting flex or bending at the connection points. Connection points can protrude along edges of the sensor component. Aspects of the present disclosure also include techniques and processes for producing low-profile sensors.

FIELD OF THE DISCLOSURE

The disclosure relates to the field of physiological sensors, and more specifically to emitters and detectors for physiological sensors.

BACKGROUND OF THE DISCLOSURE

Patient monitoring of various physiological parameters of a patient is important to a wide range of medical applications. Oximetry is one of the techniques that has developed to accomplish the monitoring of some of these physiological characteristics. It was developed to study and to measure, among other things, the oxygen status of blood. Pulse oximetry—a noninvasive, widely accepted form of oximetry—relies on a sensor attached externally to a patient to output signals indicative of various physiological parameters, such as a patient's constituents and/or analytes, including for example a percent value for arterial oxygen saturation, carbon monoxide saturation, methemoglobin saturation, fractional saturations, total hematocrit, billirubins, perfusion quality, or the like. A pulse oximetry system generally includes a patient monitor, a communications medium such as a cable, and/or a physiological sensor having light emitters and a detector, such as one or more LEDs and a photodetector. The sensor is attached to a tissue site, such as a finger, toe, ear lobe, nose, hand, foot, or other site having pulsatile blood flow which can be penetrated by light from the emitters. The detector is responsive to the emitted light after attenuation by pulsatile blood flowing in the tissue site. The detector outputs a detector signal to the monitor over the communication medium, which processes the signal to provide a numerical readout of physiological parameters such as oxygen saturation (SpO2) and/or pulse rate.

High fidelity pulse oximeters capable of reading through motion induced noise are disclosed in U.S. Pat. Nos. 7,096,054, 6,813,511, 6,792,300, 6,770,028, 6,658,276, 6,157,850, 6,002,952 5,769,785, and 5,758,644, which are assigned to Masimo Corporation of Irvine, Calif. (“Masimo Corp.”) and are incorporated by reference herein. Advanced physiological monitoring systems can incorporate pulse oximetry in addition to advanced features for the calculation and display of other blood parameters, such as carboxyhemoglobin (HbCO), methemoglobin (HbMet), total hemoglobin (Hbt), total Hematocrit (Hct), oxygen concentrations, glucose concentrations, blood pressure, electrocardiogram data, temperature, and/or respiratory rate as a few examples. Typically, the physiological monitoring system provides a numerical readout of and/or waveform of the measured parameter. Advanced physiological monitors and multiple wavelength optical sensors capable of measuring parameters in addition to SpO2, such as HbCO, HbMet and/or Hbt are described in at least U.S. patent application Ser. No. 11/367,013, filed Mar. 1, 2006, titled Multiple Wavelength Sensor Emitters and U.S. patent application Ser. No. 11/366,208, filed Mar. 1, 2006, titled Noninvasive Multi-Parameter Patient Monitor, assigned to Masimo Laboratories, Inc. and incorporated by reference herein. Further, noninvasive blood parameter monitors and optical sensors including Rainbow™ adhesive and reusable sensors and RAD-57™ and Radical-7™ monitors capable of measuring SpO2, pulse rate, perfusion index (PI), signal quality (SiQ), pulse variability index (PVI), HbCO and/or HbMet, among other parameters, are also commercially available from Masimo Corp.

SUMMARY OF THE DISCLOSURE

Aspects of the present disclosure include a sensor emitter including a reflective cavity for re-directing light to a tissue site. By reflecting light towards the tissue site, the amount of light reaching the tissue site is thereby increased. The increased light can improve parameter measurements taken by a non-invasive physiological sensor by producing a stronger and/or cleaner signal. In an embodiment, the reflective cavity is formed on one or more lead frames of the sensor emitter, wherein the lead frames are capable of transmitting electrical signals to emitting elements coupled to the lead frames.

Aspects of the present disclosure also include a sensor component configured to protect connection points of wires to conductive leads on the sensor components by inhibiting flex or bending at the connection points. In an embodiment, connection points protrude along edges of the sensor component.

Aspects of the present disclosure also include techniques and processes for producing low-profile sensors.

DETAILED DESCRIPTION

FIG. 1illustrates an embodiment of a physiological measurement system100having a monitor107and a sensor assembly101. The physiological measurement system100allows the monitoring of a person, including a patient. In particular, the multiple wavelength sensor assembly101allows the measurement of blood constituents and related parameters, including, for example, oxygen saturation, HbCO, HBMet and pulse rate, among others.

In an embodiment, the sensor assembly101is configured to plug into a monitor sensor port103. Monitor keys105provide control over operating modes and alarms, to name a few. A display107provides readouts of measured parameters, such as oxygen saturation, pulse rate, HbCO and HbMet to name a few.

FIG. 2Aillustrates a multiple wavelength sensor assembly200having a sensor203adapted to attach to a tissue site, a sensor cable205and a monitor connector201. In an embodiment, the sensor203is incorporated into a reusable finger clip adapted to removably attach to, and transmit light through, a fingertip. The sensor cable205and monitor connector201are integral to the sensor203, as shown. In embodiments, the sensor203can be configured separately from the cable205and connector201, although such communication can advantageously be wireless, over public or private networks or computing systems or devices, through intermediate medical or other devices, combinations of the same, or the like.

FIGS. 2B-Cillustrate alternative sensor embodiments, including a sensor211(FIG. 2B) partially disposable and partially reusable (resposable) and utilizing an adhesive attachment mechanism. Also shown is a disposable sensor213utilizing an adhesive attachment mechanism. The sensor can include one or more flexible tape layers. In other embodiments, a sensor can be configured to attach to various tissue sites other than a finger, such as a foot or an ear. Also, a sensor can be configured as a reflectance or transflectance device that attaches to a forehead or other tissue surface. The artisan will recognize from the disclosure herein that the sensor can include mechanical structures, adhesive or other tape structures, Velcro® wraps or combination structures specialized for the type of patient, type of monitoring, type of monitor, or the like.

FIG. 3illustrates a block diagram of an exemplary embodiment of a monitoring system300. As shown inFIG. 3, the monitoring system300includes a monitor301, a noninvasive sensor302, communicating through a cable303. In an embodiment, the sensor302includes a plurality of emitters304irradiating the body tissue306with light, and one or more detectors308capable of detecting the light after attenuation by tissue306. As shown inFIG. 3, the sensor302also includes a temperature sensor307, such as, for example, a thermistor or the like. The sensor302also includes a memory device309such as, for example, an electrically erasable programmable read only memory (EEPROM), erasable programmable read only memory (EPROM), flash memory, non-volatile memory or the like. The sensor302also includes a plurality of conductors communicating signals to and from its components, including detector composite signal conductors310, temperature sensor conductors312, memory device conductors314, and emitter drive signal conductors316.

According to an embodiment, the sensor conductors310,312,314,316communicate their signals to the monitor301through the cable303. Although disclosed with reference to the cable303, a skilled artisan will recognize from the disclosure herein that the communication to and from the sensor306can advantageously include a wide variety of cables, cable designs, public or private communication networks or computing systems, wired or wireless communications (such as Bluetooth® or WiFi, including IEEE 801.11a, b, g, or n), mobile communications, combinations of the same, or the like. In addition, communication can occur over a single wire or channel or multiple wires or channels.

In an embodiment, the temperature sensor307monitors the temperature of the sensor302and its components, such as, for, example, the emitters304. For example, in an embodiment, the temperature sensor307includes or communicates with a thermal bulk mass having sufficient thermal conduction to generally approximate a real-time temperature of a substrate of the light emission devices304. The foregoing approximation can advantageously account for the changes in surface temperature of components of the sensor302, which can change as much or more than ten degrees Celsius (10° C.) when the sensor302is applied to the body tissue306. In an embodiment, the monitor101can advantageously use the temperature sensor307output to, among other things, ensure patient safety, especially in applications with sensitive tissue. In an embodiment, the monitor301can advantageously use the temperature sensor307output and monitored operating current or voltages to correct for operating conditions of the sensor302as described in U.S. patent application Ser. No. 11/366,209, filed Mar. 1, 2006, entitled “Multiple Wavelength Sensor Substrate,” and herein incorporated by reference.

The memory309can include any one or more of a wide variety of memory devices known to an artisan from the disclosure herein, including an EPROM, an EEPROM, a flash memory, a combination of the same or the like. The memory309can include a read-only device such as a ROM, a read and write device such as a RAM, combinations of the same, or the like. The remainder of the present disclosure will refer to such combination as simply EPROM for ease of disclosure; however, an artisan will recognize from the disclosure herein that the memory309can include the ROM, the RAM, single wire memories, combinations, or the like.

The memory device309can advantageously store some or all of a wide variety data and information, including, for example, information on the type or operation of the sensor302, type of patient or body tissue306, buyer or manufacturer information, sensor characteristics including the number of wavelengths capable of being emitted, emitter specifications, emitter drive requirements, demodulation data, calculation mode data, calibration data, software such as scripts, executable code, or the like, sensor electronic elements, sensor life data indicating whether some or all sensor components have expired and should be replaced, encryption information, monitor or algorithm upgrade instructions or data, or the like. In an embodiment, the memory device309can also include emitter wavelength correction data.

In an advantageous embodiment, the monitor reads the memory device on the sensor to determine one, some or all of a wide variety of data and information, including, for example, information on the type or operation of the sensor, a type of patient, type or identification of sensor buyer, sensor manufacturer information, sensor characteristics including the number of emitting devices, the number of emission wavelengths, data relating to emission centroids, data relating to a change in emission characteristics based on varying temperature, history of the sensor temperature, current, or voltage, emitter specifications, emitter drive requirements, demodulation data, calculation mode data, the parameters it is intended to measure (e.g., HbCO, HbMet, etc.) calibration data, software such as scripts, executable code, or the like, sensor electronic elements, whether it is a disposable, reusable, or multi-site partially reusable, partially disposable sensor, whether it is an adhesive or non-adhesive sensor, whether it is reflectance or transmittance sensor, whether it is a finger, hand, foot, forehead, or ear sensor, whether it is a stereo sensor or a two-headed sensor, sensor life data indicating whether some or all sensor components have expired and should be replaced, encryption information, keys, indexes to keys or has functions, or the like monitor or algorithm upgrade instructions or data, some or all of parameter equations, information about the patient, age, sex, medications, and other information that can be useful for the accuracy or alarm settings and sensitivities, trend history, alarm history, sensor life, or the like.

FIG. 3also shows the monitor301comprising one or more processing boards318communicating with one or more host instruments320. According to an embodiment, the board318includes processing circuitry arranged on one or more printed circuit boards capable of installation into the handheld or other monitor301, or capable of being distributed as an OEM component for a wide variety of host instruments320monitoring a wide variety of patient information, or on a separate unit wirelessly communicating to it. As shown inFIG. 3, the board318includes a front end signal conditioner322including an input receiving the analog detector composite signal from the detector308, and an input from a gain control signal324. The signal conditioner322includes one or more outputs communicating with an analog-to-digital converter326(“A/D converter326”).

The A/D converter326includes inputs communicating with the output of the front end signal conditioner322and the output of the temperature sensor307. The converter326also includes outputs communicating with a digital signal processor and signal extractor328. The processor328generally communicates with the A/D converter326and outputs the gain control signal324and an emitter driver current control signal330. The processor328also communicates with the memory device309. As shown in phantom, the processor328can use a memory reader, memory writer, or the like to communicate with the memory device309. Moreover,FIG. 3also shows that the processor328communicates with the host instrument320to for example, display the measured and calculated parameters or other data.

FIG. 3also shows the board318including a digital-to-analog converter332(“D/A converter332”) receiving the current control signal330from the processor328and supplying control information to emitter driving circuitry334, which in turns drives the plurality of emitters304on the sensor302over conductors316. In an embodiment, the emitter driving circuitry334drives sixteen (16) emitters capable of emitting light at sixteen (16) predefined wavelengths, although the circuitry334can drive any number of emitters. For example, the circuitry334can drive two (2) or more emitters capable of emitting light at two (2) or more wavelengths, or it can drive a matrix of eight (8) or more emitters capable of emitting light at eight (8) or more wavelengths. In addition, one or more emitters could emit light at the same or substantially the same wavelength to provide redundancy. In one embodiment, the emitters emit light at red and infrared wavelengths, for example 660 nm (R) and 905 nm (IR).

In an embodiment, the host instrument320communicates with the processor328to receive signals indicative of the physiological parameter information calculated by the processor328. The host instrument320preferably includes one or more display devices336capable of providing indicia representative of the calculated physiological parameters of the tissue306at the measurement site. In an embodiment, the host instrument320can advantageously includes virtually any housing, including a handheld or otherwise portable monitor capable of displaying one or more of the foregoing measured or calculated parameters. In still additional embodiments, the host instrument320is capable of displaying trending data for one or more of the measured or determined parameters. Moreover, an artisan will recognize from the disclosure herein many display options for the data available from the processor328.

In an embodiment, the host instrument320includes audio or visual alarms that alert caregivers that one or more physiological parameters are falling below or above predetermined safe thresholds, which are trending in a predetermined direction (e.g., good or bad), and can include indications of the confidence a caregiver should have in the displayed data. In further embodiment, the host instrument320can advantageously include circuitry capable of determining the expiration or overuse of components of the sensor302, including, for example, reusable elements, disposable elements, combinations of the same, or the like. Moreover, a detector could advantageously determine a degree of clarity, cloudiness, transparence, or translucence over an optical component, such as the detector308, to provide an indication of an amount of use of the sensor components and/or an indication of the quality of the photo diode.

An artisan will recognize from the disclosure herein that the emitters304and/or the detector308can advantageously be located inside of the monitor, or inside a sensor housing. In such embodiments, fiber optics can transmit emitted light to and from the tissue site. An interface of the fiber optic, as opposed to the detector can be positioned proximate the tissue. In an embodiment, the physiological monitor accurately monitors HbCO in clinically useful ranges. This monitoring can be achieved with non-fiber optic sensors. In another embodiment, the physiological monitor utilizes a plurality, or at least four, non-coherent light sources to measure one or more of the foregoing physiological parameters. Similarly, non-fiber optic sensors can be used. In some cases the monitor receives optical signals from a fiber optic detector. Fiber optic detectors are useful when, for example, monitoring patients receiving MRI or cobalt radiation treatments, or the like. Similarly, light emitters can provide light from the monitor to a tissue site with a fiber optic conduit. Fiber optics are particularly useful when monitoring HbCO and HbMet. In another embodiment, the emitter is a laser diode place proximate tissue. In such cases, fiber optics are not used. Such laser diodes can be utilized with or without temperature compensation to affect wavelength.

FIG. 4Aillustrates a perspective view of the tissue-facing side of an embodiment of a sensor emitter400. In an embodiment, the sensor emitter is incorporated into a sensor, such as the sensor embodiments described above. The sensor emitter can include one or more emitters or emitting elements402,403, one or more lead frames405,406and an encapsulate410. In an embodiment, the sensor emitter400is a two-lead configuration having two emitters. The emitting elements402,403can be light emitting diodes (LEDs) or other light emitting devices. In one embodiment, the LEDs are configured to transmit light in different wavelengths. InFIG. 4A, the emitting elements402,403are electrically and/or mechanically connected to respective lead frames405,406. In some embodiments, the lead frames are at least partially reflective on the tissue-facing side where the emitting elements are connected, for example, due to the selected lead frame material. In an embodiment, the lead frame's reflectiveness is enhanced by polishing or by plating by another material, for example silver, or the like. The encapsulate410can act as a mechanical support for the lead frames405,406.

The encapsulate410can be formed out of epoxy, plastic, ceramic, or other material and can be formed by processes such as, for example, molding, injecting, rolling, pressing, casting, extruding, or other processes as would be understood by those of skill in the art from the present disclosure. In one embodiment, the encapsulate wholly encloses the emitting elements and portions of the lead frame in order to protect those elements from damage and/or wear. The encapsulate can also serve to mechanically couple elements of the sensor. In one embodiment, the encapsulate forms a low-profile shape, such as a disc, oblong, cuboid, rectangular box, or the like, wherein width and depth are generally larger than height, allowing the creation of low-profile sensor components. In one embodiment, the encapsulate can be transparent or translucent.

The lead frames405,406can be incorporated in the encapsulate410, for example, during manufacture. The lead frame material can include tungsten, copper, silver, silver-filled thermoplastic, nickel, gold, copper, any other conductive material, or other suitable material as would be understood by those of skill in the art from the present disclosure. The encapsulate410can electrically isolate at least portions of the lead frames. For example, the encapsulate can prevent a first lead frame405from electrically connecting with a second lead frame406, for example, by fixing the positions of the frames and maintaining a space between the frames.

In some embodiments, one or more lead frames405,406taken as a whole form a cavity. For example, if the first lead frame405and the second lead frame406were joined together, a cavity having a cavity bottom and cavity sides can be defined by portions407,408of the lead frames. The cavity can be formed in multiple lead frames, with sections of the cavity on each lead frame. The cavity can be shaped similarly to a parabola, a bowl, a frustum, a truncated pyramid or cone, or the like. The cavity sides and/or cavity bottom can be advantageously formed to permit or restrict light to reach the emitting elements. The cavity sides and/or cavity bottom can be flat, rounded, diagonally cut, sloped or formed in other shapes advantageous to either permit or restrict light to reach the emitting elements, to enhance properties of the encapsulate including, but not limited to, structural and manufacturing concerns, to assist in the interface of the emitters with the encapsulate, or to enhance the performance of the sensor emitter400.

In one embodiment, the cavity side can include an angled portion407of a lead frame405while a cavity bottom can include a generally flat portion408of the lead frame405, on which an emitting element402can be attached. The angled portion can form an arc or one or more sides around the generally flat portion. The angled portion and/or flat portion can be formed on an at least semi-reflective surface of the lead frame in order to reflect light outward from the emitting elements into the tissue site, thereby directing more light generated by the emitting elements towards the tissue site. Thus, usable light can be increased and/or light diffusion can be reduced.

In an embodiment, the encapsulate410acts as an electrical insulator allowing multiple lead frames405,406to be electrically insulated from each other. In one embodiment, a first wire bond414electrically connects a first emitting element402on a first lead frame405to a second lead frame406. A second wire bond415can connect a second emitting element403on the second lead frame406to the first lead frame405. In one embodiment, the emitting elements comprise LEDs or diodes that allow current to flow in only one direction. Thus, in one embodiment, current from the first lead frame405to the second lead frame406flows on one wire bond, while current from the second lead frame to the first lead frame flows on another other wire bond. In the described configuration, the wire bonds and diodes form an inverse parallel circuit. As the lead frames in the described configuration are electrically insulated from each other by the encapsulate and electrically connected only through the uni-directional wire bonds and emitting elements, the first or the second emitting element can be selectively activated based on the direction of the current flow.

In some embodiments, the lead frame405,406can protrude outward to the sides of the encapsulate410. The protruding portions419,420can allow electrical connections to be formed with wires, conductive substrates, or other conductive material in order to transmit electrical signals to and/or from a monitor and/or provide power to the sensor component. Electrical coupling can be by, for example, soldering, wire bonding, die bonding, or other suitable forms of electrical connection. In an embodiment, the emitting elements402,403can be placed near the connection points in order to allow the connecting wires and/or coupling material to act as a heatsink for the emitting elements.

FIG. 4Billustrates an exploded view of the sensor emitter embodiment ofFIG. 4A. The sensor emitter can include one or more lead frames405,406, one or more emitting elements402,403, and one or more wire bonds414,415.

FIG. 5Aillustrates a top view of the sensor emitter embodiment ofFIG. 4. The sensor emitter400can be electrically coupled in any way to wires505,506or other conductive material via the connection points509,510on the lead frame protrusions419,420. For example, the sensor emitter can be mounted to wires or to a sensor surface with embedded leads. The wires505,506are configured to connect with the sensor emitter400such that the connection points509,510are between a distal514and a proximal516end of the sensor emitter relative to a sensor cable and/or sensor cable connector. In one embodiment, the wires505,506are configured to lie generally parallel to an axis518from the distal514to the proximal516end of the sensor emitter. The encapsulate can function as a spacer and/or insulator between the wires and/or leads, preventing electrical bridging between the wires and/or leads.

In one embodiment, the bottom of the sensor emitter400is attached to an at least semi-flexible or flexible substrate, such as a tape layer, of a sensor. The flexible substrate can include conductive leads or wires. For example, the flexible substrate can comprise a flexible circuit. In one embodiment, the encapsulate410material is generally rigid or semi-rigid, inhibiting flexing of a portion of the wires505,506and/or flexible substrate around the sensor emitter. In some embodiments, the lead frame protrusions419,420can extend for some length generally parallel to the axis518and/or wires505,506in order to further inhibit flexing around the sensor emitter. For example, the lead frame protrusion419can have a generally straight portion519extending in a direction along the axis518with one or more supports520connecting the generally straight portion to the lead frame405. By positioning the connection points on the sides of the sensor emitter, the connection points can be advantageously protected from flexing of the wires or substrate by the sensor emitter body. Thus, by inhibiting flexing at the connection points, the durability of the sensor is enhanced, for example, by inhibiting disconnection of wires505,506with the sensor emitter400, limiting stress on the connection points, and/or reducing wear and tear at the connection points.

FIG. 5Billustrates a cross sectional view of the sensor emitter embodiment ofFIG. 5A. In the illustrated embodiment, the first lead frame405is electrically isolated from the second lead frame406by the encapsulate410. Protruding portions419,420of the lead frames can extend past the encapsulate, providing a connection point for wires or cables. A first emitting element402can be positioned on the first frame405and a second emitting element403can be positioned on the second frame406. The first frame and second frame can form a cavity configured to reflect light towards the tissue site. The cavity can be formed by an angled portion407and a flat portion408of the lead frames405,406. In an embodiment, the angled portion of the lead frames can extend to or near the top surface of the encapsulate in order reduce light diffusion or escape, which can cause signal artifacts in parameter measurements.

In some embodiments, the sensor emitter can be coupled to a sensor portion522, such as a sensor body, a tape layer, or the like, on the sensor emitter bottom or side opposite the tissue site. In some embodiments, another sensor portion, such as a cover, tape layer, or the like, can cover the top or tissue facing side of the sensor emitter. In an embodiment, wires are configured to run between the protruding portions419,420and the sensor portion522, placing the wires away from the tissue site in order to reduce patient discomfort. The placement of the wires between the two portions can also provide additional mechanical support for the wires, inhibiting disconnection of the wires from the sensor emitter.

FIG. 5Cillustrates a side view of an embodiment of a reverse wire bond connection. A reverse wire bond414can be used to reduce the height of the sensor. In a reverse wire bond, a ball bond525is formed on the lead frame406while a wedge or tail bond530is formed on the emitting element402on the other lead frame405. As the lead frame406is lower than the top of the emitting element, by placing the ball bond on the lead frame, the height535of the reverse wire bond is lower than a regular wire bond where the ball bond is on the emitting element. Thus, the reverse wire bond allows the formation of lower-profile sensors compared to a regular wire bond. In one embodiment, the height535of the lead frame406and wire bond525defines a minimum possible profile of the sensor.

FIG. 6illustrates a depiction of light waves emanating from one embodiment of the sensor emitter. In some embodiments, the emitting elements602,603emit light in multiple directions. Some of the light615(“direct light”) can be directly transmitted from the emitting elements to the tissue site. Some of the light620(“indirect light”) is originally transmitted to a different direction from the tissue site but can be redirected towards the tissue site by elements of the sensor emitter625,630, such as portions of lead frames or other reflective surfaces. For example, portions of the lead frames can be angled towards the tissue site in order to redirect light.

By redirecting light, the amount of usable light, including direct and indirect light, can be increased. The increased usable light can improve parameter measurements by producing a stronger and/or cleaner signal. For example, the detector can receive more light attenuated by the tissue and/or receive less light not attenuated by the tissue.

Advantageously, by using a reflective cavity, a weaker emitting element can be used while providing the same amount of usable light as a stronger emitting element not using a reflective cavity. In some cases, the weaker emitting element can be cheaper, require less power, have a longer operating life, or provide some other benefit in comparison to the stronger emitting element. For example, an emitting element with a lower power draw can increase the operating time of the sensor when connected to a stored power source, such as a battery.

In one embodiment, the lead frame can be comprised of material configured to meet particular performance specifications (“specced material”), such a reflective quality. If the lead frame material is specced, the variability of the light from the sensor emitter can be reduced in comparison to unspecced material. Generally, large portions of a sensor are comprised of low-cost, unspecced material, such as tape layers, adhesive layers, plastic materials, or the like. Thus, by reflecting much or most of the light from the sensor emitter with a specced reflective surface, the variability can be reduced. For example, if the sensor emitter did not use a specced reflective surface but simply allowed light emanating from the emitter to reflect off of unspecced portions of the sensor, the variability of the light reaching the tissue site can increase. More consistent light can generate a “cleaner” parameter measurement at the tissue site by reducing artifacts or otherwise improving the signal generated by the sensor.

FIG. 7illustrates a cross-sectional view of an embodiment of the sensor emitter700including a single lead frame705. A first conductive lead709connects to a first emitting element710and a second conductive lead713connects to a third emitting element714. A third conductive lead708can be formed as part of the lead frame705. Current on the first lead can activate the first emitting element and current on the second lead can activate the second emitting element. In one embodiment, the first and second leads can be anodes while the third lead is a cathode common to the emitting elements.

FIG. 8illustrates a cross-sectional view of an embodiment of the sensor emitter including a metallization layer. The sensor emitter800comprises a cavity805formed in the encapsulate810. A metallization layer815,816is applied onto the cavity. In one embodiment, the metallization layer is formed into electrically distinct sections815,816. The metallization layer sections can be electrically connected by wire bond819,820and diodes824,826, such as LEDs, as described above. In one embodiment, additional encapsulate material830is applied onto the metallization layer and emitting elements in order to form a protective layer over the emitter elements. In one embodiment, portions of the metallization layer816can be exposed to allow connection to wires or other conductive material.

FIG. 9illustrates a perspective view of a tissue facing side of an embodiment of a detector900. The detector comprises a sensor905and a first lead frame910and a second lead frame915. The detector can be electrically and/or mechanically coupled to the first lead frame910. An encapsulate920can surround the sensor and portions of the lead frames.

In some embodiment, the lead frames910,915are electrically isolated by the encapsulate920. A wire bond935can connect the sensor905to the second lead frame915. Lead frames can be incorporated in the encapsulate, for example, during manufacture.

In some embodiments, each lead frames can protrude outward to the sides or edges of the encapsulate1020. The protruding portions1025,1030allow electrical connections to be formed with wires, conductive substrates, or other conductive material for transmitting electrical signals to and/or from a monitor. Electrical coupling can be, for example, soldering, wire bonding, die bonding, or other suitable forms of electrical connection.

FIG. 10illustrates a top view of the detector900embodiment ofFIG. 9. As described above forFIG. 5A, by forming the leads alongside the detector between a distal1010and a proximal1005of the detector, flex at the connection points to wires or other conductive material can be inhibited.

FIG. 11illustrates a cross-sectional view of the detector embodiment ofFIG. 9. The detector905on the first frame910can be connected to the second frame by a reverse wire bond935. The reverse wire bond allows the formation of a lower-profile sensor as described above. In one embodiment, the height of the lead frame915, wire bond935, and thickness of the encapsulate920determine the profile height1105of the detector component. In some embodiments, the detector can be coupled to a sensor portion1110, such as a sensor body, a tape layer, or the like, on the detector side opposite the tissue site. In some embodiments, another sensor portion, such as a cover, tape layer, or the like, can cover the tissue site side of the detector.

Of course, the foregoing embodiments are given by way of example and not limitation. Other variations of encapsulate formation, sensor emitter configuration, and/or detector configurations will be understood by those of skill in the art from the present disclosure. For example, the cavity can be different shapes, sizes, or have different relative positions to the encapsulate. Cavity sides can be straight on some sides and a different shapes such as diagonal on other sides. The relative height of a sensor component or cavity can change. In another example, the sensor emitter and/or detector can have three, four, or more leads and/or three, four or more lead frames. These combinations do not provide an extensive list of possible substitutions or modifications that will be apparent to the skilled artisan in view of the disclosure herein.

FIG. 12illustrates a flow chart of an embodiment of a manufacturing process1200for assembling a sensor component, such as an emitter or detector. The process1200can be used for manufacturing groups of components, such as the components used in the sensor embodiments described above. For example, the process1200may be used, in whole or in part, by one or more machines for manufacturing sensors. The one or more machines can be automated or controlled by an operator. In one embodiment, one or more blocks of the process1200can be performed manually by a person.

The process1200begins with block1205, where frame material is provided. In some embodiments, the frame material can be partially shaped or formed. For example, a cavity can be formed in the frame material.

In block1210, a sub-component, such as an LED, sensor component, or the like is coupled to the frame material. For example, the sub-component can be die bonded to the metallic frame using epoxy or solder. Coupling can be mechanical and/or electrical and can be accomplished by attachment methods such as, for example, painting, attaching, gluing, adhering, etching, fusing, mechanically fastening, or other attachment methods as would be understood by those of skill in the art from the present disclosure. Alternatively, the emitter can be grown or manufactured directly on the frame material. The epoxy or solder can be allowed to set before proceeding.

In block1215, the wire bond is laid. The wire bond can connect the sub-component to the frame material. In some embodiments, the wire bond is a reverse wire bond as described above.

In block1220, an encapsulate or mold compound, such as thermoset epoxy, polysiloxanes, thermoplastic, or the like is provided. The encapsulate can placed over the sub-component and lead frame and/or molded to form a desired shape. In some embodiments, the encapsulate is a transparent or translucent substance, allowing light to pass through. The encapsulate can wholly or partially cover the sub-component and frame material. As described above, the portions of the lead frame can protrude outside the encapsulate. The encapsulate can be allowed to set before proceeding with block1225.

In block1225, the sensor component can be deflashed in order to etch out the sensor component. For example, the lead frame can be etched out of the frame material.

In block1230, the sensor component can be trimmed out of excess frame material. Optionally, portions of the sensor component can be further shaped or formed. For example, the connection points of the sensor leads can be formed from the lead frame.

Those skilled in the art will recognize from the disclosure that other sensor components such as those previously disclosed, or entire detector and/or emitter assemblies can be manufactured together to reduce cost or increase efficiency. Manufacturing components in groups reduces costs, for example, by reducing the number of assembly steps. In an embodiment, a group of lead frames is stamped from a single sheet of lead frame material and later separated into individual components. A group of sensor components, such as detectors or emitters, can be designed for batch assembly, for example, with cutouts that allow for ease in separation of individual sensor components such as by mechanically snapping the sensor components apart or by otherwise applying separating force. Those skilled in the art will recognize from the disclosure that in addition to cutouts, for example, the group of sensor components can be scored, cut, grooved, or otherwise prepared for separation to aid in manufacturing a group of sensor components.

Although the foregoing disclosure has been described in terms of certain preferred embodiments, other embodiments will be apparent to those of ordinary skill in the art from the disclosure herein. For example, although disclosed with respect to a pulse oximetry sensor, the ideas disclosed herein can be applied to other sensors such as ECG/EKG sensor, blood pressure sensors, or any other physiological sensors. Additionally, the disclosure is equally applicable to physiological monitor attachments other than a sensor, such as, for example, a cable connecting the sensor to the physiological monitor. Additionally, other combinations, omissions, substitutions and modifications will be apparent to the skilled artisan in view of the disclosure herein. It is contemplated that various aspects and features of the disclosure described can be practiced separately, combined together, or substituted for one another, and that a variety of combination and subcombinations of the features and aspects can be made and still fall within the scope of the disclosure. For example, the configurations described for the sensor emitter can be applied to the detector or other sensor components and vice versa. Furthermore, the systems described above need not include all of the modules and functions described in the preferred embodiments. Accordingly, the present disclosure is not intended to be limited by the recitation of the preferred embodiments, but is to be defined by reference to the appended claims.