SAMPLING AND STORAGE REGISTRY DEVICE FOR BREATH GAS ANALYSIS
Methods and systems are described to obtain and analyze one or more gas samples from the breath of a person, and organizing the samples in a sample registry for subsequent analysis. This technique solves the various problems that are associated with targeting an individual breath for analysis, and allows for additional versatility and options in the analysis process.
This application claims the benefit of U.S. Provisional Application Nos. 61/763,896 and 61/794,254 filed on Feb. 12, 2013 and Mar. 15, 2013, respectively, the disclosures of which are hereby incorporated by reference in their entireties.
FIELDDescribed herein are devices and methods for the analysis of breath exhalant for diagnostic purposes. More specifically, devices and methods are described for sampling and analyzing a relevant portion of the breathing cycle, for example end-tidal gas, from a person's breath. The devices and method may be used, for example, to correlate the gas analysis to an underlying physiologic condition for diagnostic, monitoring or screening purposes, or in conjunction with a therapeutic treatment.
BACKGROUNDCertain metabolites and chemicals produced in or entering the body and blood stream are excreted in the breath. The level in the body or blood stream may be determined by measuring it in the breath. For example, breath carbon monoxide (CO) levels may be measured to detect and monitor underlying disorders such as hematological disorders and conditions, metabolic disorders, and environmental and behavioral problems. For example, end-tidal CO can be correlated to blood CO, which can be indicative of hemolysis, smoking or inhalation poisoning. In order to measure end-tidal CO, alveolar gas may be collected non-invasively from the exhaled breath of a patient, by capturing the portion of the breath at the end of exhalation. The captured end-tidal gas can then be analyzed for its CO concentration thus completing the non-invasive measurement. Typically, a correlation exists between the end-tidal gas level and the level of the metabolite or chemical in the body or blood, for example a 1:1 ratio or some other ratio.
Typically, but not always, two types of sensors are used; a breath monitoring sensor and a gas analysis sensor. For breath monitoring, in order to precisely target and collect the appropriate section of the breathing pattern, typically a real-time or nearly instantaneous sensing technology is used to measuring the breathing pattern, such as an infrared CO2 sensor. Or other sensors such as airway pressure sensors, flow sensors, oxygen gas sensors, chest impedance sensors, acoustic sensors, vibration sensors, and diaphragmatic movement and innervation sensors. For gas composition analysis, in order to meet the requisite clinical accuracy, the available sensors that meet this purpose typically require a substantial signal response time that is significantly longer than the duration of a single breath. Therefore, in accurate systems, the gas analysis step may take place after the breathing pattern monitoring and gas sample collection step.
There may be some significant limitations with conventional breath analysis systems. Specifically, in a first limitation it has been reported that due to irregular breathing patterns, obtaining and analyzing a proper end-tidal gas sample is often problematic and in some cases not possible. Determining whether or not a particular breath is a “normal” breath consisting of a valid alveolar gas composition in its exhalation phase, often cannot be determined until after a series of breaths or a substantial duration of breathing is analyzed. “Capnography”, by J. S. Gravenstein, Michael B. Jaffe, Nikolaus Gravenstein describes numerous paradigms where breath analysis would be useful but cannot be completed due to underlying irregularities. Most of the analyses shown in the book assume “artifact free” waveforms, and the authors acknowledge that this is rarely the case, especially in diseased patients, intubated patients, and other commonly occurring clinical events. In addition, clinical trials related to breath analysis typically have to exclude patients with irregular, erratic or unpredictable breathing patterns. Medtronic Capnography brochure MIN 3012492-001/CAT 21300-001569 displays a series of capnographic waveforms all of which routinely occur in clinical settings as a result of disease, airway obstruction, apnea, inadequate breath, etc. Many of these conditions would make detailed measurements of chemical composition of breath difficult, inaccurate, or impossible. Further, as is obvious to anyone skilled in the art, analysis of gases such as CO, H2 and nitric oxide may be an order of magnitude more complex than the measurement of CO2 concentration, the subject of most of the references cited above. This means that when CO2 concentration cannot be reliably obtained, than most probably no other gas concentration measurements can be obtained either.
In a second limitation, it has been realized that conventional breath gas analysis devices may either miss important information by: (a) measuring only one individual breath, thereby missing potentially very useful information contained in a different breath; or by (b) volumetrically combining all the breaths within a series of breaths in a chamber, thereby diluting the information contained in an important breath. The systems may also be limited in that if measuring all the breaths within a series of breaths, valid and invalid breaths are combined thus potentially diluting the accuracy of the result.
Several issued U.S. patents and published patent applications discuss state of the art in breath analysis. U.S. Pat. No. 6,544,190 B1 discloses that the system described “provides a means to reject test data when excessive breath variability likely makes the test unreliable.” Medtronic application Ser. No. 11/588,990, publication number US 2008/0009762 A1 describes an algorithm to analyze capnographic data by providing a non-linear fit to the shape of the capnography curve, but does not address any underlying chemical analysis of the breath. Similarly, U.S. Pat. No. 6,428,483 (issued to Oridion) describes a capnographic waveform analysis system which considers angles of the waveform, transition points, and other characteristics, but it operates on one breath at a time, in real time, and has no storage mechanism. Next, U.S. Pat. No. 6,733,463 describes a nitric oxide measurement system which tries to control the exhalation flow rate, but this also is not applicable to breaths with variable flow and rate characteristics. U.S. Pat. No. 8,021,308 describes a method of isolating the end tidal portion of the breath, by finding the transition point between exhalation and inhalation, and then analyzing that portion of the breath, in real time. While that invention has adjustable analysis methodology based on the breath rate, it is limited to identifying a transition point or portion of the current breath (such as end tidal), and it does not provide a means for subsampling the stored volume, or subsequent adaptation of beginning and ending sampling points. Further, it doesn't provide means for storing multiple full breaths. U.S. Pat. No. 6,582,376 describes a measurement system for alveolar breath analysis, and provides a sample volume to store a portion of the breath based on a threshold, but it does not allow for separate identification of individual breaths.
SUMMARYDescribed herein are methods, systems and devices that analyze gases, particles and other substances in the breath by organizing a physical registry of a series of breaths and/or sections from individual and/or multiple breaths, characterizing the breath types and breath section types within that registry, organizing the different segments within that registry, and conducting the desired analysis on the desired breaths and/or desired breath sections, in real time, or after a period of time has elapsed.
To address the problems associated with conventional state-of-the-art approaches, a more powerful and useful gas analysis technology in some variations employs a breath storage and breath information registry. For example in some variations, the breath analyzer may analyze in detail a series of breaths, and collect multiple samples and subsamples from that series, then after the breathing pattern and breath types of the series are analyzed and the information organized in a registry, the system may either combine the samples together for further analysis, or combine and/or segregate them in different ways for further analysis, or separate them for individual different types of analyzes, all based on a characterization and comparison of the breath types in the series of breaths.
In a first variation, gas from a breath or series of breaths are drawn from a patient and the breath types and breath section types of each section of gas are defined analyzing using a breathing signal from a breathing sensor, preferably but not always a fast, instantaneous or near-instantaneous breathing sensor, and the requisite algorithms. The breathing signal contains indications of timing markers in a breath cycle, and may, for example, be obtained using IR sensors tuned to a breathing gas type, or multiple gas types, such as in capnography. The breath gas itself may be captured into a sample collection compartment with a small cross-sectional flow path to reduce mixing between constituent sections of gas from different sections of a breath, and between breaths. The different constituent sections may be cataloged in a registry, based on the breathing signal. Desired sections may be analyzed to determine the level of a gas of interest.
In a second variation, the breath gas is captured into different sample collection compartments each with a small cross-sectional flow path to reduce mixing between constituent sections of gas. The different constituent sections of the different compartments may be cataloged in a registry, using the breathing signal. Desired sections may be analyzed by different sensor types to determine the level of different gases of interest.
In a third variation, breath gas is captured into a sample collection compartment with a small cross-sectional flow path to reduce mixing between constituent sections of gas. The different constituent sections may be cataloged in a registry. Desired sections may be analyzed by various different sensors to determine the level of various gases in question.
In a fourth variation, breath gas is captured into different sample collection compartments each with a small cross-sectional flow path to reduce mixing between constituent sections of gas. The different constituent sections of the different compartments may be cataloged in a registry. Desired sections may be analyzed to determine the level of a substrate in question.
In additional variations, an appropriate gas such as ambient gas or an inert gas is inserted in between different constituent sections of gas in the sample compartment to help separate the sections. In other variations, a particular portion of a breath such as the end-tidal portion, is collected and collated from multiple breaths and analyzed. In other variations, different pneumatic configurations of flow pumps, sample collection compartments and substrate analysis sensors are described.
In some variations, a breath gas capture device does not include an analysis sensor, and the sample compartment is transported to a sensor after the gas is captured. For example, the gas may be captured at the patient bedside, doctor's office or remotely at home or in the field, then transported to a laboratory for analysis. In other variations, different sections of the breath may be organized in the registry for appropriate analysis. For example, upper airway analytes may contain the sample of interest, or middle airway analytes, or lower airway analytes, or alveolar analytes, or a combination thereof, depending on the diagnostic test(s) desired. The system can be fully programmable by the user, such that the user can enter the type of analysis to be undertaken, and the system then executes the necessary control systems and algorithms to collect, organize and analyze the necessary samples. In other variations, the test subject may be commanded by the user or the system to perform certain breathing maneuvers while the breath samples are being collected. For example, the user can submit a breath hold, or a deep breath, or a shallow breath, or a normal tidal volume breath, or combinations thereof. This may increase the resolution of the system in cases in which an analyte indicative of the disease in question is most noticeable in a certain breath type. The system may validate and accept or reject each sample based on measuring the actual submitted breath and comparing against expected breathing pattern signals. Or, the test subject may be subjected to a challenge maneuver for example in which he or she is instructed to breathe or inject a tracer element or provoking agent, and in which the resulting analytes in the breath change as a result, indicative of the underlying pathology or disease or syndrome under question. It should be understood that the systems described in this disclosure may include obtaining samples from a non-cooperative subject as well as cooperative subjects.
In a fifth variation, a breath sampling and analysis apparatus includes: a sensor that detects a gas parameter for determining the start point and end point of different breath portions; a pump that draws at least one gas sample from a person's breath; and a sample compartment that stores breath portions each in separate physical locations.
In a sixth variation, the breath analysis apparatus of the fifth variation further includes an analyzer that analyzes separately each of the stored breath portions for a parameter.
In a seventh variation, the sample compartment of the fifth variation comprises a capillary channel in which the different breath portions occupy sections of volume of the channel, and wherein the sections are end to end.
In an eighth variation, the separate physical locations of the fifth variation comprises separate sample containers, and wherein the apparatus further comprises a manifold system to divert the different breath portions into the separate sample containers.
In a ninth variation, the each sample container of the eighth variation comprises a respective bypass tube and a respective sensor.
In a tenth variation, the each sample container of the eighth variation comprises a respective sensor, and wherein the apparatus comprises one bypass tube for all sample containers.
In an eleventh variation, the breath analysis apparatus of the eighth variation comprises one sensor for all sample containers and one bypass tube for all sample containers.
In a twelfth variation, the breath portions of the fifth variation are from a single breath.
In a thirteenth variation, the breath portions of the fifth variation are from different breaths.
In a fourteenth variation, the breath analysis apparatus of the fifth variation includes an analyzer that analyzes one or more breath portions for a first parameter.
In a fifteenth variation, the analyzer of the fourteenth variation analyzes another one or more breath portions for a second parameter.
In a sixteenth variation, the breath analysis apparatus of the fifth variation includes an analyzer that analyzes the breath portions together.
In a seventeenth variation, the breath analysis apparatus of the fifth variation includes an analyzer that analyzes the breath portions separately.
In an eighteenth variation, the breath analysis apparatus of the fifth variation includes a processor to identify a desired breath portion by receiving measurements of a breathing pattern characteristic, and wherein the sample compartment receives gas from the desired portion of the breath.
In a nineteenth variation, a breath sampling and analysis apparatus includes: a sensor that identifies the beginning and end of a breath, thereby dividing the breath pattern into different breath portions identifying the beginning and end of different breath portions; a vacuum pump that draws a gas sample from a person's breath into at least one sample tube, the sample tube comprising gas from at least one breath and at least one breath portion; and a computer to identify the location of gas in the sample tube corresponding to the beginning and end of the breath, and corresponding to the beginning and end of the breath portion.
In a twentieth variation, the breath analysis apparatus of the nineteenth variation includes an analyzer that analyzes the stored breath samples for a parameter.
In a twenty-first variation, a breath sampling apparatus includes: a sampling tube configured to prevent mixing within the tube of breath exhaled by a patient; an inlet valve and an outlet valve coupled to the sampling tube, wherein the inlet valve and outlet valve together are operable to capture the breath exhaled by the patient within the sampling tube; and an inlet tube fluidly coupled to the sampling tube, wherein the inlet tube is operable to directly receive the breath exhaled by the patient, and wherein the inlet valve is further operable to isolate the sampling tube from the inlet tube.
In a twenty-second variation, the breath sampling apparatus of the twenty-first variation includes a processor for determining a position in the storage tube of a segment of the exhaled breath.
In a twenty-third variation, the breath sampling apparatus of the twenty-first variation includes an in-flow sensor for determining one or parameters of the exhaled breath in the sampling tube.
In a twenty-fourth variation, the in-flow sensor of the twenty-third variation includes one or more selected from the group consisting of a flow rate sensor, a MEMS fluidic sensor, an optical bench, and a mass spectrometer.
In a twenty-fifth variation, the processor of the twenty-third variation determines the position of the segment by referencing a record of parameters of the exhaled breath in the sampling tube, wherein the record is populated by the one or more parameters determined by the in-flow sensor.
In a twenty-sixth variation, the one or more parameters of the twenty-fifth variation includes one or more selected from the group consisting of a time profile of the exhaled breath entering the sampling tube, a flow rate profile of the exhaled breath, a pump-speed profile of a pump coupled to the sampling tube, a pressure profile of the exhaled breath, a carbon dioxide concentration profile of the exhaled breath, and a temperature profile of the exhaled breath.
In a twenty-seventh variation, the breath sampling apparatus of the twenty-first variation includes an analyzing system for determining a characteristic of a segment of the exhaled breath after it is captured in the sampling tube.
In a twenty-eighth variation, the analyzing system of the twenty-seventh variation includes one or more storage containers, wherein the one or more storage containers are fluidly coupled to the sampling tube, and wherein the outlet valve is operable to isolate the sampling tube from the one or more storage containers.
In a twenty-ninth variation, the analyzing system of the twenty-seventh variation an exhaust for venting segments of the exhaled breath.
In a thirtieth variation, the analyzing system of the twenty-seventh variation analyzes a characteristic of one or more gases selected from the group consisting of anesthesia gases, poisonous gases, metabolic gases resulting from alcohol use, metabolic gases resulting from drug use, metabolic gases resulting from disease, and hydrogen.
In a thirty-first variation, the breath sampling apparatus of the twenty-first variation includes a pump fluidly coupled to the sampling tube, wherein the outlet valve is operable to isolate the sampling tube from the pump.
In a thirty-second variation, the pump of the thirty-first variation has a variable speed.
In a thirty-third variation, the pump of the thirty-first variation has a reversible flow direction.
In a thirty-fourth variation, the sampling tube of the twenty-first variation has a capillary tube.
In a thirty-fifth variation, the sampling tube of the twenty-first variation is configured to store a plurality of exhaled breaths.
In a thirty-sixth variation, the plurality of exhaled breaths of the thirty-fifth variation are exhaled by a plurality of patients.
In a thirty-seventh variation, a method of analyzing one or more breaths includes: storing the one or more breaths in a sampling tube configured to prevent mixing of the breath within the sampling tube; recording one or more characteristics of the breath stored in the sampling tube; identifying one or more segments of the breath stored in the sampling tube, wherein the identification of the one or more segments is based upon the recorded characteristics of the breath; extracting the one or more segments from the sampling tube; and analyzing the one or more segments.
In a thirty-eighth variation, the recording the one or more characteristics of the breath of thirty-seventh variation includes determining the one or more characteristic with an in-flow sensor.
In a thirty-ninth variation, the in-flow sensor of the thirty-eighth is configured to determine one or more selected from the group consisting of a time profile of the exhaled breath entering the sampling tube, a flow rate profile of the exhaled breath, a pump-speed profile of a pump coupled to the sampling tube, a pressure profile of the exhaled breath, a carbon dioxide concentration profile of the exhaled breath, and a temperature profile of the exhaled breath.
In a fortieth variation, the extracting the one or more segments of the breath in the thirty-seventh variation includes exhausting unwanted segments.
In a forty-first variation, the extracting the one or more segments of the breath in the thirty-seventh variation includes storing the one or more segments in one or more storage containers.
In a forty-second variation, the extracting the one or more segments of the breath in the thirty-seventh variation includes returning unwanted segments to the sampling tube using a pump with a reversible flow.
In a forty-third variation, the analyzing the one or more segments of the breath in the thirty-seventh variation includes analyzing a characteristic of one or more gases selected from the group consisting of anesthesia gases, poisonous gases, metabolic gases resulting from alcohol use, metabolic gases resulting from drug use, metabolic gases resulting from disease, and hydrogen.
In a forty-fourth variation, the analyzing the one or more segments of the breath in the thirty-seventh variation includes analyzing at least one selected from the group consisting of breath segments from a plurality of breaths, an end-tidal concentration of one or more breaths, and an alveolar concentration of one or more breaths.
In a forty-fifth variation, the storing the one or more breaths in the thirty-seventh variation includes storing the one or more breaths in a capillary tube.
In a forty-sixth variation, the storing the one or more breaths in the thirty-seventh variation includes storing a plurality of breaths from a plurality of patients.
In a forty-seventh variation, the storing the one or more breaths in the thirty-seventh variation includes drawing the breath into the sampling tube with a pump.
In a forty-eighth variation, the pump of the forty seventh-variation has a variable flow rate.
In a forty-ninth variation, a breath sampling apparatus includes: a sampling tube configured to prevent mixing of exhaled gases within the sampling tube; and first and second valves coupled to the sampling tube, wherein the first and second vales are configured to capture exhaled breath within the sampling tube.
In a fiftieth variation, a method of analyzing one or more breaths includes: identifying one or more constituent portions of the one or more breaths; storing the one or more breaths so the one or more constituent portions are not mixed; identifying at least one of the one or more constituent portions for analysis; and analyzing the at least one of the one or more constituent portions.
In a fifty-first variation, a method of analyzing a breaths includes: storing the breath so that one or more constituent portions of the breath are not mixed; and analyzing at least one of the one or more constituent portions.
Variations disclosed herein may have the following benefits. First, a breath, or multiple breaths, can be physically stored, while preserving accurate timing and breath type information for each breath, and each section of each breath. This allows for any portion of the breath(s) to be independently analyzed for the chemical composition under interest. It also allows for a breath or section of breath to be chosen for analysis after comparing and contrasting its breath type against thresholds and against other breath types in a series of breaths. It also allows for different breath types to be sought and chosen for different types of compositional analyses. Second, variations herein prevent undesired mixing of the breath sample, for example the end-tidal sample, with the ambient or other portions of the breath, or other breaths, by selecting a proper size of the storage apparatus and appropriate isolation valves, pneumatic routing of the gas, and precise valve control. Third, variations herein include adding an inert gas as necessary to maintain relative concentration of gasses of interest. This may be useful when the overall volume of the collected breath is too small to be effectively moved around the apparatus or measured, and also to avoid the mixing in of the ambient air into the stored samples. Fourth, variations herein include varying the gas sampling flow rate to collect incoming breath gas at variable speed, covered in more detail in U.S. patent application Ser. No. 13/722,950, assigned to the assignee of the present application, the disclosure of which is incorporated by reference herein in its entirety.
Separately, the derivation of the breathing signal can be accomplished using various algorithms for analysis of a breath waveform to determine a breath segmentation to achieve a specific objective: increased volume of specific breath portions, increased accuracy by sampling smaller sections of the breath, end tidal concentration, alveolar concentration, etc. These algorithms may affect the decision making for time markers for one breath which are dependent on the shape and number of one or more additional breaths. This may particularly be the case when a specific breathing pattern is identified, say for a known pathology, for which several breaths needs to be collected. Algorithms for identifying time markers for each of the breaths collected during the sampling period may subsequently be adjusted as new breaths come in. The time markers identified from the breathing signal may then be used to correctly identify breath portions to group together, to obtain sufficient volume to be measurable by the sensors.
Described here are devices and methods for creating a breath gas sample registry, and analyzing the gas in that registry for a desired monitoring, screening or diagnostic purpose. In the embodiments shown, for exemplary purposes, the patient's breath sample is shown to be drawn into the instrument from the patient by application of vacuum. However the disclosure also applies to patients breathing into the instrument in order for the instrument to collect the breath sample, without the vacuum application.
In some variations, one or more breathing parameters are measured to identify the different constituent portions of a breath and the respective time periods, and a pneumatic system is used for capturing the portion of exhaled breath in a sampling tube using the identified time period. In some variations, one or more valves and/or flow control mechanisms—such as a vacuum pump, for example—are used to regulate the flow rate of gas drawn into the sampling tube. In some variations, the captured portion of breath is analyzed for indications of a patient's physiological state.
Measured breathing parameters may include one or more of carbon dioxide, oxygen, airway pressure, airway temperature, breath flow rate, chest impedance, diaphragmatic movement or innervation, breath sounds, or breath vibrations. Identifying the time period of a portion of a breath may include identifying substantially the start, midpoint and termination of that time period.
A diagnostic gas sample may be best taken from the end-tidal period, for example when attempting to diagnose a physiologic condition in the blood stream, such as hemolysis. For explanatory purposes, exemplary variations for sampling end-tidal gas for end-tidal CO measurement are given below; however the principles apply to other diagnostic purposes.
In some variations, the level of CO2 in an exhaled breath is used to determine the duration of a period of a breath. In further variations, duration of a period of breath may be characterized by a start and a termination of that period. In some variations, a CO2 level is used to determine a start or a termination of a period of a breath. Some examples include inspiratory time Ti, expiratory time Te, pre-end-tidal time Tpet, end-tidal time Tet, post expiratory time Tpe. In other variations, a first time derivative of a CO2 level is used to determine a start or a termination of a period of a breath. In yet other variations, a second time derivative of a CO2 level is used to determine a start or a termination of a period of a breath. In some variations, a combination of CO2 levels and CO2 level time derivatives may be used to determine a start or a termination of a period of a breath. In some variations, a start of an end-tidal period may be determined by a change in the first time derivative of a CO2 level of the exhaled breath, such as a sudden decrease in the first time derivative of the CO2 level. In some variations, a decrease in the first time derivate of the CO2 level is more than a 10% decrease. In some variations, a decrease in the first time derivate of the CO2 level is more than a 25% decrease. In some variations, the derivative will approach or become zero showing very little rate of change or a peak plateau respectively. In other variations, the start of an end-tidal period may be determined by a large second time derivative of the CO2 level. In some variations, a termination of an end-tidal period may be determined by a maximum CO2 level, which may be detected or confirmed by a change in the sign of the first time derivative of the CO2 level as the derivative becomes negative associated with a drop of the CO2 level from its peak value. In further variations, a start of a beginning period may be determined by a sudden increase in the first time derivative of the CO2 level. In other variations, the start of a beginning period may be determined by an increase in the CO2 level from zero CO2 level. In some variations, a termination of a middle period may be determined by a change in the first time derivative of a CO2 level of the exhaled breath, such as a sudden decrease in the first time derivative of the CO2 level. In some variations, a CO2 level, first time derivative thereof, or second time derivative thereof may be used to determine the start and termination of one or more periods. In another variation, a pattern matching algorithm may be employed to analyze the shape of the CO2 waveform. Other breath-borne gases may be used in place of CO2 for measuring the breathing curve. For example, oxygen can be measured which would indicate a higher oxygen concentration during inspiration than expiration. It is also contemplated that the breathing pattern may be instantaneously or substantially instantaneously measured by a fast-responding CO sensor. In this case referring to
In some variations, airway pressure is used to determine a start or a termination of a period of a breath. In other variations, a first time derivative of an airway pressure is used to determine a start or a termination of a period of a breath. In yet other variations, a second time derivative of an airway pressure is used to determine a start or a termination of a period of a breath. In some variations, a combination of airway pressures and airway pressure time derivatives may be used to determine a start or a termination of a period of a breath. In some variations, a start of an end-tidal period is determined by maximum airway pressure, that is, by a zero first time derivative of the airway pressure. In some variations, a termination of an end-tidal period may be determined by zero airway pressure. In some variations, an airway pressure, first time derivative thereof, or second time derivative thereof may be used to determine the start and termination of one or more periods. In some variations, a pattern matching algorithm can be utilized to identify relevant time markers of the breaths.
In some variations, the breath sensor monitors the person's breathing over time, and trends the breathing pattern by determining a continually updated value that is characteristic of the breathing pattern. For example, peak positive values of a breathing signal may be measured and updated for each breath. Peak values may be compared with previous peak values. Peak values may be averaged over a previous number of multiple breaths. Similarly, time-related aspects of the breaths may be trended, such as the expiratory time. Various breath-related events that are not normal breaths may be identified and exception algorithms may exist in order to not include these non-normal breath events inadvertently in deterministic steps. For example, the characteristic waveform of a sneeze, cough, stacked breath, or non-full breath may be defined in advanced or based on monitoring of a particular patient, and when detected by the breathing sensor, excepted from the appropriate deterministic algorithms.
As used herein, a sample compartment “prevents mixing” of a gas when the time-sensitive characteristics of the gas are preserved when the gas is stored in the compartment. For example, if a parameter of the gas varies during exhalation, the sample compartment prevents mixing when it preserves the variance in the parameter with respect to the associated timing of the exhalation. In this way, the sampling tube can be considered to retain the gas sections in separate physical locations. However, the term “separate physical locations” is not limited to such sample compartments. As described below, separate physical locations could include separate sampling containers. In this way, a location of a gas portion may be its position within a sampling compartment configured to prevent mixing or the separate sampling container in which it is stored.
Some examples of analyses are shown in
The system in
Some variations of the present disclosure relate to storage, with time markers, of one or more breaths, which may similar to a computer shift register where a breath or breaths are loaded into the storage tube linearly, as exhaled, and detailed timing information is kept for each physical location of the breath, which may include flow rate, pressure, CO2 concentration, etc. Any section of the stored breath(s) can be loaded forward into a set of sensors, including same sections of multiple breaths. For example, if the end tidal concentration of a certain gas is a critical measurement (i.e. hydrogen), it may be necessary to obtain multiple readings of end tidal concentration from multiple breaths, collect them together and then analyze them using a fuel cell sensor. The reason it may be necessary to collect multiple samples is that the fuel cell sensors require a minimum volume of test gas, and also, the fuel cells require significant integration time to reach steady state—possibly several minutes. This may also be true for a number of other sensor types, including mass spectrometry, etc. Additionally, each breath may have a different morphology, especially if the patient has disorderly breathing due to the presence of a disease. In that case, it may be necessary to analyze each breath separately, and select only the end tidal portion (or no portion if the breath is not well defined), to assure that the correct part of the breath is being sampled.
The process may entail collecting one or more breaths into the storage tube, with the timing information being kept separately, and then through engaging a combination of pumps and valves, routing only the relevant portions from one or more breaths to the one or more sensors. Particular attention must be paid to the inner diameter of the capillary tube, to assure that it is sufficiently large to allow for proper inflow of the exhaled gas without turbulent flows and mixing, while also being sufficiently small to prevent gas mixing. This also applies to the selection of the pump speed, which can be either fixed to allow for a range of breaths, or variable to account for breath-to-breath differences, as described in U.S. patent application Ser. No. 13/722,950, assigned to the assignee of the present application, the disclosure of which is incorporated by reference herein in its entirety. Information about pump speeds can be utilized later to “resample” the gasses in the storage tube. The process is very similar to digitally sampling analog signals with a sampling apparatus utilizing adjustable sampling rate. One re-sampling methodology involves using a “chirp” transform, to select the correct sampling points.
Although this disclosure primarily describes variations where the breath storage compartment(s) and the analysis sensor(s) are in the same device, it should be understood that the storage compartment and analysis sensor may be separated. For example, the gas may be field-captured in a compartment configured to prevent mixing. The compartment may or may not be associated with a flow mechanism (such as a vacuum pump, for example) and a mechanism for determining and recording specific portions of the breath (such as a capnometer and software, for example). Then, the stored gas may be transported to a laboratory for the analysis to be performed. The analysis performed may include some or all of the analysis described herein, such as measuring a specific constituent of the breath and/or determining the beginning/end of a specific portion of the breath (such as an end-tidal portion, for example).
Sensors may include fuel cells, MEMS fluidics sensors, optical benches, gas spectrometers, mass spectrometers, and any other type of sensor. Gases analyzed can include any standard gasses traditionally present in exhaled breath, anesthesia gases, unwanted inhaled gases (i.e. poisons, biochemical weapons), or gasses present due to metabolic processes (alcohol, drugs, disease, etc.).
It is also contemplated that new technology on the horizon, such as nanotube sensor technology, may prove to be accurate enough to measure gas composition with the requisite accuracy and in real time. So, while many of the variations describe herein describe a separate breath pattern sensing sensor and step, and a separate gas composition sensor and step, the breath sensing and gas composition analysis steps can be performed by the same sensor, and potentially at the same time. In such apparatuses, the breath information registry variations described here may be beneficial.
As used herein, the term end-tidal typically can be understood to refer to a section of the exhaled breath that is at or near the end of the expiratory period, and typically may be after the deadspace has been exhaled from the person. In addition to measuring gases such as CO in the end-tidal gas exemplified throughout the specification, it is also contemplated that non-gases such as particulates and other chemicals may be measured in the same manner.
In the foregoing descriptions of variations of the invention, it should be noted that it is also conceived that the sequences of operation described in the Figures can be combined in all possible permutations. In addition, while the examples describe ETCO measurement they may apply to other gases, for example hydrogen. The examples provided throughout are illustrative of the principles of the invention, and that various modifications, alterations, and combinations can be made by those skilled in the art without departing from the scope and spirit of the invention. Any of the variations of the various breath measurement and sampling devices disclosed herein can include features described by any other breath measurement and sampling devices or combination of breath measurement and sampling devices herein. Accordingly, it is not intended that the invention be limited, except as by the appended claims. For all of the variations described above, the steps of the methods need not be performed sequentially.
Claims
1. A breath sampling and analysis apparatus comprising:
- a sensor that detects a gas parameter for determining the start point and end point of different breath portions;
- a pump that draws at least one gas sample from a person's breath; and
- a sample compartment that stores breath portions each in separate physical locations.
2. The breath analysis apparatus of claim 1, further comprising an analyzer that analyzes separately each of the stored breath portions for a parameter.
3. The breath analysis apparatus of claim 1, wherein the sample compartment comprises a capillary channel in which the different breath portions occupy sections of volume of the channel, and wherein the sections are end to end.
4. The breath analysis apparatus of claim 1, wherein the separate physical locations comprises separate sample containers, and wherein the apparatus further comprises a manifold system to divert the different breath portions into the separate sample containers.
5. The breath analysis apparatus of claim 4, wherein the each sample container comprises a respective bypass tube and a respective sensor.
6. The breath analysis apparatus of claim 4, wherein the each sample container comprises a respective sensor, and wherein the apparatus comprises one bypass tube for all sample containers.
7. The breath analysis apparatus of claim 4, wherein the apparatus comprises one sensor for all sample containers and one bypass tube for all sample containers.
8. The breath analysis apparatus of claim 1, wherein the breath portions are from a single breath.
9. The breath analysis apparatus of claim 1, wherein the breath portions are from different breaths.
10. The breath analysis apparatus of claim 1, further comprising an analyzer that analyzes one or more breath portions for a first parameter.
11. The breath analysis apparatus of claim 10, wherein the analyzer analyzes another one or more breath portions for a second parameter.
12. The breath analysis apparatus of claim 1, further comprising an analyzer that analyze the breath portions together.
13. The breath analysis apparatus of claim 1, further comprising an analyzer that analyzes the breath portions separately.
14. The breath analysis apparatus of claim 1, further comprising a processor to identify a desired breath portion by receiving measurements of a breathing pattern characteristic, and wherein the sample compartment receives gas from the desired portion of the breath.
15. A breath sampling and analysis apparatus comprising:
- a sensor that identifies the beginning and end of a breath, thereby dividing the breath pattern into different breath portions identifying the beginning and end of different breath portions;
- a vacuum pump that draws a gas sample from a person's breath into at least one sample tube, the sample tube comprising gas from at least one breath and at least one breath portion; and
- a computer to identify the location of gas in the sample tube corresponding to the beginning and end of the breath, and corresponding to the beginning and end of the breath portion.
16. The breath analysis apparatus as in claim 15, further comprising an analyzer that analyzes the stored breath samples for a parameter.
17. A method of analyzing one or more breaths, the method comprising:
- identifying one or more constituent portions of the one or more breaths;
- storing the one or more breaths so the one or more constituent portions are not mixed;
- identifying at least one of the one or more constituent portions for analysis; and
- analyzing the at least one of the one or more constituent portions.
18. A method of analyzing a breaths, the method comprising:
- storing the breath so that one or more constituent portions of the breath are not mixed; and
- analyzing at least one of the one or more constituent portions.
Type: Application
Filed: Feb 12, 2014
Publication Date: Aug 14, 2014
Inventors: Elvir CAUSEVIC (San Francisco, CA), Anthony D. WONDKA (San Ramon, CA), Anish BHATNAGAR (Redwood City, CA)
Application Number: 14/179,381
International Classification: A61B 5/083 (20060101); A61B 5/087 (20060101);