This disclosure relates generally to systems and methods for noninvasively monitoring temperature within a body of a subject and, more specifically, to systems and methods for noninvasively obtaining an accurate measure of brain temperature.
In one aspect, systems for noninvasively monitoring temperature within a body of a subject, or an internal temperature at a selected location within the subject's body, are disclosed. Such a system includes a transducer and an interface unit.
The transducer of a system for noninvasive temperature monitoring is configured to receive electromagnetic radiation that originates from tissues inside of the subject's body. At least some electromagnetic radiation that originates from tissues within a subject's body provides an indication of the temperature at the location from which that electromagnetic radiation originates. Accordingly, electromagnetic radiation that corresponds to a temperature within the body of a subject may also be referred to herein as a “native temperature signal.” In some embodiments, the transducer may be configured to be positioned against an externally accessible surface (e.g., on skin, etc.) of the subject's body to receive native temperature signals that originate from nearby tissue.
The interface unit of a system for noninvasive temperature monitoring is configured to process a native temperature signal received by the transducer in a manner that provides a standardized temperature signal, which is also referred to herein as a “standard temperature signal,” that may be recognized by a standard vital signs monitor (e.g., a bedside monitor, etc.), or patient monitor. In a specific embodiment, each standardized temperature signal may comprise a thermistor-type signal. Thus, the interface unit is configured to translate native temperature signals to standardized temperature signals. By outputting standardized temperature signals, the interface unit may enable communication between the transducer for noninvasive temperature monitoring and an apparatus, such as a standard vital signs monitor (e.g., a monitor for displaying parameters such as temperature, blood pressure, blood oxidation, heart rhythms, etc.), a standard body temperature management system (e.g., a clinical hypothermia system, etc.) or the like, that is configured to receive a temperature input in the form of a standardized temperature signal (e.g., a standard electrical resistance, etc.).
In some embodiments, conversion of a native temperature signal to a standardized temperature signal may involve consideration of a reliable reference temperature. The reference temperature may be obtained by a reference temperature sensor, which may comprise part of the transducer or part of the interface unit, or it may be an independent element. In a specific embodiment, the reference temperature sensor may be configured to obtain a reliable reference temperature signal from an externally accessible location of the subject's body, and the interface unit may receive the reference temperature signal and consider it in providing a corresponding standardized temperature signal.
A system for noninvasively monitoring temperature may also include a standard vital signs monitor, such as a bedside monitor, as well as a communication link between the interface unit and the standard vital signs monitor. The communication link enables standardized temperature signals to be communicated from the interface unit to the standard vital signs monitor. In a specific embodiment, the communication link may comprise a cable that includes a thermistor connector that will couple with a standard thermistor input of the standard vital signs monitor.
In a method for noninvasively monitoring an internal temperature within a subject's body, one or more native temperature signals that originate from tissue at a location within the subject's body that is not externally accessible may be received at a location that is readily accessible (e.g., without requiring surgery, catheterization, etc.) from outside of the subject's body. In addition, the native temperature signals may be processed to provide one or more standardized temperature signals. Each standardized temperature signal may be communicated to a standard vital signs monitor, which may then provide a user perceptible output of the temperature at a location of interest (e.g., the brain, etc.) within the subject's body.
Other aspects, as well as features and advantages of various aspects, of the disclosed subject matter will become apparent to those of ordinary skill in the art through consideration of the ensuing description, the accompanying drawings and the appended claims.
In the drawings,
In
The transducer 20 is configured to receive electromagnetic radiation that originates from tissues inside of a subject's body B. As shown in
When the transducer 20 is properly positioned relative to a location of interest L, each antenna 24 of the transducer 20 may receive a native temperature signal SN originating from that location of interest L. In various embodiments, each antenna 24 may be configured to receive a native temperature signal SN that comprise electromagnetic radiation in the so-called “microwave” portion of the electromagnetic spectrum. Without limitation, each antenna 24 may be configured to receive a native temperature signal SN of a specific frequency, or native temperature signals SN within a bandwidth of frequencies. In a specific embodiment, the range of frequencies of microwave radiation that may be received by the antenna 24 of the transducer 20 may include native temperature signals SN having frequencies in the range of about 4 GHz±200 MHz. Specific embodiments of such a transducer 20 and antenna 24 are disclosed by PCT International Publication No. WO 2013/090047 A2 of Meridian Medical Systems, LLC, which was published on Jun. 20, 2013.
In addition to being configured to receive a native temperature signal SN, each antenna 24 of the transducer 20 is configured to convert the native temperature signal SN, which are electromagnetic, to a voltage, which is an electrical signal.
Optionally, the system 10 may include a reference temperature sensor 28, such as a thermistor, that provides a reliable (e.g., accurate, etc.) temperature measurement. In some embodiments, the reference temperature sensor 28 may be positioned to place the same into close proximity to, or even into contact with, a location from which a reference temperature measurement is to be obtained (e.g., skin, etc.). A reference temperature sensor 28 may be configured to generate a reference temperature signal SR of a known type.
One or more cables 30 may extend from the transducer 20 to the radiometer 40. A cable 30 may enable the communication of voltages from the transducer 20 to the radiometer 40. In embodiments where the reference temperature sensor 28 is part of the transducer 20, a cable 30 may also be configured to convey one or more reference temperature signals SR from the transducer 20.
The radiometer 40 of a system 10 for noninvasively measuring temperature within a body B of a subject (
In the depicted embodiment, the intermediate signals SI are conveyed from the radiometer 40 to a separate interface unit 60 by way of a cable 50 that electrically couples the interface unit 60 to the radiometer 40. Alternatively, the radiometer 40 may comprise a part of an interface unit (e.g., the radiometer 40 may be housed with components of an interface unit 60, such as the components that are depicted by and described with reference to
The interface unit 60 is configured to convert, or translate, each intermediate signal SI received from the radiometer 40 and, ultimately, each native temperature signal SN received by an antenna 24 of the transducer 20, to a standardized temperature signal SS. Turning now to
The converter 62 of the interface unit 60 receives each intermediate signal SI from the radiometer 40 and converts that signal to a signal type that may be processed by other components of the interface unit 60. In embodiments where the converter 62 comprises an A/D converter, it may convert a voltage to a digital temperature signal. In addition, in embodiments where the system 10 includes a reference temperature sensor 28, the converter 62 may receive each reference temperature signal SR and convert it to a reference signal of a desired signal type (e.g., in embodiments where the converter 62 comprises an A/D converter, to a digital reference signal, etc.).
The temperature signals and any reference signals (which are collectively referred to herein as “converted signals”) output by the converter 62 may be received and processed by the processing element 64. The processing element 64 may be programmed, based on the digital signals it receives, to calculate and output a composite temperature signal.
With added reference to
When the processing element 64 outputs a composite temperature signal, that signal is a digital signal. The processing element 64 transmits the composite temperature signal to the one or more standardization converters 66. Each standardization converter 66 converts the composite temperature signal to a standardized temperature signal SS (
With returned reference to
Various embodiments of standard vital signs monitors that may be employed as the temperature signal-receiving apparatus 80 of a system 10 for non-invasively monitoring temperature within the body B of a subject include, but are not limited to, the S/5™ series vital signs monitors available from the Datex-Ohmeda division of GE Healthcare. Some non-limiting examples of body temperature management systems that may be employed as the temperature signal-receiving apparatus 80 of a system 10 include the ARCTIC SUN® 5000 temperature management system available from Medivance, Inc., of Louisville, Colo.; the THERMOGARD XP® thermal regulation system available from Zoll Medical Corporation of Chelmsford, Mass.; and the InnerCool RTx endovascular system available from Philips Healthcare of Best, the Netherlands.
With returned reference to
As
In the specific, but nonlimiting embodiment depicted by
Once native temperature signals SN have been detected, they may be processed in accordance with the teachings of this disclosure to generate a standardized temperature signal SS, and transmitted to a temperature signal-receiving apparatus 80, such as a standard vital signs monitor (
Although the foregoing description sets forth many specifics, these should not be construed as limiting the scope of any of the claims, but merely as providing illustrations of some embodiments and variations of elements or features of the disclosed subject matter. Other embodiments of the disclosed subject matter may be devised which do not depart from the spirit or scope of any of the claims. Features from different embodiments may be employed in combination. Accordingly, the scope of each claim is limited only by its plain language and the legal equivalents thereto.
Number | Date | Country | |
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61883990 | Sep 2013 | US |