The present application is the US national stage of International Application PCT/CN2013/089445 filed on Dec. 14, 2013 which, in turn, claims priority to Chinese Patent Application CN2013106460589 filed on Dec. 4, 2013.
The invention relates to a technical field of nano measurement, and more particularly to a temperature measurement method based on magnetization of magnetic nanoparticles using a triangle wave excitation magnetic field, which is especially applicable for temperature measurement in vivo.
Temperature is one of physical quantities of the seven basic units set by the International System of Units and is also one of the most basic physical quantities of materials in the nature. Temperature measurement is of great importance for cognition of nature of materials in the nature. Magnetic nano temperature measurement method, a brand new temperature measurement method characterized in non-invasion, obtains temperature information mainly by measuring magnetization of magnetic nanoparticles and by inverse calculation based on certain model. Non-invasion property of magnetic nano temperature measurement method makes it have broad application prospects under special circumstances such as deeply in vivo and in other confined spaces.
Temperature measurement deeply in vivo and in other confined spaces remains a worldwide problem severely hindering development of related applications in the biomedical field such as tumor hyperthermia and drug transportation. Tumor hyperthermia technique, a tumor surgery known as the “Green Treatment” characterized in non-invasion or mini-invasion, treats a tumor mainly by differences of temperature tolerance between normal cells and tumor cells in vivo. Drug transportation technique releases a drug at a designated location and a predetermined amount by magnetic nanoparticles coated with drug laden polymer and by RF heating, where measuring and controlling temperature of the magnetic nanoparticles is critical to releasing the drug at a designated location and a predetermined amount. Unfortunately, at present, although temperature measurement technique under normal circumstances such as thermal resistances has already been very mature with properties of high precision and high real-time, temperature measurement technique under special circumstances such as deeply in vivo remains developing slowly. Challenges in temperature measurement in vivo mainly lie in the special circumstance in vivo and its safety requirements, which makes contact and non-contact temperature measurement methods in prior art inapplicable. Therefore, breakthrough in temperature measurement in vivo is bringing a technical revolution to related biomedical applications, and temperature measurement in vivo with high precision and high real-time remains a worldwide problem to be solved.
Development of related magnetic measurement technology brings twilight to solving the worldwide problem of precise and real-time temperature measurement in vivo. In recent years, development of magnetic resonance thermometry provides a reliable solution to temperature measurement in vivo. In 2008, Warren et al. realized high-precision temperature imaging by coherence of inner molecules in magnetic resonance, which is significant for research in tumor hyperthermia and drug transportation. Besides, in 2009, J. B. Weaver realized magnetic nano temperature measurement through experiments by amplitude ratio between the triple harmonic generation and the quintuple harmonic generation of AC magnetization of magnetic nanoparticles. In 2012, Liu Wenzhong realized precise temperature measurement using magnetic nanoparticles by DC magnetic susceptibility of magnetic nanoparticles and by derivation and experimental verification of theoretical models based on Langevin's function model, and finished theoretical model research on temperature measurement using magnetic nanoparticles by AC magnetic susceptibility of magnetic nanoparticles and by simulation afterwards. The researches pave the way for non-invasive temperature measurement in vivo, however, due to lack of proper theoretical model research and adequate experimental research, magnetic nano temperature measurement technique remains immature, in particular, real-time and precise temperature measurement technique lacks adequate theoretical and experimental researches. Therefore, realizing non-invasive, real-time and precise temperature measurement remains an urgent problem to be resolved in technical fields like biomedicine.
In view of the above-mentioned problems, it is an objective of the invention to provide a magnetic nano temperature measurement method under a triangle wave excitation magnetic field, so as to realize real-time and precise temperature measurement in vivo.
To achieve the above objective, there is provided a magnetic nano temperature measurement method under a triangle wave excitation magnetic field, comprising steps of:
(1) positioning a magnetic nano sample at a measured object;
(2) applying a triangle wave excitation magnetic field on area of the magnetic nano sample;
(3) detecting a triangle wave excitation magnetic field-time curve and a magnetization-time curve of the magnetic nano sample;
(4) obtaining a magnetizing curve of the magnetic nano sample, namely excitation magnetic field-magnetization curve, by the triangle wave excitation magnetic field-time curve and the magnetization-time curve, and sampling the excitation magnetic field-magnetization curve to obtain magnetization Mi of the magnetic nano sample under excitation magnetic field Hi, where i=1, . . . , n and n is the total number of sampling points; and
(5) determining temperature T of the measured object by curve fitting with excitation magnetic field Hi as input, magnetization Mi as output, and a relationship between the excitation magnetic field and the magnetization
as objective function, where N is concentration of the magnetic nano sample, Ms is effective magnetic moment of a magnetic nanoparticle, and k is Boltzmann's constant.
Furthermore, step (3) further performs two-fold averaging on each of the periodic curve segment of triangle wave excitation magnetic field and that of magnetization by the same method as follows:
Obtaining multiple continuous periodic curve segments from the curve;
obtaining a periodic curve segment per unit period by performing superimposed averaging on the continuous periodic curve segments;
sampling the periodic curve segment sequentially;
dividing the periodic curve segment into four curve segments ranging from a first zero value to a peak, from the peak to a second zero value, from the second zero value to a valley, and from the valley to a third zero value respectively;
arranging sampling points of the curve segment ranging from a first zero value to a peak sequentially to form a first set of sampling points;
arranging sampling points of the curve segment ranging from the peak to a second zero value sequentially to form a second set of sampling points;
averaging each point of the first set of sampling points and a sequentially corresponding point of the second set of sampling points to obtain a first array of intermediate mean values;
arranging sampling points of the curve segment ranging from the second zero value to a valley sequentially to form a third set of sampling points;
arranging sampling points of the curve segment ranging from the valley to a third zero value sequentially to form a fourth set of sampling points;
averaging each point of the third set of sampling points and a sequentially corresponding point of the fourth set of sampling points to obtain a second array of intermediate mean values; and
averaging each value of the first array of intermediate mean values and the absolute value of a sequentially corresponding value of the second array of intermediate mean values to obtain a sampling array illustrating a variation trend between a zero value and a peak in a period.
Furthermore, a smoothing process is performed on the periodic curve segment which is further illustrated as follows: updating Y-axis value of a first point of the periodic curve segment to an average of that of a 1st point to a Nth point, updating Y-axis value of a second point to an average of that of a (N+1)th point to a (2N)th point, updating Y-axis value of a third point to an average of that of a (2N+1)th point to a (3N)th point, . . . , and so on until finishing updating Y-axis values for the whole periodic curve segment.
Furthermore, step (5) further comprises steps of:
substituting a sampling array of excitation magnetic field (H1, H2, . . . , Hn) and a sampling array of magnetization (M1, M2, . . . , Mn) into the Langevin's function
as input, where a=NMs and
and obtaining optimum values a* and b* of variables a and b with a target of minimum error α=∥S∥2, where
i=1, . . . , n, n is the total number of sampling points, coth( ) represents the hyperbolic cotangent function, and the superscript T represents transposition; and
calculating temperature
according to optimum value b* of variable b.
Furthermore, the frequency of the triangle wave excitation magnetic field ranges from 0.5 Hz to 100 Hz, and the amplitude of the triangle wave excitation magnetic field ranges from 10 Gs to 1000 Gs.
Advantages of the present invention comprise:
applying a low-frequency triangle wave excitation magnetic field on area of a magnetic nano sample, detecting the excitation magnetic field and magnetization of the magnetic nano sample simultaneously, and calculating by Langevin's function model and related inversion algorithms (Levenberg-Marquardt) for the reason that phase difference between magnetization of the magnetic nano sample and the excitation magnetic field is negligible under the low-frequency triangle wave excitation magnetic field, and the magnetizing curve (excitation magnetic field-magnetization curve) can be described by the Langevin's function, so as to obtain precise temperature information in real time; and
furthermore, considering that hysteresis occurs in the magnetizing curve of the magnetic nano sample, namely two magnetizing curves obtained by magnetization of the magnetic nano sample increasing and decreasing with the excitation magnetic field respectively are not identical, averaging multiple periods of a excitation magnetic field curve and a magnetization curve of the magnetic nano sample detected in certain time period respectively, and performing two-fold averaging on a periodic curve segment, so as to obtain a magnetizing curve of the magnetic nano sample without hysteresis and further improve measurement accuracy.
Overall, the present invention detects a magnetizing curve of a magnetic nano sample rapidly using a triangle wave excitation magnetic field, calculates temperature information by related inverse algorithms and Langevin's function model, and realizes rapid and precise temperature measurement. Tests show that accuracy of magnetic nano temperature measurement reaches 0.1K according to the method of the present invention.
For clear understanding of the objectives, features and advantages of the invention, detailed description of the invention will be given below in conjunction with accompanying drawings and specific embodiments. It should be noted that the embodiments are only meant to explain the invention, and not to limit the scope of the invention.
Firstly, the principle of magnetic nano temperature measurement is described briefly in order to better illustrate the present invention. Magnetic nanoparticle is a superparamagnetic material and its magnetizing curve follows the Langevin's paramagnetic theorem:
Where a=NMs,
M is magnetization of a magnetic nano sample, N is concentration of the magnetic nano sample, Ms is effective magnetic moment of a magnetic nanoparticle, H is a triangle wave excitation magnetic field, k is Boltzmann's constant, and T is absolute temperature. It can be concluded from the Langevin's function that the magnetizing curve of magnetic nanoparticles is temperature sensitive which changes with the temperature (as in
The magnetizing curve (excitation magnetic field-magnetization curve) of magnetic nanoparticles should be obtained rapidly so as to measure the temperature of magnetic nanoparticles in real time. At high frequencies, phase difference between a excitation magnetic field and magnetization of magnetic nanoparticles exists and is affected by parameters such as temperature and the particle size, which makes the magnetizing model of magnetic nanoparticles quite complicated and accurately measuring the magnetizing curve of magnetic nanoparticles difficult. The present invention found that under a low-frequency triangle wave excitation magnetic field, phase difference between magnetization of magnetic nanoparticles and the excitation magnetic field is negligible and the magnetizing process of magnetic nanoparticles can be described by the Langevin's function. Therefore, a magnetizing curve of magnetic nanoparticles can be obtained accurately in real time by detecting a magnetization curve of magnetic nanoparticles under a low-frequency triangle wave excitation magnetic field, so as to realize precise and real-time temperature measurement of magnetic nanoparticles.
Based on the above technical ideas, the present invention provides a magnetic nano temperature measurement method under a triangle wave excitation magnetic field, comprising steps of:
(1) positioning a magnetic nano sample at a measured object;
modifying surface of a magnetic nano sample to make it biocompatible and can be targeted to a measured vivo object by blood circulation;
(2) applying a triangle wave excitation magnetic field on area of the magnetic nano sample;
applying a triangle wave excitation magnetic field on area of the magnetic nano sample by Helmholtz coils, where there are certain requirements for both frequency and amplitude of the triangle wave excitation magnetic field where the frequency ranges from 0.5 Hz to 100 Hz for the reason that averaging by period is required to reduce noise and enough data points is required for each period, and the amplitude ranges from 10 Gs to 1000 Gs for the reason that amplitude of the triangle wave excitation magnetic field affects preset values of the excitation magnetic field and the total number n of data points for fitting;
(3) detecting the triangle wave excitation magnetic field and magnetization of the magnetic nano sample simultaneously;
detecting the excitation magnetic field and magnetization of the magnetic nano sample simultaneously by related sensors, processing the detected results by a signal conditioning circuit, collecting the excitation magnetic field and magnetization into a computer by a data acquisition card, and obtaining a excitation magnetic field curve and a magnetization curve of the magnetic nano sample;
(4) sampling magnetization Mi of the magnetic nano sample under excitation magnetic field Hi;
sampling the triangle wave excitation magnetic field-time curve and the magnetization-time curve to obtain magnetization Mi of the magnetic nano sample under excitation magnetic field Hi, where i=1, . . . , n and n is the total number of sampling points;
(5) establishing a theoretical model between the excitation magnetic field and magnetization of the sample according to the Langevin's paramagnetic theorem, and calculating the temperature in real time by related inverse algorithms;
determining temperature T of the measured object by curve fitting with excitation magnetic field Hi as input, magnetization Mi as output, and a relationship between the excitation magnetic field and the magnetization
as objective function, where Ms is effective magnetic moment of a magnetic nanoparticle, and k is Boltzmann's constant.
Further description is as follows:
substituting excitation magnetic field (H1, H2, . . . , Hn) and corresponding magnetization of the sample (M1, M2, . . . , Mn) into the Langevin's function
as input, where a=NMs,
and b is a variable to be solved in an inverse algorithm, obtaining errors between theoretical values and experimental values of magnetization of the magnetic nano sample:
setting S=[δ1, δ2, . . . δn]T and α=STS=∥S∥2, where variables a and b reach optimal values and F=S′ST=0 when the sum of squared errors α is minimum, predetermining initial parameters (a0,b0) and termination conditions (error range, maximum number of iterations, etc.) which is determined by experiences and can be adjusted by test results, obtaining optimum parameters a* and b* by solving nonlinear equations, and calculating temperature T by
Advantageously, in step (4), an optimizing process is performed on the triangle wave excitation magnetic field-time curve and the magnetization-time curve, where Y-axis values of the triangle wave excitation magnetic field curve are discrete values of the excitation magnetic field and Y-axis values of the magnetization curve are discrete values of magnetization. The process is as follows:
(41) capturing a curve segment containing multiple consecutive periods from each of the triangle wave excitation magnetic field-time curve and the magnetization-time curve;
(42) obtaining a periodic curve segment of triangle wave excitation magnetic field per unit period by performing superimposed averaging on multiple continuous periodic curve segments of the triangle wave excitation magnetic field-time curve, and obtaining a periodic curve segment of magnetization per unit period by performing superimposed averaging on multiple continuous periodic curve segments of the magnetization-time curve; and
(43) performing two-fold averaging on each of the periodic curve segment of triangle wave excitation magnetic field and that of magnetization by the same method as follows and obtaining an array of triangle wave excitation magnetic field Hi and an array of magnetization Mi:
dividing the periodic curve segment into four curve segments ranging from a first zero value to a peak, from the peak to a second zero value, from the second zero value to a valley, and from the valley to a third zero value respectively;
arranging sampling points of the curve segment ranging from a first zero value to a peak sequentially to form a first set of sampling points;
arranging sampling points of the curve segment ranging from the peak to a second zero value sequentially to form a second set of sampling points;
averaging Y-axis value of each point of the first set of sampling points and that of a sequentially corresponding point of the second set of sampling points to obtain a first array of intermediate mean values;
arranging sampling points of the curve segment ranging from the second zero value to a valley sequentially to form a third set of sampling points;
arranging sampling points of the curve segment ranging from the valley to a third zero value sequentially to form a fourth set of sampling points;
averaging Y-axis value of each point of the third set of sampling points and that of a sequentially corresponding point of the fourth set of sampling points to obtain a second array of intermediate mean values; and
averaging each value of the first array of intermediate mean values and the absolute value of a sequentially corresponding value of the second array of intermediate mean values to obtain the array of triangle wave excitation magnetic field Hi or the array of magnetization Mi effectively illustrating a variation trend between a zero value and a peak in a period.
The process is realized specifically as follows:
presetting certain number of points required for the excitation magnetic field (h1,h2, . . . hn) to obtain corresponding magnetization, where h1˜hn is arranged in an ascending order;
resampling each of the curve segments ranging from a first zero value to a peak (excitation magnetic field and magnetization) in
resampling each of the curve segments ranging from the peak to a second zero value (excitation magnetic field and magnetization) in
resampling each of the curve segments ranging from the second zero value to a valley (excitation magnetic field and magnetization) in
resampling each of the curve segments ranging from the valley to a third zero value (excitation magnetic field and magnetization) in
obtaining two sets of points (H11, M11), (H12, M12), . . . , (H12n, M12n) and (H21, M21), (H22, M22), . . . , (H22n, M22n) by the above processes, setting H3j=(H1j+H22n−j+1)/2 and M3j=(M1j+M22n−j+1)/2 whereby deriving a set of data points (H3j, M3j), where j=1, 2, . . . , 2n, and setting Hi=(H3n+i−H3n−i+1)/2 and Mi=(M3n+i−M3n−i+1)/2 whereby deriving a set of data points (Hi, Mi) shown in
Besides, after obtaining a periodic curve segment of excitation magnetic field by averaging any curve segment of triangle wave excitation magnetic field containing m consecutive periods by period and a periodic curve segment of magnetization of magnetic nanoparticles by averaging any curve segment of magnetization of the sample containing m consecutive periods by period, an averaging process by N points (ex. eight points) may be performed on each of the periodic curve segment of excitation magnetic field and that of magnetization (shown in
In practice, real-time measurement is realized by dividing the measuring time period into several time periods in advance and processing multiple periods of the triangle wave excitation magnetic field and multiple periods of magnetization of the sample in each time period by the above method.
A curve between the excitation magnetic field and magnetization is derived finally (shown in
Simulation Example:
In order to study the effectiveness of the temperature measuring method, simulation data containing noise is used for testing the algorithm in simulation. Assume effective magnetic moment of a magnetic nanoparticle Ms=5.2×10−19 (should be tested repeatedly in experiment and is determined by parameters of a magnetic nano sample), frequency of the triangle wave excitation magnetic field ƒ=20 Hz, and amplitude thereof Ha=245 Gauss. The number n of data points in each curve segment used for solving the nonlinear equations and step of the excitation magnetic field ΔH are determined by Ha. Gaussian white noise with a standard deviation of 0.01 is added to the excitation magnetic field and magnetization of the sample respectively. In simulation, temperature points are selected in every 5° C. in a range of 300˜340° C., and the simulation result is illustrated in
While preferred embodiments of the invention have been described above, the invention is not limited to disclosure in the embodiments and the accompanying drawings. Any changes or modifications without departing from the spirit of the invention fall within the scope of the invention.
Number | Date | Country | Kind |
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2013 1 06460589 | Dec 2013 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2013/089445 | 12/14/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/081585 | 6/11/2015 | WO | A |
Number | Name | Date | Kind |
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8498837 | Liu | Jul 2013 | B2 |
9301693 | Liu | Apr 2016 | B2 |
20090068112 | Haik | Mar 2009 | A1 |
20090068114 | Haik | Mar 2009 | A1 |
20090074670 | Haik | Mar 2009 | A1 |
20120184872 | Haik | Jul 2012 | A1 |
20120239341 | Liu | Sep 2012 | A1 |
20130129630 | Haik | May 2013 | A1 |
Number | Date | Country |
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102156006 | Aug 2011 | CN |
103156581 | Jun 2013 | CN |
2600128 | Jun 2013 | EP |
2013517515 | May 2013 | JP |
2012119329 | Sep 2012 | WO |
Entry |
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PCT International Search Report for PCT/CN2013/089445 filed Dec. 14, 2013 in the name of Huazhong University of Science and Technology. |
PCT Written Opinion for PCT/CN2013/089445 filed Dec. 14, 2013 in the name of Huazhong University of Science and Technology. |
English translation of PCT Written Opinion for PCT/CN2013/089445 filed Dec. 14, 2013 in the name of Huazhong University of Science and Technology. |
Zhong J. et al. “Real-time magnetic nanothermometry: The use of magnetization of magnetic nanoparticles assessed under low frequency triangle-wave magnetic fields.” Review of Scientific Instruments 85, 094905 (2014); doi: 10.1063/1.4896121. |
Zhong J. et al. “A new approach for highly accurate, remote temperature probing using magnetic nanoparticles.” Scientific Reports 4 : 6338 (2014); DOI: 10.1038/srep06338. |
Number | Date | Country | |
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20160273971 A1 | Sep 2016 | US |