In vivo tumor detection with com bined MR-Photoacoustic-Thermoacoustic imaging

Here,we report a new method using combined magnetic resonance(MR)-Photoacoustic(PA)-Thermoacoustic(TA)imaging techmiques,and demonstrate its unique ability for in vrivo cancer detection using tumor-bearing mice.Circular scanning TA and PA imaging systems were used to recover the dielectric and optical property dist ributions of three colon carcinoma bearing mice While a 7.0-T magnetic resonance imaging(MRI)unit with a mouse body volume coil was utilized for high resolution structural imaging of the same mice.Three plastic tubes flled with soybean sauce were used as fiducial markers for the co-registration of MR,PA and TA images.The resulting fused images provided both enhanced tumor margin and contrast relative to the surrounding normal tissues.In particular,some finger-like protrusions extending into the surrounding tissues were revealed in the MR/TA infused images.These results show that the tissue functional optical and dielectric properties provided by PA and TA images along with the anatomical structure by MRI in one picture make accurate tumor identification easier.This combined MR-PA-TA-imaging strategy has the potential to offer a dinically useful triple-modality tool for accurate cancer detection and for intraoper ative surgical navigation.

Photoacoustic Detection in the Michelson Interferometer Cavity

For the first time, we report photoacoustic (PA) signal detection in a cell placed within the Michelson interferometer cavity in an attempt to relate photoacoustic effect to the Michelson fringe shift as a result of changes in the cell. Both detection schemes were investigated using IR absorption and their sensitivities compared. Signals related to Michelson interferometer fringe and PA effect have shown good correlations with each other using different samples including some essential oils and their corresponding plant part from which the essential oil is usually obtained. Results were encouraging and will open the door widely to use the combined Michelson interferometer-photoacoustic spectroscopy (PAS) in trace gas detection for different applications.

Synchronous detection of multiple optical characteristics of atmospheric aerosol by coupled photoacoustic cavity

Owing to the influence of sampling loss,cavity difference and detecting source,the multi-optical parameter measurement of atmospheric aerosol cannot be detected simultaneously in the same reference environment.In order to solve this problem,a new method of simultaneously detecting the aerosol optical parameters by coupling cavity ring-down spectrometer with photoacoustic spectroscopy is proposed.Firstly,the coupled photoacoustic cavity is formed by the organic fusion of the photoacoustic cavity and the ring-down cavity.Secondly,the integrated design of the coupling spectroscopy system is carried out.Finally,the extinction coefficient and absorption coefficient of aerosol are measured simultaneously by the system,and then the aerosol scattering coefficient and single albedo are calculated indirectly.The accuracy of the system is verified by comparing with the data from the environmental quality monitoring station,which provides a new idea for the detection of multi-optical characteristics of atmospheric aerosol.

Detection of Photoacoustic Signals from Blood in Dental Pulp

Photoacoustic waves from hemoglobin solutions in dental roots are detected by using a 1064-nm laser and an ultrasonic soft probe based on a composite transducer on the tooth surface. The high-frequency ultrasonic waves are detected from a tooth with a hemoglobin solution in the pulp cavity due to the large heat transfer coefficient and absorption coefficient of hemoglobin. The spectral intensities of frequency components higher than 1 MHz show good correlation with the hemoglobin solution concentrations, and maps of frequency spectra calculated by taking short-time Fourier transforms clearly exhibit the effect of absorbance in dental pulp.

Detecting Photoacoustic Signals of Sulfur Hexafluoride at Varying Microphone Positions

Photoacoustic spectroscopy was used to test the photoacoustic properties of sulfur hexafluoride, an optically thick and potent greenhouse gas. While exploring the photoacoustic effect of sulfur hexafluoride, the effects of the position of the microphone within a gas cell were determined. Using a 35 cm gas cell, microphones were positioned at 17.5 cm, the middle of the gas cell, 12.5 cm, 7.5 cm, and 2.5 cm from the window of the cell. From the photoacoustic signal produced for each resonance frequency at each microphone position, the effects of acoustic pressure produced at each position on the signal recorded were observed. This is the first study done by experimentation with the photoacoustic effect to show that standing waves have different amplitudes at different microphone positions.

A quartz-enhanced photoacoustic spectroscopy sensor for measurement of water vapor concentration in the air

A compact and highly linear quartz-enhanced photoacoustic spectroscopy（QEPAS） sensor for the measurement of water vapor concentration in the air is demonstrated. A cost-effective quartz tuning fork（QTF） is used as the sharp transducer to convert light energy into an electrical signal based on the piezoelectric effect, thereby removing the need for a photodetector. The short optical path featured by the proposed sensing system leads to a decreased size. Furthermore, a pair of microresonators is applied in the absorbance detection module（ADM） for QTF signal enhancement. Compared with the system without microresonators, the detected QTF signal is increased to approximately 7-fold. Using this optimized QEPAS sensor with the proper modulation frequency and depth, we measure the water vapor concentration in the air at atmospheric pressure and room temperature. The experimental result shows that the sensor has a high sensitivity of 1.058parts-per-million.

Photoacoustic viscoelasticity imaging dedicated to mechanical characterization of biological tissues

Since changes in mechanical properties of biological tissues are often closely related to pathology,the viscoelastic properties are important physical parameters for medical diagnosis.A photoacoustic(PA)phase-resolved method for noninvasively characterizing the biological tissue viscoelasticity has been proposed by Gao et al.[G.Gao,S.Yang,D.Xing,\Viscoelasticity imaging of biological tissues with phase-resolved photoacoustic measurement,"Opt.Lett.36,3341–3343(2011)].The mathematical relationship between the PA phase delay and the viscosity–elasticity ratio has been theoretically deduced.Moreover,systems of PA viscoelasticity(PAVE)imaging including PAVE microscopy and PAVE endoscopy were developed,and high-PA-phase contrast images re°ecting the tissue viscoelasticity information have been successfully achieved.The PAVE method has been developed in tumor detection,atherosclerosis characterization and related vascular endoscopy.We reviewed the development of the PAVE technique and its applications in biomedical¯elds.It is believed that PAVE imaging is of great potential in both biomedical applications and clinical studies.

Scanning photoacoustic imaging of submucosal gastric tumor based on a long focused transducer in phantom and in vitro experiments

Photoacoustic imaging,which can provide the maximum intensity contrast in tissue depth imaging without ionizing radiation,will be a promising imaging trend for tumor detection.In this paper,a column diffusionfiber was employed to carry a pulsed laser for irradiating stomach directly through esophagus based on the characteristics of gastric tissue structure.A long focused ultrasonic transducer was placed outside the body to detect photoacoustic signals of gastric tissue.Phantom and in vitro experiments of submucosal gastric tumors were carried out to check the sensitivity of scanning photoacoustic tomography system,including the lateral and longitudinal resolution of the system,sensitivity of different absorption coefficient in imaging,capability of transversal detection,and probability of longitudinal detection.The results demonstrate that our innovative technique can improve the parameters of imaging.The lateral resolution reaches 2.09 mm.Then a depth of 5.5mm with a longitudinal accuracy of 0.36mm below gastric mucosa of early gastric cancer(EGC)has been achieved.In addition,the optimal absorption coefficient differences among absorbers of system are 3.3-3.9 times.Results indicate that our photoacoustic imaging(PAI)system,is based on a long focusing transducer,can provide a potential application for detecting submucosal EGC without obvious symptoms.

Ultrasonic signal detection based on Fabry–Perot cavity sensor

Acoustic/ultrasonic sensors are devices that can convert mechanical energy into electrical signals.The Fabry–Perot cavity is processed on the end face of the double-clad fiber by a two-photon three-dimensional lithography machine.In this study,the outer diameter of the core cladding was 250μm,the diameter of the core was 9μm,and the microcavity sensing unit was only 30μm.It could measure ultrasonic signals with high precision.The characteristics of the proposed ultrasonic sensor were investigated,and its feasibility was proven through experiments.Its design has a small size and can replace a larger ultrasonic detector device for photoacoustic signal detection.The sensor is applicable to the field of biomedical information technology,including medical diagnosis,photoacoustic endoscopy,and photoacoustic imaging.

High-speed all-optic optical coherence tomography and photoacoustic microscopy dual-modal system for microcirculation evaluation

We propose a high-speed all-optic dual-modal system that integrates spectral domain optical coherence tomography and photoacoustic microscopy(PAM).A 3*3 coupler-based interfer-ometer is used to remotely detect the surface vibration caused by photoacoustic(PA)waves.Three outputs of the interferometer are acquired simultaneously with a multi-channel data ac-quisition card.One channel data with the highest PA signal detection sensitivity is selected for sensitivity compensation.Experiment on the phantom demonstrates that the proposed method can sucessfully compensate for the loss of intensity caused by sensitivity variation.The imaging speed of the PAM is improved compared to our previous system.The total time to image a sample with 256×256 pixels is~20s.Using the proposed system,the microvasculature in the mouse auricle is visualized and the blood flow state is accessed.

Trace Ammonia Detection Based on Near-Infrared Fiber-Optic Cantilever-Enhanced Photoacoustic Spectroscopy

A trace ammonia(NH3)detection system based on the near-infrared fiber-optic cantilever-enhanced photoacoustic spectroscopy(CEPAS)is proposed.A fiber-optic extrinsic Fabry-Perot interferometer(EFPI)based cantilever microphone has been designed to detect the photoacoustic pressure signal.The microphone has many advantages,such as small size and high sensitivity.A near-infrared tunable erbium-doped fiber laser(EDFL)amplified by an erbium-doped fiber amplifier(EDFA)is used as a photoacoustic excitation light source.To improve the sensitivity,the photoacoustic signal is enhanced by a photoacoustic cell with a resonant frequency of 1624 Hz.When the wavelength modulation spectroscopy(WMS)technique is applied,the weak photoacoustic signal is detected by the second-harmonic detection technique.Trace NH3 measurement experiments demonstrate that the designed fiber-optic CEPAS system has a linear response to concentrations in the range of 0 ppm‒20 ppm at the wavelength of 1522.448 nm.Moreover,the detection limit is estimated to be 3.2 ppb for a lock-in integration time of 30 s.

Pretheranostic agents with extraordinary NIRF/photoacoustic imaging performance and photothermal oncotherapy efficacy

Cervical cancer,the most common gynecological malignancy,significantly and adversely af-fects women’s physical health and well-being.Traditional surgical interventions and chemotherapy,while potentially effective,often entail serious side effects that have led to an urgent need for novel therapeutic methods.Photothermal therapy(PTT)has emerged as a promising approach due to its ability to minimize damage to healthy tissue.Connecting a biothiol detection group to PTT-sensitive molecules can improve tumor targeting and further minimize potential side effects.In this study,we developed a near-infrared fluorescence(NIRF)/photoacoustic(PA)dual-mode probe,S-NBD,which demonstrated robust PTT per-formance.This innovative probe is capable of activating NIRF/PA signals to enable the detection of bio-thiols with high emission wavelength(838 nm)and large Stokes shift(178 nm),allowing for in vivo monitoring of cancer cells.Additionally,the probe achieved an outstanding photothermal conversion ef-ficiency of 67.1%.The application of laser irradiation(660 nm,1.0 W/cm^(2),5 min)was able to achieve complete tumor ablation without recurrence.In summary,this seminal study presents a pioneering NIRF/PA dual-mode dicyanoisophorone-based probe for biothiol imaging,incorporating features from PTT for the first time.This pioneering approach achieves the dual objectives of improving tumor diagnosis and treatment.

基于便携式悬臂梁麦克风光声光谱仪测定温室气体的方法研究

介绍了一套基于便携式悬臂梁麦克风光声光谱监测大气环境温室气体浓度的高灵敏系统,采用脉冲红外光源通过窄带光学滤光片,形成中红外区的多个光谱波段,结合光学悬臂梁麦克风技术,具有超高灵敏度,可去除背景气体干扰,实现同时监测多种气体。通过对温室气体浓度的测量,验证了甲烷(CH_(4))的方法检出限为0.226×10^(-6),二氧化碳(CO_(2))的方法检出限为2.624×10^(-6),其余的温室气体检出限最低为四氟化碳(0.052×10^(-6)),最高为三氟化氮(0.164×10^(-6))。同时验证了长期重复性,CO_(2)的1倍标准偏差为0.405 5,最大漂移量为1.775 6×10^(-6);CH_(4)的1倍标准偏差为9.162 0,最大漂移量为36.261 1×10^(-9);该仪器对CO_(2)的最大示值偏差为-0.04×10^(-6),CH_(4)的最大示值偏差为1.48×10^(-9)。温室气体的相对标准偏差均<2%;CO_(2)和CH_(4)的平均响应时间均为2 min 40 s;CO_(2)和CH_(4)的决定系数(R~2)均>0.999 9,CO_(2)拟合残差在±0.05×10^(-6)以内,CH_(4)拟合残差在±1×10^(-6)以内。

适用于CH_(4)泄漏检测的全光光声光谱装置

光声光谱技术是一种高灵敏的光学检测技术,已成功应用于各种痕量气体检测场合。针对工业上CH_(4)气体泄漏的快速安全检测问题,研制了一套基于H形光声池和Fabry-Perot干涉式光纤麦克风的全光光声光谱装置。采用有限元分析方法对悬臂梁的振动特性进行了仿真分析,并优化了悬臂梁的结构参数,使其共振频率和光声池的共振频率相匹配,实现了对光声信号的双共振增强。同时利用平面镜使光声吸收池的投射光再次入射进入吸收池,进一步增强了光声信号。装置使用Q点稳定强度解调程序对干涉信号进行解调,解决了光纤麦克风在测试过程中的Q点随温度漂移的问题,确保了光纤麦克风长期工作时的稳定性。该光声测量装置采用1653 nm波长DFB激光器作为激发光源,利用Q点稳定强度解调方法,结合波长调制-二次谐波检测技术、声学共振放大技术实现了对CH_(4)气体的全光、高灵敏度检测。实验结果表明,全光光声光谱装置的共振频率为1594 Hz,在共振频率处CH_(4)气体的检测极限为7.47 ppm(1 ppm=1×10^(−6))。根据Allan方差结果,在142 s的平均时间下,全光光声光谱装置测量CH_(4)气体的检测极限为0.23 ppm。

基于宽带光源的光声传感器用于氨气探测

对来自不同排放源的氨气进行高灵敏度探测,可以为环境治理和医疗诊断等方面提供一定的参考依据。然而,目前的氨气传感器存在在近红外波段吸收线强较弱、在中红外波段光源成本高且普遍体积大等缺点。本工作开发了一款基于宽带光源的光声传感器,选择的工作波长在2239 nm附近,此处的氨气线强量级较大为10-20cm/molecule,可以有效避免CO_(2)和H_(2)O的干扰。研究结果表明:该光声池的共振频率为1830 Hz;在室温、一个大气压和光功率为2.46 m W的实验条件下,对不同浓度的氨气测量信号进行线性拟合,线性度可达0.98976,系统具有良好的线性响应特性;Allan方差分析表明该系统稳定的最优积分时间为100 s。该传感器能满足对来自不同排放源氨气的探测要求,对实现氨气的高灵敏度探测具有重要的参考价值。

基于光纤光声传感的多组分痕量气体检测技术

为进一步提升多组分痕量气体检测灵敏度,设计了一套光纤光声传感系统。系统主要集成了2个近红外DFB激光器、近红外宽带光源、高速光谱模块、现场可编程逻辑门阵列信号采集与处理电路,具有激光调制控制、光声信号解调和数字锁相放大等功能。利用声学共振腔和干涉型光纤声波传感器对光声信号进行激发增强和探测增强,实现了乙炔和甲烷气体的高灵敏度检测。光纤声波传感器中以微机电系统悬臂梁作为声学敏感元件,设计了光纤法布里-珀罗干涉结构,将悬臂梁偏转位移转换为F-P腔长的变化。采用高分辨率光谱解调技术,实现了基于光纤F-P传感器的超高灵敏度光声信号检测。系统对乙炔和甲烷的检测极限分别达到2×10^(-9)和3×10^(-9),归一化噪声等效吸收系数为8×10^(-10)cm^(-1)W Hz^(-1/2)。

SF_(6)分解气体光声光谱检测的交叉干扰及其标定方法研究

SF_(6)气体绝缘设备内发生局部放电时会分解生成一系列微量气体产物,实现对该分解产物的实时检测对及时发现设备的绝缘缺陷、维护电网安全运行具有重要意义。文中针对SF_(6)分解气体的光声光谱在线检测技术,分析了其技术难点,并对SF_(6)分解物的交叉干扰以及标定等关键技术进行研究讨论。提出了SF_(6)分解物滤光片的科学选择方法,并通过大量实验确定了7种SF_(6)分解物的特征气体组合及其对应的滤光片红外吸收峰参数;同时,采用多组分气体标定方法消除分解物气体组分在检测中的交叉干扰影响。通过文中的研究,对解决SF_(6)分解气体光声光谱在线检测技术的关键问题提供了参考思路。

用于痕量H_(2)S检测的音叉设计及性能分析

针对商用标准石英音叉在石英增强光声光谱(Quartz-Enhanced Photoacoustic Spectroscopy,QEPAS)应用的局限性,对声波探测器石英音叉的前6阶振动模态进行了仿真研究,通过优化石英音叉参数,分析各参数对共振频率的影响,设计了一种低共振频率且高品质因数的新型石英音叉。经过测试,该音叉共振频率为12.21 kHz,品质因数高达12068,叉指间隙为0.40 mm,与商用30.72 kHz的标准石英音叉相比,共振频率降低60.25%,叉指间隙提高2倍,能量积累时间提高1.95倍。通过优化耦合共振管长度及光源的激励位置,提高了系统的探测性能。利用波长调制和二次谐波解调技术,得到系统的二次谐波信号与H_(2)S浓度存在良好的线性关系,基于QEPAS技术探测的检测限低至186×10^(-9),实现了H_(2)S的高灵敏度探测。

光声测量技术在煤炭质量检验中的应用研究

光声测量技术具有快速、准确、无损等优点,已广泛应用于材料检测领域。探讨光声测量技术在煤炭质量检验中的应用研究现状,分析其在煤炭成分分析、结构表征、热性能测量等方面的应用前景。通过工程案例验证了光声技术用于原煤品质在线检测的可行性和有效性,有效提高了检测效率。