Your search keyword '"Emma Pickwell-MacPherson"' showing total 19 results

1. In vivo terahertz sensing of psoriasis and eczema patients

Author

Jacob J. Young, Arturo I. Hernandez-Serrano, Joesph Hardwicke, and Emma Pickwell-MacPherson

Subjects

Medicine, Science

Abstract

Abstract In this study we present the first in vivo clinical study of patients with eczema and psoriasis using terahertz (THz) sensing. Eczema and psoriasis patients were measured using a handheld THz scanner, both before and after the application of moisturiser. We show that THz sensing can distinguish between dry and healthy skin in different regions of the body. Furthermore, the impact of applying moisturiser on the skin can also be observed and potentially evaluated using THz light.

Published

2024

2. Low cost and long-focal-depth metallic axicon for terahertz frequencies based on parallel-plate-waveguides

Author

A. I. Hernandez-Serrano and Emma Pickwell-MacPherson

Subjects

Medicine, Science

Abstract

Abstract In this work we demonstrate a triangular surface lens (axicon) operating at frequencies between 350 and 450 GHz using parallel-plate-waveguide technology. The proposed axicon offers longer focal depth characteristics compared to conventional plastic lenses, surpassing common TPX lenses by one order of magnitude. Additionally, due to the triangular surface of the axicon, this device is able to focus THz radiation onto smaller areas than TPX lenses, enhancing the resolution characteristics of THz imaging systems. The frequency range of operation of the proposed axicon can be easily tuned by changing the space between plates, making this approach a very attractive candidate for low-cost, robust and easy to assemble solutions for the next generation of active THz devices.

Published

2021

3. Real-time terahertz imaging with a single-pixel detector

Author

Rayko Ivanov Stantchev, Xiao Yu, Thierry Blu, and Emma Pickwell-MacPherson

Subjects

Science

Abstract

Terahertz imaging is promising in many applications, but still relies on complex equipment. Here, the authors develop a simplified solution that enables terahertz real-time imaging using a single-pixel detector and rapid reconstruction methods.

Published

2020

4. Exploiting Complementary Terahertz Ellipsometry Configurations to Probe the Hydration and Cellular Structure of Skin In Vivo

Author

Xuequan Chen, Qiushuo Sun, Jiarui Wang, Hannah Lindley-Hatcher, and Emma Pickwell-MacPherson

Subjects

anisotropy, cellular structures, hydration, in vivo, skin, terahertz ellipsometry, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

The noninvasive and water‐sensitive characteristics of terahertz (THz) light make it highly attractive for in vivo studies, especially for skin applications. However, THz instrumentation has not been developed sufficiently to fully explore all the potential applications arising: current systems cannot obtain uncorrelated reflections from multiple configurations to determine the complicated structure of living tissues. Herein, this bottleneck is overcome by implementing a novel ellipsometry configuration able to efficiently provide four complementary sets of spectral ratios, significantly enhancing characterization capabilities. An accurate model of the skin is established and validated. The anisotropy of the stratum corneum (SC) caused by its cellular structure is verified both theoretically and experimentally. The in vivo response of skin on the volar forearm to occlusion is observed by the dynamic changes in the SC and the epidermis. In addition, the THz dispersion and birefringence sensitively probe the level of hydration and the cellular inhomogeneity, producing results in good agreement with microscope images and the biological processes of the SC. The presented technique offers a brand‐new functionality in extracting insightful structural information from complex systems, significantly extending the versatility of THz spectroscopy.

Published

2021

5. Simulated and Experimental Verification for a Terahertz Specific Finite Rate of Innovation Signal Processing Method

Author

Xavier E. Ramirez Barker, Rayko I. Stanchev, Arturo I. Hernandez Serrano, and Emma Pickwell-MacPherson

Subjects

finite rate of innovation, terahertz time-domain spectroscopy, low sampling rate, sum-of-sincs, annihilating filters, Chemical technology, TP1-1185

Abstract

Recently, finite rate of innovation methods have been successfully applied to achieve low sampling rates in many areas, such as for ultrasound and radio signals. However, to the best of our knowledge, there are no journal publications applying this to real terahertz signals. In this work, we mathematically describe a finite rate of innovation method applied specifically to terahertz signals both experimentally and in simulation. To demonstrate our method, we applied it to randomized simulated signals with and without the presence of noise and to simple experimental measurements. We found excellent agreement between the simulated signals and those recreated based on results from our method, with this success also being replicated experimentally. These results were obtained at relatively low sampling rates, compared to standard methods, which is a key advantage to using a finite rate of innovation method as it allows for faster data acquisition and signal processing.

Published

2022

6. Objective and efficient terahertz signal denoising by transfer function reconstruction

Author

Xuequan Chen, Qiushuo Sun, Rayko I. Stantchev, and Emma Pickwell-MacPherson

Subjects

Applied optics. Photonics, TA1501-1820

Abstract

As an essential processing step in many disciplines, signal denoising efficiently improves data quality without extra cost. However, it is relatively under-utilized for terahertz spectroscopy. The major technique reported uses wavelet denoising in the time-domain, which has a fuzzy physical meaning and limited performance in low-frequency and water-vapor regions. Here, we work from a new perspective by reconstructing the transfer function to remove noise-induced oscillations. The method is fully objective without a need for defining a threshold. Both reflection imaging and transmission imaging were conducted. The experimental results show that both low- and high-frequency noise and the water-vapor influence were efficiently removed. The spectrum accuracy was also improved, and the image contrast was significantly enhanced. The signal-to-noise ratio of the leaf image was increased up to 10 dB, with the 6 dB bandwidth being extended by over 0.5 THz.

Published

2020

7. Graphene controlled Brewster angle device for ultra broadband terahertz modulation

Author

Zefeng Chen, Xuequan Chen, Li Tao, Kun Chen, Mingzhu Long, Xudong Liu, Keyou Yan, Rayko I. Stantchev, Emma Pickwell-MacPherson, and Jian-Bin Xu

Subjects

Science

Abstract

Low-dimensional materials show promise for applications in imaging, spectroscopy and ultra-broadband communications. Here, the authors report an effect of Brewster angle control at graphene-quartz interface for applications in terahertz modulation over a broadband range from 0.5 to 1.6 THz.

Published

2018

8. Monitoring the Effect of Transdermal Drug Delivery Patches on the Skin Using Terahertz Sensing

Author

Hannah Lindley-Hatcher, Jiarui Wang, Arturo I. Hernandez-Serrano, Joseph Hardwicke, Gabit Nurumbetov, David M. Haddleton, and Emma Pickwell-MacPherson

Subjects

THz time domain spectroscopy, transdermal drug delivery, occlusion, skin hydration, Pharmacy and materia medica, RS1-441

Abstract

Water content of the skin is an important parameter for controlling the penetration rate of chemicals through the skin barrier; therefore, for transdermal patches designed for drug delivery to be successful, the effects of the patches on the water content of the skin must be understood. Terahertz (THz) spectroscopy is a technique which is being increasingly investigated for biomedical applications due to its high sensitivity to water content and non-ionizing nature. In this study, we used THz measurements of the skin (in vivo) to observe the effect of partially and fully occlusive skin patches on the THz response of the skin after the patches had been applied for 24 h. We were able to observe an increase in the water content of the skin following the application of the patches and to identify that the skin remained hyper-hydrated for four hours after the removal of the fully occlusive patches. Herein, we show that THz spectroscopy has potential for increasing the understanding of how transdermal patches affect the skin, how long the skin takes to recover following patch removal, and what implications these factors might have for how transdermal drug patches are designed and used.

Published

2021

9. THz Sensing of Human Skin: A Review of Skin Modeling Approaches

Author

Jiarui Wang, Hannah Lindley-Hatcher, Xuequan Chen, and Emma Pickwell-MacPherson

Subjects

Terahertz spectroscopy, in vivo, skin, skin modeling, Chemical technology, TP1-1185

Abstract

The non-ionizing and non-invasive nature of THz radiation, combined with its high sensitivity to water, has made THz imaging and spectroscopy highly attractive for in vivo biomedical applications for many years. Among them, the skin is primarily investigated due to the short penetration depth of THz waves caused by the high attenuation by water in biological samples. However, a complete model of skin describing the THz–skin interaction is still needed. This is also fundamental to reveal the optical properties of the skin from the measured THz spectrum. It is crucial that the correct model is used, not just to ensure compatibility between different works, but more importantly to ensure the reliability of the data and conclusions. Therefore, in this review, we summarize the models applied to skin used in the THz regime, and we compare their adaptability, accuracy, and limitations. We show that most of the models attempt to extract the hydration profile inside the skin while there is also the anisotropic model that displays skin structural changes in the stratum corneum.

Published

2021

10. Invited Article: An active terahertz polarization converter employing vanadium dioxide and a metal wire grating in total internal reflection geometry

Author

Xudong Liu, Xuequan Chen, Edward P. J. Parrott, Chunrui Han, Georges Humbert, Aurelian Crunteanu, and Emma Pickwell-MacPherson

Subjects

Applied optics. Photonics, TA1501-1820

Abstract

Active broadband terahertz (THz) polarization manipulation devices are challenging to realize, but also of great demand in broadband terahertz systems. Vanadium dioxide (VO2) shows a promising phase transition for active control of THz waves and provides broadband polarization characteristics when integrated within grating-type structures. We creatively combine a VO2-based grating structure with a total internal reflection (TIR) geometry providing a novel interaction mechanism between the electromagnetic waves and the device, to realize a powerful active broadband THz polarization-controlling device. The device is based on a Si-substrate coated with a VO2 layer and a metal grating structure on top, attached to a prism for generating the TIR condition on the Si-VO2-grating interface. The grating is connected to electrodes for electrically switching the VO2 between its insulating and conducting phases. By properly selecting the incident angle of the THz waves, the grating direction, and the incident polarization state, we first achieved a broadband intensity modulator under a fused silica prism with an average modulation depth of 99.75% in the 0.2-1.1 THz region. Additionally, we realized an active ultra-broadband quarter-wave converter under a Si prism that can be switched between a 45° linear rotator and a quarter wave converter in the 0.8-1.5 THz region. This is the first demonstration of an active quarter-wave converter with ultra-broad bandwidth performance. Our work shows a highly flexible and multifunctional polarization-controlling device for broadband THz applications.

Published

2018

11. A Sensitive and Versatile Thickness Determination Method Based on Non-Inflection Terahertz Property Fitting

Author

Xuequan Chen and Emma Pickwell-MacPherson

Subjects

thin-film characterization, thickness uncertainty, inflection point, exponential function, fitting, Chemical technology, TP1-1185

Abstract

The accuracy of thin-film characterization in terahertz spectroscopy is mainly set by the thickness uncertainty. Physical thickness measurement has limited accuracy for thin-film samples thinner than a few hundreds of micrometers and is sometimes even impossible. The temporal resolution of time-domain terahertz spectrometers is not sufficient to resolve such thin films. Previously reported numerical methods mainly only work for materials with low dispersion and absorption. Here, we propose a novel method for thickness determination by fitting a non-inflection offset exponential function to the material optical properties. Theoretical analysis predicts the best fitting to only be achieved when the correct thickness is given. Transmission measurements on a thin-film polymer, water, and a lactose pallet verify the theory and show the accurate thickness determination and property characterization on materials which are either achromatic or dispersive, transparent or absorptive, featureless or resonant. The measurements demonstrate the best versatility and sensitivity compared to the state-of-art. The method could be widely adapted to various types of research and industrial applications.

Published

2019

12. Exploiting total internal reflection geometry for efficient optical modulation of terahertz light

Author

Xudong Liu, Edward P. J. Parrott, Benjamin S.-Y. Ung, and Emma Pickwell-MacPherson

Subjects

Applied optics. Photonics, TA1501-1820

Abstract

Efficient methods to modulate terahertz (THz) light are essential for realizing rapid THz imaging and communication applications. Here we report a novel THz modulator which utilizes the evanescent wave in a total internal reflection setup coupled with a conductive interface to enhance the attenuation efficiency of THz light. This approach makes it possible to achieve close to 100% modulation with a small interface conductivity of 12 mS. The frequency dependence of this technique is linked to the optical properties of the materials: a material with close to frequency independent conductivity that is also controllable will result in an achromatic modulation response, and the device performance can be optimized further by tuning the internal reflection angle. In this work, we focus on applying the technique in the terahertz frequency range. Using an LED array with a pump intensity of 475 mW/cm2 to produce carriers in a silicon wafer, we have achieved a modulation depth of up to 99.9% in a broad frequency range of 0.1 THz–0.8 THz. The required pumping power for the generation of the required free carriers is low because the sheet conductivity needed is far less than required for traditional transmission techniques. Consequently, the device can be modulated by an LED making it a very practical, low cost, and scalable solution for THz modulation.

Published

2016

13. Use of finite difference time domain simulations and Debye theory for modelling the terahertz reflection response of normal and tumour breast tissue.

Author

Anthony J Fitzgerald, Emma Pickwell-MacPherson, and Vincent P Wallace

Subjects

Medicine, Science

Abstract

The aim of this work was to evaluate the capabilities of Debye theory combined with Finite Difference Time Domain (FDTD) methods to simulate the terahertz (THz) response of breast tissues. Being able to accurately model breast tissues in the THz regime would facilitate the understanding of image contrast parameters used in THz imaging of breast cancer. As a test case, the model was first validated using liquid water and simulated reflection pulses were compared to experimental measured pulses with very good agreement (p = 1.00). The responses of normal and cancerous breast tissues were simulated with Debye properties and the correlation with measured data was still high for tumour (p = 0.98) and less so for normal breast (p = 0.82). Sections of the time domain pulses showed clear differences that were also evident in the comparison of pulse parameter values. These deviations may arise from the presence of adipose and other inhomogeneities in the breast tissue that are not accounted for when using the Debye model. In conclusion, the study demonstrates the power of the model for simulating THz reflection imaging; however, for biological tissues extra Debye terms or a more detailed theory may be required to link THz image contrast to physiological composition and structural changes of breast tissue associated with differences between normal and tumour tissues.

Published

2014

14. Observing the temperature dependent transition of the GP2 peptide using terahertz spectroscopy.

Author

Yiwen Sun, Zexuan Zhu, Siping Chen, Jega Balakrishnan, Derek Abbott, Anil T Ahuja, and Emma Pickwell-Macpherson

Subjects

Medicine, Science

Abstract

The GP2 peptide is derived from the Human Epidermal growth factor Receptor 2 (HER2/nue), a marker protein for breast cancer present in saliva. In this paper we study the temperature dependent behavior of hydrated GP2 at terahertz frequencies and find that the peptide undergoes a dynamic transition between 200 and 220 K. By fitting suitable molecular models to the frequency response we determine the molecular processes involved above and below the transition temperature (T(D)). In particular, we show that below T(D) the dynamic transition is dominated by a simple harmonic vibration with a slow and temperature dependent relaxation time constant and that above T(D), the dynamic behavior is governed by two oscillators, one of which has a fast and temperature independent relaxation time constant and the other of which is a heavily damped oscillator with a slow and temperature dependent time constant. Furthermore a red shifting of the characteristic frequency of the damped oscillator was observed, confirming the presence of a non-harmonic vibration potential. Our measurements and modeling of GP2 highlight the unique capabilities of THz spectroscopy for protein characterization.

Published

2012

15. Determination of terahertz permittivity of dehydrated biological samples.

Author

Yuezhi He, Kai Liu, Corinna Au, Qiushuo Sun, Edward P J Parrott, and Emma PickWell-MacPherson

Subjects

DIAGNOSTIC imaging, SUBMILLIMETER waves, LIPIDS

Abstract

A key step in transforming terahertz imaging to a practical medical imaging modality lies in understanding the interactions between terahertz (THz) waves and biological tissues. Most of the models in the literature use the permittivity of liquid water to simulate the THz-tissue interactions, but they often neglect contributions from the biological background such as proteins and lipids because dehydrated biological samples are experimentally difficult to prepare. In this work, we present a method to prepare thin and flat dehydrated samples which can be easily handled and measured in a transmission setup. Our results will provide fundamental parameters for modelling THz-tissue interactions. [ABSTRACT FROM AUTHOR]

Published

2017

16. Vanadium dioxide devices for terahertz wave modulation: a study of wire grid structures.

Author

Edward P J Parrott, Chunrui Han, Fei Yan, Georges Humbert, Annie Bessaudou, Aurelian Crunteanu, and Emma Pickwell-MacPherson

Subjects

VANADIUM dioxide, VANADIUM compounds, WIRE, ELASTIC rods & wires, TRANSITION metals

Abstract

Vandium dioxide (VO2) shows promise as the basis for a terahertz wave modulator due to its phase transition properties. Its insulator–metal-transition (IMT) can be induced either through temperature changes, optically or electronically. Recently, a metal-VO2 wire grid structure was proposed which was able to increase the modulation depth (MD) from 0.65 to 0.9, suggesting that these simple metallic structures could greatly increase the difference in terahertz transmission for the insulating and metallic states of VO2 based structures. In this paper, we have found that the increase in MD decreases with increasing VO2 conductivity in the metallic state, resulting in a maximum modulation depth of approximately 0.95 for wire grid structures that preserves a high transmission in the insulating state. Surprisingly, we find that deposition of VO2 on top of metallic structures results in reduced performance. However, we find that devices based upon VO2 alone can achieve unexpectedly high performance. In this work we present a device with a switchable wire-grid polariser effect over a broadband frequency range (from 0.3 to 2 THz). To our knowledge this is the first such broadband metamaterial based solely on VO2. The ability to switch on a metamaterial property like this to produce a polarisation effect is very useful for future terahertz optical devices such as rotators and waveplates. [ABSTRACT FROM AUTHOR]

Published

2016

17. Gelatin embedding: a novel way to preserve biological samples for terahertz imaging and spectroscopy.

Author

Shuting Fan, Benjamin Ung, Edward P J Parrott, and Emma Pickwell-MacPherson

Subjects

SUBMILLIMETER wave imaging, GELATIN, TERAHERTZ spectroscopy, DEHYDRATION, MEDICAL imaging systems

Abstract

Sample dehydration has traditionally been a challenging problem in ex vivo terahertz biomedical experiments as water content changes significantly affect the terahertz properties and can diminish important contrast features. In this paper, we propose a novel method to prevent sample dehydration using gelatin embedding. By looking at terahertz image data and calculating the optical properties of the gelatin-embedded sample, we find that our method successfully preserves the sample for at least 35 h, both for imaging and spectroscopy. Our novel preservation method demonstrates for the first time the capability to simultaneously maintain sample structural integrity and prevent dehydration at room temperature. This is particularly relevant for terahertz studies of freshly excised tissues but could be beneficial for other imaging and spectroscopy techniques. [ABSTRACT FROM AUTHOR]

Published

2015

18. The growth of biomedical terahertz research.

Author

Shuting Fan, Yuezhi He, Benjamin S Ung, and Emma Pickwell-MacPherson

Subjects

TERAHERTZ technology, MEDICAL research, DRUG analysis, PHARMACEUTICAL industry, MEDICAL technology

Abstract

Interest in biomedical terahertz research is growing rapidly and there are now several terahertz groups in Asia, Europe and the US investigating potential applications such as pharmaceutical quality control, protein characterization and cancer detection. This review article outlines the technological bottlenecks that have been overcome which have made biomedical terahertz research possible. Key research findings will be presented, and the limitations that remain and the research initiatives that strive to address them will also be discussed. [ABSTRACT FROM AUTHOR]

Published

2014

19. Effects of formalin fixing on the terahertz properties of biological tissues.

Author

Yiwen Sun, Bernd M. Fischer, and Emma Pickwell-MacPherson

Subjects

FORMALDEHYDE, TISSUE fixation (Histology), TERAHERTZ technology, ADIPOSE tissues, TISSUE analysis, MOLECULAR probes, SPECTRUM analysis, ABSORPTION

Abstract

We demonstrate how the terahertz properties of porcine adipose tissue and skeletal muscle are affected by formalin fixing. Terahertz radiation is sensitive to covalently cross-linked proteins and can be used to probe unique spectroscopic signatures. We study in detail the changes arising from different fixation times and see that formalin fixing reduces the refractive index and the absorption coefficient of the samples in the terahertz regime. These fundamental properties affect the time-domain terahertz response of the samples and determine the level of image contrast that can be achieved. [ABSTRACT FROM AUTHOR]

Published

2009