Your search keyword '"Westerhausen MT"' showing total 34 results

1. Fine particle pollution during megafires contains potentially toxic elements.

Author

Gill, RL, Fleck, R, Chau, K, Westerhausen, MT, Lockwood, TE, Violi, JP, Irga, PJ, Doblin, MA, Torpy, FR, Gill, RL, Fleck, R, Chau, K, Westerhausen, MT, Lockwood, TE, Violi, JP, Irga, PJ, Doblin, MA, and Torpy, FR

Abstract

Wildfires that raged across Australia during the 2019-2020 'Black Summer' produced an enormous quantity of particulate matter (PM) pollution, with plumes that cloaked many urban centres and ecosystems along the eastern seaboard. This has motivated a need to understand the magnitude and nature of PM exposure, so that its impact on both built and natural environments can be more accurately assessed. Here we present the potentially toxic fingerprint of PM captured by building heating, ventilation, and air conditioning filters in Sydney, Australia during the peak of the Wildfires, and from ambient urban emissions one year later (Reference period). Atmospheric PM and meteorological monitoring data were also assessed to determine the magnitude and source of high PM exposure. The wildfires were a major source of PM pollution in Sydney, exceeding the national standards on 19 % of days between November-February. Wildfire particles were finer and more spherical compared to Reference PM, with count median diameters of 892.1 ± 23.1 versus 1484.8 ± 96.7 nm (mean ± standard error). On an equal-mass basis, differences in potentially toxic elements were predominantly due to higher SO42--S (median 20.4 vs 4.7 mg g-1) and NO3--N (2.4 vs 1.2 mg g-1) in Wildfire PM, and higher PO43--P (10.4 vs 1.4 mg g-1) in Reference PM. Concentrations of remaining elements were similar or lower than Reference PM, except for enrichments to F-, Cl-, dissolved Mn, and particulate Mn, Co and Sb. Fractional solubilities of trace elements were similar or lower than Reference PM, except for enhanced Hg (12.1 vs 1.0 %) and greater variability in Cd, Hg and Mn solubility, which displayed upper quartiles exceeding that of Reference PM. These findings contribute to our understanding of human and ecosystem exposures to the toxic components of mixed smoke plumes, especially in regions downwind of the source.

Published

2024

2. Immunolabelling perturbs the endogenous and antibody-conjugated elemental concentrations during immuno-mass spectrometry imaging.

Author

Mello, MG, Westerhausen, MT, Lockwood, TE, Singh, P, Wanagat, J, Bishop, DP, Mello, MG, Westerhausen, MT, Lockwood, TE, Singh, P, Wanagat, J, and Bishop, DP

Abstract

Immuno-mass spectrometry imaging uses lanthanide-conjugated antibodies to spatially quantify biomolecules via laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS). The multi-element capabilities allow for highly multiplexed analyses that may include both conjugated antibodies and endogenous metals to reveal relationships between disease and chemical composition. Sample handling is known to perturb the composition of the endogenous elements, but there has been little investigation into the effects of immunolabelling and coverslipping. Here, we used cryofixed muscle sections to examine the impact of immunolabelling steps on the concentrations of a Gd-conjugated anti-dystrophin primary antibody, and the endogenous metals Cu and Zn. Primary antibody incubation resulted in a decrease in Zn, and an increase in Cu. Zn was removed from the cytoplasm where it was hypothesised to be more labile, whereas concentrated locations of Zn remained in the cell membrane in all samples that underwent the immunostaining process. Cu increased in concentration and was found mostly in the cell membrane. The concentration of the Gd-conjugated antibody when compared to the standard air-dried sample was not significantly different when coverslipped using an organic mounting medium, whereas use of an aqueous mounting medium significantly reduced the concentration of Gd. These results build on the knowledge of how certain sample handling techniques change elemental concentrations and distributions in tissue sections. Immunolabelling steps impact the concentration of endogenous elements, and separate histological sections are required for the quantitative analysis of endogenous elements and biomolecules. Additionally, coverslipping tissue sections for complementary immunohistochemical/immunofluorescent imaging may compromise the integrity of the elemental label, and organic mounting media are recommended over aqueous mounting media.

Published

2023

3. Enhancement of excitonic and defect-related luminescence in neutron transmutation doped β-Ga2 O3

Author

Irvine, CP, Stopic, A, Westerhausen, MT, Phillips, MR, and Ton-That, C

Abstract

Neutron irradiation analysis, inductively coupled plasma mass spectrometry (ICPMS), and cathodoluminescence (CL) spectroscopy are used to investigate the influence of transmuted Ge incorporation on the luminescence properties of β-Ga2O3 single crystals. Calculations based on Ga2O3-neutron interaction reveal temporal variations of both Ge and Zn concentrations as a function of time during and after neutron irradiation. To produce a concentration of 5×1018Gedonors/cm3 from the neutron transmutation of Ga, the β-Ga2O3 crystal was irradiated for 27 h, which was accompanied by the incorporation of 1016Znacceptors/cm3. These calculated dopant concentrations are confirmed by ICPMS. The β-Ga2O3 crystals exhibit a UV band at 3.40 eV due to self-trapped holes (STHs) and two blue donor-acceptor pair (DAP) peaks at 3.14 eV (BL1) and 2.92 eV (BL2). In addition to the neutron-induced incorporation of substitutional Ge donors and Zn acceptors on Ga sites, Ga vacancies (VGa) were created by high-energy neutrons in the flux, which strongly enhanced the BL1 peak. The VGa acceptors compensate the neutron-induced Ge donors, making the Ga2O3 crystal highly resistive. Concurrent temperature-resolved CL measurements of the β-Ga2O3 before and after neutron irradiation reveal a twofold increase in both the STH and BL1 peaks. This result suggests that STHs are preferentially localized at an O site adjacent to VGa, as theoretically predicted by Kananen et al. [Appl. Phys. Lett. 110, 202104 (2017)10.1063/1.4983814.]. Analysis of the Ga2O3 CL temperature dependence reveals that the UV and BL1 bands after the neutron irradiation exhibit an equivalent activation energy of 100±10meV due to the presence of a neutron-induced defect that acts as an efficient competitive nonradiative recombination channel. The results also provide evidence that the BL1 and BL2 bands arise from different DAP pairs.

Published

2022

4. Spontaneous Emergence of Optically Polarizing Nanoscale Structures by Co-Deposition of Aluminum with Refractory Metals: Implications for High-Temperature Polarizers

Author

Tai, MC, Arnold, MD, Estherby, C, De Silva, KSB, Gentle, AR, Cortie, DL, Mitchell, DRG, Westerhausen, MT, Cortie, MB, Tai, MC, Arnold, MD, Estherby, C, De Silva, KSB, Gentle, AR, Cortie, DL, Mitchell, DRG, Westerhausen, MT, and Cortie, MB

Abstract

The unexpected growth of highly aligned and optically polarizing metallic fins during physical vapor deposition under modestly oblique conditions is investigated. The fins exhibit nanoscale dimensions and are formed when Al is co-sputtered with any of V, Cr, Nb, Mo, Ta, W, Ru, Fe, Ni, Pt, Zr, Mg, and Ti. It is proposed that the phenomenon is caused by anomalously low atomic mobility in the alloys and intermetallic compounds formed by co-depositing with Al. In contrast, when Cu, Ag, and Au (which diffuse more rapidly in Al) are deposited, no fins form. There is a sharp visible transition in optical properties as the ratio of Al to other element is decreased: the color of the sample changes from black to silver-white for compositions containing less than about 55 atom % Al. The region over which the color change occurs is associated with a very strongly polarized reflectance. Cross-sectional elemental mapping and Monte Carlo simulations suggest that growth of the fins may be nucleated by Al hillocks and enhanced by shadowing effects. The diversity of suitable metals makes this a versatile technique for producing nanoscale polarizing surfaces suitable for high-flux and high-temperature applications.

Published

2022

5. The hydrological performance of a green roof in Sydney, Australia: A tale of two towers

Author

Fleck, R, Westerhausen, MT, Killingsworth, N, Ball, J, Torpy, FR, Irga, PJ, Fleck, R, Westerhausen, MT, Killingsworth, N, Ball, J, Torpy, FR, and Irga, PJ

Abstract

This study describes the sister buildings Daramu house and International house in Barangaroo, Sydney (Australia's largest metropolitan city), with and without a green roof, respectively. Trace metal samples were collected from both roofs and analysed using ICP-MS to determine the bioretention potential of the green roof to remediate soluble and particulate stormwater trace metal contamination. Retention of ambient trace metal contamination by the green roof substrate was deemed significant for soluble copper and particulate zinc, chromium and copper. In addition, hydrological models (DRAINS and SWMM) were applied to predict the performance of the green roof to identify its ability to manage stormwater runoff and frequency, as well as to analyse the green roof's performance in complex surface flooding situations where storage or backwater effects occur in overflow routes and surface flows. Our results demonstrate a reduction in peak stormwater flow by 18.29 L/s (∼50%) for storms as infrequent as 1 in 5 years, and peak flow reductions up to 90% storms of lower intensities. These results are significant as it demonstrates that a green roof could remediating trace metals contamination, thus reducing the impact on aquatic environments through stormwater runoff. It also highlights their potential to reduce stormwater flow, and utilise this additional water for evapotranspiration, leading to cooler ambient temperatures. Future works should aim to quantify the remediation effect of various planted species on in-situ green roofs, as well as determine the specific retention capabilities of various substrate compositions.

Published

2022

6. Pew2: Open-Source Imaging Software for Laser Ablation-Inductively Coupled Plasma-Mass Spectrometry

Author

Lockwood, TE, Westerhausen, MT, and Doble, PA

Subjects

Spectrum Analysis, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Laser Therapy, Mass Spectrometry, Software, 0301 Analytical Chemistry, 0399 Other Chemical Sciences, Analytical Chemistry, Trace Elements

Abstract

Open-sourced software is a key component of the mass spectrometry imaging field, where transparency in data processing is vital. Imaging of trace elements and immunohistochemically labeled biomolecules in tissue sections is typically performed using laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS). However, efficient and facile processing of images is hampered by a lack of verifiable and user-friendly software that supports multiple LA-ICP-MS platforms. In this technical note, we introduce Pew2, a LA-ICP-MS specific and feature-rich open-source image processing software that is compatible with common ICP-MS vendors. Pew2 is designed to be fast and easy to use and adheres to modern visualization philosophies to maximize productivity and to minimize data interpretation errors and image anomalies.

Published

2021

7. Bottom‐Up Synthesis of Hexagonal Boron Nitride Nanoparticles with Intensity‐Stabilized Quantum Emitters

Author

Chen, Y, Xu, X, Li, C, Bendavid, A, Westerhausen, MT, Bradac, C, Toth, M, Aharonovich, I, Tran, TT, Chen, Y, Xu, X, Li, C, Bendavid, A, Westerhausen, MT, Bradac, C, Toth, M, Aharonovich, I, and Tran, TT

Abstract

Fluorescent nanoparticles are widely utilized in a large range of nanoscale imaging and sensing applications. While ultra-small nanoparticles (size ≤10 nm) are highly desirable, at this size range, their photostability can be compromised due to effects such as intensity fluctuation and spectral diffusion caused by interaction with surface states. In this article, a facile, bottom-up technique for the fabrication of sub-10-nm hexagonal boron nitride (hBN) nanoparticles hosting photostable bright emitters via a catalyst-free hydrothermal reaction between boric acid and melamine is demonstrated. A simple stabilization protocol that significantly reduces intensity fluctuation by ≈85% and narrows the emission linewidth by ≈14% by employing a common sol-gel silica coating process is also implemented. This study advances a promising strategy for the scalable, bottom-up synthesis of high-quality quantum emitters in hBN nanoparticles.

Published

2021

8. Acetonitrile adduct analysis of underivatised amino acids offers improved sensitivity for hydrophilic interaction liquid chromatography tandem mass-spectrometry.

Author

Violi, JP, Bishop, DP, Padula, MP, Westerhausen, MT, Rodgers, KJ, Violi, JP, Bishop, DP, Padula, MP, Westerhausen, MT, and Rodgers, KJ

Abstract

LC-MS/MS method development for native amino acid detection can be problematic due to low ionisation efficiencies, in source fragmentation, potential for cluster ion formation and incorrect application of chromatography techniques. This has led to the majority of the scientific community derivatising amino acids for more sensitive analysis. Derivatisation has several benefits including reduced signal-to-noise ratios, more efficient ionisation, and a change in polarity, allowing the use of reverse phase chromatography. However, derivatisation of amino acids can be expensive, requires additional sample preparation steps, is more time consuming and increases sample instability, due to the most derivatised amino acids only be stable for finite amount of time. While showing initial promise, development of reliable hydrophilic interaction liquid chromatography (HILIC) separation methods has presented difficulties for the analyst including irreproducible separation and poor sensitivity. This study aimed to find a means to improve the detection sensitivity of the 20 protein amino acids by HILIC-MS/MS. We describe the use of previously undescribed amino acid-acetonitrile (ACN) adducts to improve detection of 16 out of the 20 amino acids. While all amino acids examined did form an ACN adduct, 4 had low intensity adduct formation compared to their protonated state, 3 of which are classified as basic amino acids. For 15 of the 20 amino acids tested, we used the ACN adduct for both quantification and qualification ions and demonstrated a significant enhancement in signal-to-noise ratio, ranging from 23 to 1762% improvement. Lower LODs, LOQs and lower ranges of linearity were also achieved for these amino acids. The optimised method was applied to a human neuroblastoma cell line (SH-SY5Y) with the potential to be applied to other complex sample types. The improved sensitivity this method offers simplifies sample preparation and reduces the costs of amino acid analysis compared to

Published

2021

9. Assessing the reproducibility of labelled antibody binding in quantitative multiplexed immuno-mass spectrometry imaging.

Author

Mello, MG, Westerhausen, MT, Singh, P, Doble, PA, Wanagat, J, Bishop, DP, Mello, MG, Westerhausen, MT, Singh, P, Doble, PA, Wanagat, J, and Bishop, DP

Abstract

Immuno-mass spectrometry imaging (iMSI) uses laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) to determine the spatial expression of biomolecules in tissue sections following immunolabelling with antibodies conjugated to a metal reporter. As with all immunolabelling techniques, the binding efficiency of multiplexed staining can be affected by a number of factors including epitope blocking and other forms of steric hindrance. To date, the effects on the binding of metal-conjugated antibodies to their epitopes in a multiplexed analysis have yet to be quantitatively explored by iMSI. Here we describe a protocol to investigate the effects of multiplexing on reproducible binding using the muscle proteins, dystrophin, sarcospan, and myosin as a model, with antibodies conjugated with Maxpar® reagents before histological application to murine quadriceps sections using standard immunolabelling protocols and imaging with LA-ICP-MS. The antibodies were each individually applied to eight sections, and multiplexed to another eight sections. The average concentrations of the lanthanide analytes were determined, before statistical analyses found there was no significant difference between the individual and multiplexed application of the antibodies. These analyses provide a framework for ensuring reproducibility of antibody binding during multiplexed iMSI, which will allow quantitative exploration of protein-protein interactions and provide a greater understanding of fundamental biological processes during healthy and diseased states.

Published

2021

10. Quantitative immuno-mass spectrometry imaging of skeletal muscle dystrophin

Author

Bishop, DP, Westerhausen, MT, Barthelemy, F, Lockwood, T, Cole, N, Gibbs, EM, Crosbie, RH, Nelson, SF, Miceli, MC, Doble, PA, Wanagat, J, Bishop, DP, Westerhausen, MT, Barthelemy, F, Lockwood, T, Cole, N, Gibbs, EM, Crosbie, RH, Nelson, SF, Miceli, MC, Doble, PA, and Wanagat, J

Abstract

Emerging and promising therapeutic interventions for Duchenne muscular dystrophy (DMD) are confounded by the challenges of quantifying dystrophin. Current approaches have poor precision, require large amounts of tissue, and are difficult to standardize. This paper presents an immuno-mass spectrometry imaging method using gadolinium (Gd)-labeled anti-dystrophin antibodies and laser ablation-inductively coupled plasma-mass spectrometry to simultaneously quantify and localize dystrophin in muscle sections. Gd is quantified as a proxy for the relative expression of dystrophin and was validated in murine and human skeletal muscle sections following k-means clustering segmentation, before application to DMD patients with different gene mutations where dystrophin expression was measured up to 100 µg kg−1 Gd. These results demonstrate that immuno-mass spectrometry imaging is a viable approach for pre-clinical to clinical research in DMD. It rapidly quantified relative dystrophin in single tissue sections, efficiently used valuable patient resources, and may provide information on drug efficacy for clinical translation.

Published

2021

11. Solvent-Exfoliated Hexagonal Boron Nitride Nanoflakes for Quantum Emitters

Author

Chen, Y, Westerhausen, MT, Li, C, White, S, Bradac, C, Bendavid, A, Toth, M, Aharonovich, I, Tran, TT, Chen, Y, Westerhausen, MT, Li, C, White, S, Bradac, C, Bendavid, A, Toth, M, Aharonovich, I, and Tran, TT

Abstract

Quantum emitters in hexagonal boron nitride (hBN) flakes have recently emerged as a promising platform for nanophotonic and quantum applications. The solvent-exfoliation process of these flakes has, however, remained largely unexplored. In this work, we demonstrate a surfactant-assisted exfoliation technique in an aqueous solution to exfoliate a variety of commercially available hBN powders into hBN nanoflakes. We show that the selection of hBN powder greatly impacts the optical properties of the resultant quantum emitters embedded in exfoliated hBN nanoflakes. We find that the sample with the best optical performance also shows the lowest impurity levels in its starting hBN powder. Our study provides further insight into quantum emitter fabrication in hBN and tailoring of their optical properties.

Published

2021

12. Controlled Doping of GeV and SnV Color Centers in Diamond Using Chemical Vapor Deposition

Author

Westerhausen MT, Trycz AT, Stewart C, Nonahal M, Regan B, Kianinia M, and Aharonovich I

Subjects

Nanoscience & Nanotechnology, 03 Chemical Sciences, 09 Engineering

Abstract

Group IV color centers in diamond (Si, Ge, Sn, and Pb) have recently emerged as promising candidates for realization of scalable quantum photonics. However, their synthesis in nanoscale diamond is still in its infancy. In this work we demonstrate controlled synthesis of selected group IV defects (Ge and Sn) into nanodiamonds and nanoscale single crystal diamond membranes by microwave plasma chemical vapor deposition. We take advantage of inorganic salts to prepare the chemical precursors that contain the required ions that are then incorporated into the growing diamond. Photoluminescence measurements confirm that the selected group IV emitters are present in the diamond without degrading its structural quality. Our results are important to expand the versatile synthesis of color centers in diamond.

Published

2020

13. Matching sensitivity to abundance: High resolution immuno-mass spectrometry imaging of lanthanide labels and endogenous elements in the murine brain

Author

Clases, D, Gonzalez De Vega, R, Funke, S, Lockwood, TE, Westerhausen, MT, Taudte, RV, Adlard, PA, Doble, PA, Clases, D, Gonzalez De Vega, R, Funke, S, Lockwood, TE, Westerhausen, MT, Taudte, RV, Adlard, PA, and Doble, PA

Abstract

© 2020 The Royal Society of Chemistry. This work introduces a new method for immuno-mass spectrometry imaging via quadrupole-based laser ablation-inductively coupled plasma-mass spectrometry instruments that is matched to the abundance of elements in biological tissues. Manipulation of ion-optics and quadrupole mass filter parameters provided increased transmission of low level high-mass elements, which are typically used as labels for antibodies, at the expense of highly abundant endogenous low-mass elements. Transmission of mid-mass elements such as transition metals was only slightly affected. The implications for mass resolution and background signals are critically discussed and signal to noise ratios and imaging capabilities are compared to those obtained from a standard method. This novel approach resulted in a 6-fold improved signal to noise ratio for lanthanides that are routinely used as elemental labels for antibodies to target protein distributions in biological tissues. This increase in signal intensity, enhanced contrasts, lower limits of detection and the potential to improve spatial resolution contributed to enhanced imaging and trace analyses, as demonstrated by imaging murine brain sections of the hippocampal system and substantia nigra.

Published

2020

14. Super-Resolution Reconstruction for Two-and Three-Dimensional LA-ICP-MS Bioimaging

Author

Westerhausen, MT, Bishop, DP, Dowd, A, Wanagat, J, Cole, N, and Doble, PA

Subjects

Analytical Chemistry

Abstract

© 2019 American Chemical Society. The resolution of laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) elemental bioimaging is usually constrained by the diameter of the laser spot size and is often not adequate to explore in situ subcellular distributions of elements and proteins in biological tissue sections. Super-resolution reconstruction is a method typically used for many imaging modalities and combines multiple lower resolution images to create a higher resolution image. Here, we present a super-resolution reconstruction method for LA-ICP-MS imaging by ablating consecutive layers of a biological specimen with offset orthogonal scans, resulting in a 10× improvement in resolution for quantitative measurement of dystrophin in murine muscle fibers. Layer-by-layer image reconstruction was also extended to the third dimension without the requirement of image registration across multiple thin section specimens. Quantitative super-resolution reconstruction, combined with Gaussian filtering and application of the Richardson-Lucy total variation algorithm, provided superior image clarity and fidelity in two-and three-dimensions.

Published

2019

15. Low background mould-prepared gelatine standards for reproducible quantification in elemental bio-imaging

Author

Westerhausen, MT, Lockwood, TE, Gonzalez De Vega, R, Röhnelt, A, Bishop, DP, Cole, N, Doble, PA, Clases, D, Westerhausen, MT, Lockwood, TE, Gonzalez De Vega, R, Röhnelt, A, Bishop, DP, Cole, N, Doble, PA, and Clases, D

Abstract

© The Royal Society of Chemistry 2019. Standard preparation for elemental bio-imaging by laser ablation-inductively coupled plasma-mass spectrometry is confounded by the chemical and physical differences between standard and sample matrices. These differences lead to variable ablation, aerosol generation and transportation characteristics and must be considered when designing matrix-matched standards for reliable calibration and quantification. The ability to precisely mimic sample matrices is hampered due to the complexity and heterogeneity of biological tissue and small variabilities in standard matrices and sample composition often negatively impact accuracy, precision and robustness. Furthermore, cumbersome preparation protocols may limit reproducibility and traceability. This work presents novel facile methods for the preparation of gelatine standards using both commercial and laboratory-made moulds. Surface roughness, thickness and robustness of the mould-prepared standards were compared against cryo-sectioned gelatine and homogenised brain tissue standards. The mould-prepared standards had excellent thickness accuracy and signal precision which allowed robust quantification, were easier to prepare and therefore easier to reproduce. We also compared gelatine standards prepared from a variety of animal sources and discuss their suitability to calibrate low level elemental concentrations. Finally, we present a simple method to remove background metals in gelatine using various chelating resins to increase the dynamic calibration range and to improve limits of analysis.

Published

2019

16. From Lead(II) Dithiocarbamate Precursors to a Fast Response PbS Positive Temperature Coefficient Thermistor

Author

Angeloski, A, Gentle, AR, Scott, JA, Cortie, MB, Hook, JM, Westerhausen, MT, Bhadbhade, M, Baker, AT, McDonagh, AM, Angeloski, A, Gentle, AR, Scott, JA, Cortie, MB, Hook, JM, Westerhausen, MT, Bhadbhade, M, Baker, AT, and McDonagh, AM

Abstract

© 2018 American Chemical Society. PbS submicron crystals were formed by thermolysis of two different lead dithiocarbamate complexes. These precursors were readily synthesized and fully characterized, and in situ synchrotron powder diffraction experiments were performed to characterize their decomposition. The structure and purity of resultant PbS was examined using scanning electron and transmission electron microscopies, powder X-ray diffraction, and infrared spectroscopy. Submicron crystalline PbS was used to create a new PbS thermistor with excellent sensitivity and an ultrarapid thermal response time.

Published

2018

17. Charge state switching of Cu acceptors in ZnO nanorods

Author

Rahman, MA, Westerhausen, MT, Nenstiel, C, Choi, S, Hoffmann, A, Gentle, A, Phillips, MR, Ton-That, C, Rahman, MA, Westerhausen, MT, Nenstiel, C, Choi, S, Hoffmann, A, Gentle, A, Phillips, MR, and Ton-That, C

Abstract

© 2017 Author(s). Undoped and Ga-doped ZnO nanorods both exhibit an intense green luminescence (GL) band centered at ∼2.4 eV. Unlike the defect-related GL in undoped nanorods, the GL band in Ga-doped nanorods displays a periodic fine structure separated by 72 meV, which consists of doublets with an energy spacing of 30 ± 3 meV. The emergence of the structured GL is due to the Cu+ state being stabilized by the rise in the Fermi level above the 0/- (Cu2+/Cu+) charge transfer level as a result of Ga donor incorporation. From a combination of optical characterization and simulation using the Brownian oscillator model, the doublet fine structures are shown to originate from two hole transitions with the Cu+ state located at 390 meV above the valence band.

Published

2017

18. Remarkable thermal stability of gold nanoparticles functionalised with ruthenium phthalocyanine complexes

Author

King, SR, Shimmon, S, Gentle, AR, Westerhausen, MT, Dowd, A, McDonagh, AM, King, SR, Shimmon, S, Gentle, AR, Westerhausen, MT, Dowd, A, and McDonagh, AM

Abstract

© 2016 IOP Publishing Ltd. A gold nanoparticle (AuNP) ruthenium phthalocyanine (RuPc) nanocomposite has been synthesised that exhibits high thermal stability. Electrical resistance measurements revealed that the nanocomposite is stable up to ∼320 °C. Examination of the nanocomposite and the RuPc stabiliser complex using thermogravimetric analysis and differential scanning calorimetry show that the remarkable thermal stability is due to the RuPc molecules, which provide an effective barrier to sintering of the AuNPs.

Published

2016

19. Alterations in Zinc, Copper, and Iron Levels in the Retina and Brain of Alzheimer's Disease Patients and the APP/PS1 Mouse Model.

Author

Mashkani SMH, Bishop D, Westerhausen MT, Adlard PA, and Golzan SM

Abstract

Transition metals like copper, iron, and zinc are vital for normal central nervous system function and are also linked to neurodegeneration, particularly in the onset and progression of Alzheimer's disease (AD). Their alterations in AD, identified prior to amyloid plaque aggregation, offer a unique target for staging pre-amyloid AD. However, analysing their levels in the brain is extremely challenging, necessitating the development of alternative approaches. Here, we utilised laser ablation-inductively coupled plasma-mass spectrometry and solution nebulisation-inductively coupled plasma-mass spectrometry to quantitatively measure Cu, Fe, and Zn concentrations in the retina and hippocampus samples obtained from human donors (i.e., AD and healthy controls), and in the APP/PS1 mouse model of AD, and Wild Type controls, aged 9 and 18 months. Our findings revealed significantly elevated Cu, Fe, and Zn levels in the retina (*p < 0.05, **p < 0.01, ***p < 0.001) and hippocampus (*p < 0.05, *p < 0.05, *p < 0.05) of human AD samples compared to healthy controls. Conversely, APP/PS1 mouse models exhibited notably lower metal levels in the same regions compared to WT mice, Cu, Fe, and Zn levels in the retina (**p < 0.01, *p < 0.05, *p < 0.05) and hippocampus (**p < 0.01, **p < 0.01, *p < 0.05). The contrasting metal profiles in human and mouse samples, yet similar patterns within each species' retina and brain, suggest the retina mirrors cerebral metal dyshomeostasis in AD. Our findings lay the groundwork for staging pre-AD pathophysiology through assessment of transition metal levels in the retina., (© The Author(s) 2024. Published by Oxford University Press.)

Published

2024

20. Preparation of gelatine calibration standards for LA-ICP-MS bioimaging with 266 nm laser ablation systems.

Author

Lockwood TE, Bordin DCM, Westerhausen MT, and Bishop DP

Abstract

Gelatine is the external standard matrix of choice for quantitative biomaging of elements and metal tags in tissue. Its ablation characteristics closely match that of tissue when using 193 and 213 nm lasers, but this has not been demonstrated at 266 nm. With the interest in 266 nm laser ablation systems growing due to the selective ablation of tissue over glass substrates, this gap needed to be investigated. Optical profilometry was used to map the line crater volumes of gelatine and murine brain and quadriceps tissues ablated with a 266 nm laser. Raw gelatine did not ablate in a similar manner to either tissue type and ultra-violet absorbent chemical additives were required to match ablation volumes. Addition of either 4 g L -1 l-tryptophan or 3 g L -1 gallic acid was used to match the ablation volume of murine quadriceps. Murine brain tissue had an increased ablation volume over the quadriceps tissue (1400 ± 130 versus 1100 ± 160 μm 3  at 1.5 J cm -2 ), and the addition of 5 g L -1 gallic acid and the use of low laser energy (≤1.5 J cm -2 ) was required to match the ablation of brain tissue. The modified standards were tested on a 213 nm laser, and the addition of either additive to gelatine did not affect ablation volume. The effect of additives on fractionation and two-phase sample transport was investigated, no fractionation was observed, and a decrease in two-phase sample transport of up to 60 % was obtained with the modified gelatine. This decrease was caused by the reduced laser energy required for ablation. Finally, the potential uses of optical profilometry as a standardisation tool are discussed., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

21. Improvement in the sensitivity of LA-ICP-MS bioimaging by addition of nitrogen to the argon carrier gas.

Author

Mello MG, Lockwood TE, Wanagat J, Westerhausen MT, and Bishop DP

Abstract

Elemental bioimaging of low abundant elements via laser ablation-inductively coupled plasma mass spectrometry (LA-ICP-MS) is hampered by a lack of sensitivity. Novel solutions for specific applications have been developed, however there is a need for more universal approaches. Here we investigated the addition of N 2 to the ICP carrier gas to increase sensitivity, defined as signal-to-background, for the majority of biologically relevant elements. A gelatine standard that contained 38 elements across the mass range was ablated with increasing amounts of N 2 added to the carrier gas post-ablation. The results show that while all elements examined had an increase in signal intensity, some elements did not have a resultant increase in signal-to-background. Sc, V, Mn, Fe, and Se all exhibited a reduction in signal-to-background ratios across all N 2 flow rates examined, with the remaining elements experiencing signal-to-background increases from 1.2-7.8x, depending on the N 2 flow rate and element. A compromised optimum N 2 flow rate was determined for the analysis all elements and used to image endogenous elements in a mouse brain, and antibody-conjugated elements in a quadriceps muscle section. These images confirmed that the addition of N2 to the carrier gas increased the signal-to-background of the analysis, improving image resolution for endogenous elements and low abundant analytes used for immuno-mass spectrometry imaging of biomarkers. These findings offer a promising avenue for advancing the capabilities of LA-ICP-MS in bio-imaging applications.

Published

2024

22. Immunolabelling perturbs the endogenous and antibody-conjugated elemental concentrations during immuno-mass spectrometry imaging.

Author

Mello MG, Westerhausen MT, Lockwood TE, Singh P, Wanagat J, and Bishop DP

Subjects

Mass Spectrometry methods, Diagnostic Imaging, Metals analysis, Laser Therapy methods

Abstract

Immuno-mass spectrometry imaging uses lanthanide-conjugated antibodies to spatially quantify biomolecules via laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS). The multi-element capabilities allow for highly multiplexed analyses that may include both conjugated antibodies and endogenous metals to reveal relationships between disease and chemical composition. Sample handling is known to perturb the composition of the endogenous elements, but there has been little investigation into the effects of immunolabelling and coverslipping. Here, we used cryofixed muscle sections to examine the impact of immunolabelling steps on the concentrations of a Gd-conjugated anti-dystrophin primary antibody, and the endogenous metals Cu and Zn. Primary antibody incubation resulted in a decrease in Zn, and an increase in Cu. Zn was removed from the cytoplasm where it was hypothesised to be more labile, whereas concentrated locations of Zn remained in the cell membrane in all samples that underwent the immunostaining process. Cu increased in concentration and was found mostly in the cell membrane. The concentration of the Gd-conjugated antibody when compared to the standard air-dried sample was not significantly different when coverslipped using an organic mounting medium, whereas use of an aqueous mounting medium significantly reduced the concentration of Gd. These results build on the knowledge of how certain sample handling techniques change elemental concentrations and distributions in tissue sections. Immunolabelling steps impact the concentration of endogenous elements, and separate histological sections are required for the quantitative analysis of endogenous elements and biomolecules. Additionally, coverslipping tissue sections for complementary immunohistochemical/immunofluorescent imaging may compromise the integrity of the elemental label, and organic mounting media are recommended over aqueous mounting media., (© 2023. The Author(s).)

Published

2024

23. Fine particle pollution during megafires contains potentially toxic elements.

Author

Gill RL, Fleck R, Chau K, Westerhausen MT, Lockwood TE, Violi JP, Irga PJ, Doblin MA, and Torpy FR

Subjects

Humans, Ecosystem, Environmental Monitoring, Particulate Matter analysis, Air Pollutants analysis, Air Pollution analysis, Mercury

Abstract

Wildfires that raged across Australia during the 2019-2020 'Black Summer' produced an enormous quantity of particulate matter (PM) pollution, with plumes that cloaked many urban centres and ecosystems along the eastern seaboard. This has motivated a need to understand the magnitude and nature of PM exposure, so that its impact on both built and natural environments can be more accurately assessed. Here we present the potentially toxic fingerprint of PM captured by building heating, ventilation, and air conditioning filters in Sydney, Australia during the peak of the Wildfires, and from ambient urban emissions one year later (Reference period). Atmospheric PM and meteorological monitoring data were also assessed to determine the magnitude and source of high PM exposure. The wildfires were a major source of PM pollution in Sydney, exceeding the national standards on 19 % of days between November-February. Wildfire particles were finer and more spherical compared to Reference PM, with count median diameters of 892.1 ± 23.1 versus 1484.8 ± 96.7 nm (mean ± standard error). On an equal-mass basis, differences in potentially toxic elements were predominantly due to higher SO 4 2- -S (median 20.4 vs 4.7 mg g -1 ) and NO 3 - -N (2.4 vs 1.2 mg g -1 ) in Wildfire PM, and higher PO 4 3- -P (10.4 vs 1.4 mg g -1 ) in Reference PM. Concentrations of remaining elements were similar or lower than Reference PM, except for enrichments to F - , Cl - , dissolved Mn, and particulate Mn, Co and Sb. Fractional solubilities of trace elements were similar or lower than Reference PM, except for enhanced Hg (12.1 vs 1.0 %) and greater variability in Cd, Hg and Mn solubility, which displayed upper quartiles exceeding that of Reference PM. These findings contribute to our understanding of human and ecosystem exposures to the toxic components of mixed smoke plumes, especially in regions downwind of the source., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

24. Preparation of matrix-matched standards for the analysis of teeth via laser ablation-inductively coupled plasma-mass spectrometry.

Author

Westerhausen MT, Bernard M, Choi G, Jeffries-Stokes C, Chandrajith R, Banati R, and Bishop DP

Subjects

Retrospective Studies, Mass Spectrometry methods, Copper analysis, Metals, Cadmium analysis, Laser Therapy

Abstract

Mineralised tissue such as teeth can serve as a retrospective, chronological bioindicator of past exposure to toxic metals. Laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) can be used to determine the presence and spatial distribution of toxic metals in teeth, giving a record of when an exposure occurred. Concentrations of these metals are often determined by a one-point calibration against NIST glass using an equation that requires an internal standard factor that accounts for differences in ablation behaviour between the glass and the tooth. However, an ideal external calibration would contain multiple matrix-matched standards to obtain a calibration curve. Here, we investigated optimal procedures for preparing synthetic hydroxyapatite (HA) doped with elements of interest as a calibration material. The materials were examined for homogeneity of metal incorporation, matrix-matched ablation characteristics, linearity, and limits of detection. A homogenised and pelleted HA was the most suitable material, providing improved ablation characteristics over previous HA materials and NIST glass for the analysis of teeth. An ablation yield of 1.1 showed its suitability to analyse teeth, the metals were homogeneously incorporated, and it produced excellent linearity with limits of detection ranging from 0.1-2 μg kg -1 for magnesium, aluminium, nickel, copper, zinc, cadmium, barium and lead. A juvenile incisor from a remote indigenous community in Australia and an adult molar from Sri Lanka were assessed for toxic metal exposure. The molar showed evidence of exposure to cadmium and lead. The synthetic HA material was straightforward to prepare, and will improve confidence in the analysis of teeth and other biomineralised material when assessing toxic metal exposure.

Published

2023

25. Acetonitrile adduct analysis of underivatised amino acids offers improved sensitivity for hydrophilic interaction liquid chromatography tandem mass-spectrometry.

Author

Violi JP, Bishop DP, Padula MP, Westerhausen MT, and Rodgers KJ

Subjects

Acetonitriles, Chromatography, Liquid, Humans, Hydrophobic and Hydrophilic Interactions, Amino Acids, Tandem Mass Spectrometry

Abstract

LC-MS/MS method development for native amino acid detection can be problematic due to low ionisation efficiencies, in source fragmentation, potential for cluster ion formation and incorrect application of chromatography techniques. This has led to the majority of the scientific community derivatising amino acids for more sensitive analysis. Derivatisation has several benefits including reduced signal-to-noise ratios, more efficient ionisation, and a change in polarity, allowing the use of reverse phase chromatography. However, derivatisation of amino acids can be expensive, requires additional sample preparation steps, is more time consuming and increases sample instability, due to the most derivatised amino acids only be stable for finite amount of time. While showing initial promise, development of reliable hydrophilic interaction liquid chromatography (HILIC) separation methods has presented difficulties for the analyst including irreproducible separation and poor sensitivity. This study aimed to find a means to improve the detection sensitivity of the 20 protein amino acids by HILIC-MS/MS. We describe the use of previously undescribed amino acid-acetonitrile (ACN) adducts to improve detection of 16 out of the 20 amino acids. While all amino acids examined did form an ACN adduct, 4 had low intensity adduct formation compared to their protonated state, 3 of which are classified as basic amino acids. For 15 of the 20 amino acids tested, we used the ACN adduct for both quantification and qualification ions and demonstrated a significant enhancement in signal-to-noise ratio, ranging from 23 to 1762% improvement. Lower LODs, LOQs and lower ranges of linearity were also achieved for these amino acids. The optimised method was applied to a human neuroblastoma cell line (SH-SY5Y) with the potential to be applied to other complex sample types. The improved sensitivity this method offers simplifies sample preparation and reduces the costs of amino acid analysis compared to those methods that rely on derivatisation for sensitivity., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2021. Published by Elsevier B.V.)

Published

2021

26. β-Methylamino-L-alanine-induced protein aggregation in vitro and protection by L-serine.

Author

Quinn AW, Phillips CR, Violi JP, Steele JR, Johnson MS, Westerhausen MT, and Rodgers KJ

Subjects

Antioxidants pharmacology, Cell Differentiation, Excitatory Amino Acid Agonists adverse effects, Humans, Lysosomal-Associated Membrane Protein 2 genetics, Neuroblastoma metabolism, Neuroblastoma pathology, Oxidative Stress, Proteasome Endopeptidase Complex genetics, Proteasome Endopeptidase Complex metabolism, Tumor Cells, Cultured, Amino Acids, Diamino adverse effects, Chaperone-Mediated Autophagy, Cyanobacteria Toxins adverse effects, Lysosomal-Associated Membrane Protein 2 metabolism, Neuroblastoma drug therapy, Protein Aggregates drug effects, Serine pharmacology, Ubiquitin metabolism

Abstract

The cyanobacterial non-protein amino acid α-amino-β-methylaminopropionic acid, more commonly known as BMAA, was first discovered in the seeds of the ancient gymnosperm Cycad circinalis (now Cycas micronesica Hill). BMAA was linked to the high incidence of neurological disorders on the island of Guam first reported in the 1950s. BMAA still attracts interest as a possible causative factor in amyotrophic lateral sclerosis (ALS) following the identification of ALS disease clusters associated with living in proximity to lakes with regular cyanobacterial blooms. Since its discovery, BMAA toxicity has been the subject of many in vivo and in vitro studies. A number of mechanisms of toxicity have been proposed including an agonist effect at glutamate receptors, competition with cysteine for transport system x c &#95; and other mechanisms capable of generating cellular oxidative stress. In addition, a wide range of studies have reported effects related to disturbances in proteostasis including endoplasmic reticulum stress and activation of the unfolded protein response. In the present studies we examine the effects of BMAA on the ubiquitin-proteasome system (UPS) and on chaperone-mediated autophagy (CMA) by measuring levels of ubiquitinated proteins and lamp2a protein levels in a differentiated neuronal cell line exposed to BMAA. The BMAA induced increases in oxidised proteins and the increase in CMA activity reported could be prevented by co-administration of L-serine but not by the two antioxidants examined. These data provide further evidence of a protective role for L-serine against the deleterious effects of BMAA., (© 2021. The Author(s), under exclusive licence to Springer-Verlag GmbH Austria, part of Springer Nature.)

Published

2021

27. Assessing the reproducibility of labelled antibody binding in quantitative multiplexed immuno-mass spectrometry imaging.

Author

Mello MG, Westerhausen MT, Singh P, Doble PA, Wanagat J, and Bishop DP

Subjects

Animals, Mice, Reproducibility of Results, Antibodies analysis, Immunohistochemistry methods, Mass Spectrometry methods, Muscle Proteins analysis

Abstract

Immuno-mass spectrometry imaging (iMSI) uses laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) to determine the spatial expression of biomolecules in tissue sections following immunolabelling with antibodies conjugated to a metal reporter. As with all immunolabelling techniques, the binding efficiency of multiplexed staining can be affected by a number of factors including epitope blocking and other forms of steric hindrance. To date, the effects on the binding of metal-conjugated antibodies to their epitopes in a multiplexed analysis have yet to be quantitatively explored by iMSI. Here we describe a protocol to investigate the effects of multiplexing on reproducible binding using the muscle proteins, dystrophin, sarcospan, and myosin as a model, with antibodies conjugated with Maxpar® reagents before histological application to murine quadriceps sections using standard immunolabelling protocols and imaging with LA-ICP-MS. The antibodies were each individually applied to eight sections, and multiplexed to another eight sections. The average concentrations of the lanthanide analytes were determined, before statistical analyses found there was no significant difference between the individual and multiplexed application of the antibodies. These analyses provide a framework for ensuring reproducibility of antibody binding during multiplexed iMSI, which will allow quantitative exploration of protein-protein interactions and provide a greater understanding of fundamental biological processes during healthy and diseased states., (© 2021. Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2021

28. Pew 2 : Open-Source Imaging Software for Laser Ablation-Inductively Coupled Plasma-Mass Spectrometry.

Author

Lockwood TE, Westerhausen MT, and Doble PA

Subjects

Mass Spectrometry, Software, Spectrum Analysis, Laser Therapy, Trace Elements analysis

Abstract

Open-sourced software is a key component of the mass spectrometry imaging field, where transparency in data processing is vital. Imaging of trace elements and immunohistochemically labeled biomolecules in tissue sections is typically performed using laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS). However, efficient and facile processing of images is hampered by a lack of verifiable and user-friendly software that supports multiple LA-ICP-MS platforms. In this technical note, we introduce Pew 2 , a LA-ICP-MS specific and feature-rich open-source image processing software that is compatible with common ICP-MS vendors. Pew 2 is designed to be fast and easy to use and adheres to modern visualization philosophies to maximize productivity and to minimize data interpretation errors and image anomalies.

Published

2021

29. Bottom-Up Synthesis of Hexagonal Boron Nitride Nanoparticles with Intensity-Stabilized Quantum Emitters.

Author

Chen Y, Xu X, Li C, Bendavid A, Westerhausen MT, Bradac C, Toth M, Aharonovich I, and Tran TT

Abstract

Fluorescent nanoparticles are widely utilized in a large range of nanoscale imaging and sensing applications. While ultra-small nanoparticles (size ≤10 nm) are highly desirable, at this size range, their photostability can be compromised due to effects such as intensity fluctuation and spectral diffusion caused by interaction with surface states. In this article, a facile, bottom-up technique for the fabrication of sub-10-nm hexagonal boron nitride (hBN) nanoparticles hosting photostable bright emitters via a catalyst-free hydrothermal reaction between boric acid and melamine is demonstrated. A simple stabilization protocol that significantly reduces intensity fluctuation by ≈85% and narrows the emission linewidth by ≈14% by employing a common sol-gel silica coating process is also implemented. This study advances a promising strategy for the scalable, bottom-up synthesis of high-quality quantum emitters in hBN nanoparticles., (© 2021 Wiley-VCH GmbH.)

Published

2021

30. Quantitative immuno-mass spectrometry imaging of skeletal muscle dystrophin.

Author

Bishop DP, Westerhausen MT, Barthelemy F, Lockwood T, Cole N, Gibbs EM, Crosbie RH, Nelson SF, Miceli MC, Doble PA, and Wanagat J

Subjects

Adolescent, Aged, 80 and over, Animals, Child, Dystrophin genetics, Dystrophin immunology, Female, Fluorescent Antibody Technique, Gadolinium, Humans, Immunohistochemistry, Male, Mass Spectrometry, Mice, Muscle Fibers, Skeletal chemistry, Muscular Dystrophy, Duchenne genetics, Mutation, Dystrophin analysis, Muscular Dystrophy, Duchenne metabolism, Quadriceps Muscle chemistry

Abstract

Emerging and promising therapeutic interventions for Duchenne muscular dystrophy (DMD) are confounded by the challenges of quantifying dystrophin. Current approaches have poor precision, require large amounts of tissue, and are difficult to standardize. This paper presents an immuno-mass spectrometry imaging method using gadolinium (Gd)-labeled anti-dystrophin antibodies and laser ablation-inductively coupled plasma-mass spectrometry to simultaneously quantify and localize dystrophin in muscle sections. Gd is quantified as a proxy for the relative expression of dystrophin and was validated in murine and human skeletal muscle sections following k-means clustering segmentation, before application to DMD patients with different gene mutations where dystrophin expression was measured up to 100 µg kg -1 Gd. These results demonstrate that immuno-mass spectrometry imaging is a viable approach for pre-clinical to clinical research in DMD. It rapidly quantified relative dystrophin in single tissue sections, efficiently used valuable patient resources, and may provide information on drug efficacy for clinical translation.

Published

2021

31. Super-Resolution Reconstruction for Two- and Three-Dimensional LA-ICP-MS Bioimaging.

Author

Westerhausen MT, Bishop DP, Dowd A, Wanagat J, Cole N, and Doble PA

Subjects

Animals, Gene Expression, Image Processing, Computer-Assisted methods, Laser Therapy, Male, Mice, Mice, Inbred C57BL, Microtomy, Muscle Fibers, Skeletal metabolism, Muscle Fibers, Skeletal ultrastructure, Quadriceps Muscle metabolism, Quadriceps Muscle ultrastructure, Algorithms, Dystrophin genetics, Imaging, Three-Dimensional statistics & numerical data, Quadriceps Muscle diagnostic imaging, Spectrophotometry, Atomic methods

Abstract

The resolution of laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) elemental bioimaging is usually constrained by the diameter of the laser spot size and is often not adequate to explore in situ subcellular distributions of elements and proteins in biological tissue sections. Super-resolution reconstruction is a method typically used for many imaging modalities and combines multiple lower resolution images to create a higher resolution image. Here, we present a super-resolution reconstruction method for LA-ICP-MS imaging by ablating consecutive layers of a biological specimen with offset orthogonal scans, resulting in a 10× improvement in resolution for quantitative measurement of dystrophin in murine muscle fibers. Layer-by-layer image reconstruction was also extended to the third dimension without the requirement of image registration across multiple thin section specimens. Quantitative super-resolution reconstruction, combined with Gaussian filtering and application of the Richardson-Lucy total variation algorithm, provided superior image clarity and fidelity in two- and three-dimensions.

Published

2019

32. Low background mould-prepared gelatine standards for reproducible quantification in elemental bio-imaging.

Author

Westerhausen MT, Lockwood TE, Gonzalez de Vega R, Röhnelt A, Bishop DP, Cole N, Doble PA, and Clases D

Subjects

Animals, Brain Chemistry, Calibration, Cattle, Chelating Agents chemistry, Fishes, Gelatin chemistry, Laser Therapy methods, Lung chemistry, Male, Mass Spectrometry methods, Metals analysis, Metals chemistry, Mice, Inbred C57BL, Quadriceps Muscle chemistry, Reference Standards, Reproducibility of Results, Solid Phase Extraction methods, Swine, Gelatin standards

Abstract

Standard preparation for elemental bio-imaging by laser ablation-inductively coupled plasma-mass spectrometry is confounded by the chemical and physical differences between standard and sample matrices. These differences lead to variable ablation, aerosol generation and transportation characteristics and must be considered when designing matrix-matched standards for reliable calibration and quantification. The ability to precisely mimic sample matrices is hampered due to the complexity and heterogeneity of biological tissue and small variabilities in standard matrices and sample composition often negatively impact accuracy, precision and robustness. Furthermore, cumbersome preparation protocols may limit reproducibility and traceability. This work presents novel facile methods for the preparation of gelatine standards using both commercial and laboratory-made moulds. Surface roughness, thickness and robustness of the mould-prepared standards were compared against cryo-sectioned gelatine and homogenised brain tissue standards. The mould-prepared standards had excellent thickness accuracy and signal precision which allowed robust quantification, were easier to prepare and therefore easier to reproduce. We also compared gelatine standards prepared from a variety of animal sources and discuss their suitability to calibrate low level elemental concentrations. Finally, we present a simple method to remove background metals in gelatine using various chelating resins to increase the dynamic calibration range and to improve limits of analysis.

Published

2019

33. From Lead(II) Dithiocarbamate Precursors to a Fast Response PbS Positive Temperature Coefficient Thermistor.

Author

Angeloski A, Gentle AR, Scott JA, Cortie MB, Hook JM, Westerhausen MT, Bhadbhade M, Baker AT, and McDonagh AM

Abstract

PbS submicron crystals were formed by thermolysis of two different lead dithiocarbamate complexes. These precursors were readily synthesized and fully characterized, and in situ synchrotron powder diffraction experiments were performed to characterize their decomposition. The structure and purity of resultant PbS was examined using scanning electron and transmission electron microscopies, powder X-ray diffraction, and infrared spectroscopy. Submicron crystalline PbS was used to create a new PbS thermistor with excellent sensitivity and an ultrarapid thermal response time.

Published

2018

34. Remarkable thermal stability of gold nanoparticles functionalised with ruthenium phthalocyanine complexes.

Author

King SR, Shimmon S, Gentle AR, Westerhausen MT, Dowd A, and McDonagh AM

Abstract

A gold nanoparticle (AuNP) ruthenium phthalocyanine (RuPc) nanocomposite has been synthesised that exhibits high thermal stability. Electrical resistance measurements revealed that the nanocomposite is stable up to ∼320 °C. Examination of the nanocomposite and the RuPc stabiliser complex using thermogravimetric analysis and differential scanning calorimetry show that the remarkable thermal stability is due to the RuPc molecules, which provide an effective barrier to sintering of the AuNPs.

Published

2016