ORCID Profile
0000-0002-8894-3593
Current Organisations
Telethon Kids Institute
,
University of Western Australia
,
University of Oxford
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Publisher: Hindawi Limited
Date: 07-11-2018
DOI: 10.1155/2018/4580919
Abstract: Brain and tumour blood flow can be measured noninvasively using arterial spin labelling (ASL) magnetic resonance imaging (MRI), but reliable quantification in mouse models remains difficult. Pseudocontinuous ASL (pCASL) is recommended as the clinical standard for ASL and can be improved using multiphase labelling (MP pCASL). The aim of this study was to optimise and validate MP pCASL MRI for cerebral blood flow (CBF) measurement in mice and to assess its sensitivity to tumour perfusion. Following optimization of the MP pCASL sequence, CBF data were compared with gold-standard autoradiography, showing close agreement. Subsequently, MP pCASL data were acquired at weekly intervals in models of primary and secondary brain tumours, and tumour microvessel density was determined histologically. MP pCASL measurements in a secondary brain tumour model revealed a significant reduction in blood flow at day 35 after induction, despite a higher density of blood vessels. Tumour core regions also showed reduced blood flow compared with the tumour rim. Similarly, significant reductions in CBF were found in a model of glioma 28 days after tumour induction, together with an increased density of blood vessels. These findings indicate that MP pCASL MRI provides accurate and robust measurements of cerebral blood flow in naïve mice and is sensitive to changes in tumour perfusion.
Publisher: Radiological Society of North America (RSNA)
Date: 06-2015
Abstract: To use localized correlated spectroscopy (COSY) to assess for an altered biochemical state or states in breast tissue of women with BRCA gene mutations that potentially constitute preinvasive conditions. Institutional review board approval was obtained. Participants provided written informed consent. In vivo localized COSY images were recorded at 3 T in the breast tissue of women carrying BRCA1 (n = 9) or BRCA2 (n = 14) gene mutations and were compared with images in healthy control subjects with no family history of breast cancer (n = 10). All participants underwent contrast material-enhanced MR imaging and ultrasonography (US). Statistical significance was calculated with the Mann-Whitney two-sided nonparametric test. No abnormality was recorded with MR imaging or US. Metabolite levels in the BRCA1 cohort were reduced by 79% (P = .014) when compared with triglycerides level, and there was a 19% increase in lipid unsaturation and triglyceride levels (P = .027 and P = .086, respectively) when compared with cellular cholesterol level. Cholesterol level was reduced by 47% (P = .027) when compared with diallylic lipid level. Metabolite levels in the BRCA2 cohort showed increased unsaturation of 21% (P = .030) relative to triglycerides level. Comparison of the BRCA1 and BRCA2 cohorts showed a 47% (P = .002) increase in cholesterol level in the BRCA2 cohort when compared with diallylic lipid level and a 52% (P = .003) increase when compared with triglycerides level. Levels of diallylic lipid, unsaturated lipid, triglycerides, and terminal methyl on the acyl chain are reduced by 46% (P = .002), 57% (P = .003), 66% (P = .003), and 29% (P = .010), respectively, when compared with cholesterol level. Localized COSY recorded significant changes in women with BRCA1 and BRCA2 gene mutations when compared with control subjects. If these changes are ultimately proven to be a premalignant stage, this method may prove useful in screening.
Publisher: Elsevier
Date: 2022
Publisher: Radiological Society of North America (RSNA)
Date: 11-2015
Publisher: Frontiers Media SA
Date: 29-04-2021
DOI: 10.3389/FMOLB.2021.633344
Abstract: Medulloblastoma is the most common malignant childhood brain tumor, and 5-year overall survival rates are as low as 40% depending on molecular subtype, with new therapies critically important. As radiotherapy and chemotherapy act through the induction of DNA damage, the sensitization of cancer cells through the inhibition of DNA damage repair pathways is a potential therapeutic strategy. The poly-(ADP-ribose) polymerase (PARP) inhibitor veliparib was assessed for its ability to augment the cellular response to radiation-induced DNA damage in human medulloblastoma cells. DNA repair following irradiation was assessed using the alkaline comet assay, with veliparib inhibiting the rate of DNA repair. Veliparib treatment also increased the number of γH2AX foci in cells treated with radiation, and analysis of downstream pathways indicated persistent activation of the DNA damage response pathway. Clonogenicity assays demonstrated that veliparib effectively inhibited the colony-forming capacity of medulloblastoma cells, both as a single agent and in combination with irradiation. These data were then validated in vivo using an orthotopic implant model of medulloblastoma. Mice harboring intracranial D425 medulloblastoma xenografts were treated with vehicle, veliparib, 18 Gy multifractionated craniospinal irradiation (CSI), or veliparib combined with 18 Gy CSI. Animals treated with combination therapy exhibited reduced tumor growth rates concomitant with increased intra-tumoral apoptosis observed by immunohistochemistry. Kaplan–Meier analyses revealed a statistically significant increase in survival with combination therapy compared to CSI alone. In summary, PARP inhibition enhanced radiation-induced cytotoxicity of medulloblastoma cells thus, veliparib or other brain-penetrant PARP inhibitors are potential radiosensitizing agents for the treatment of medulloblastoma.
Publisher: Oxford University Press (OUP)
Date: 09-2022
DOI: 10.1093/NEUONC/NOAC174.020
Abstract: Brain cancers are the most common solid cancer in children and the leading cause of cancer-related deaths in children. Medulloblastoma is the most common paediatric brain tumour. Treatment for medulloblastoma involves surgery, craniospinal irradiation (CSI) and chemotherapy. These therapies are extremely damaging to the developing brain and have not changed in decades, resulting in stagnation in the survival outcomes for children with medulloblastoma, and poor quality of life for children who survive their treatment. Immunotherapy has become a focus of novel treatment development. While there are multiple clinical trials aiming to increase immune recognition of medulloblastoma, none have been successful to date. Anti-CD47 is an immune-modulating therapeutic antibody which blocks the anti-phagocytic signal, CD47, expressed by brain cancer cells. Anti-CD47 has shown promising preliminary efficacy in brain cancer models. Using a small animal radiotherapy platform, we have developed a preclinical CSI protocol which mimics clinical radiotherapy. Using an orthotopic xenograft model of medulloblastoma, mice were treated with either anti-CD47 antibody therapy, CSI, or the combination of both anti-CD47 and CSI. CSI was found to deplete adaptive immune cells in the brain, while myeloid cells remained the dominant populations. Anti-CD47 antibody therapy was ineffective as a single agent against a patient derived xenograft model of Group 3 medulloblastoma, and CSI as a monotherapy resulted in temporary tumour regression. We found that the combination of anti-CD47 with CSI resulted in marked and persistent tumour regression. This preclinical work has shown promising efficacy of anti-CD47 in combination with CSI, which we are currently testing in additional models. Our work is currently employing a range of techniques such as high dimensional flow cytometry and single cell sequencing to elucidate the mechanisms by which radiotherapy enhances the anti-tumour activity of myeloid cells. This work will enable the rational design and translation of optimal combination therapies for medulloblastoma clinical trials.
Publisher: Cold Spring Harbor Laboratory
Date: 15-03-2023
DOI: 10.1101/2023.03.14.532679
Abstract: Brain metastasis is responsible for a large proportion of cancer mortality, and there are currently no effective treatments. Moreover, the impact of treatments, particularly anti-angiogenic therapeutics, is difficult to ascertain using current magnetic resonance imaging (MRI) methods. Imaging of the angiogenic vasculature has been successfully carried out in solid tumours using microparticles of iron oxide (MPIO) conjugated to a peptide (RGD) targeting the integrin α v β 3 . The aim of this study was to determine whether RGD-MPIO could be used to identify angiogenic blood vessels in brain metastases in vivo. A mouse model of intracerebrally implanted brain macrometastasis was established through intracerebral injection of 4T1-GFP cells. T 2 * weighted imaging was used to visualize MPIO induced hypointense voxels in vivo, and Prussian blue staining was used to visualize MPIO and endogenous iron histologically ex vivo. The RGD-MPIO showed target-specific binding in vivo, but the sensitivity of the agent for visualizing angiogenic vessels per se was reduced by the presence of endogenous iron-laden macrophages in larger metastases, resulting in pre-existing hypointense areas within the tumour. Further, our data suggest that peptide-targeted MPIO, but not antibody-targeted MPIO, are taken up by perivascular macrophages within the macrometastatic microenvironment, resulting in additional nonspecific contrast. Whilst pre-MPIO imaging will circumvent the issues surrounding pre-existing hypointensities and enable detection of specific contrast, our findings suggest that the use of antibodies rather than peptides as the targeting ligand may represent a preferable route forward for new angiogenesis-targeted molecular MRI agents.
Publisher: Wiley
Date: 23-04-2023
DOI: 10.1002/NBM.4948
Abstract: Brain metastasis is responsible for a large proportion of cancer mortality, and there are currently no effective treatments. Moreover, the impact of treatments, particularly antiangiogenic therapeutics, is difficult to ascertain using current magnetic resonance imaging (MRI) methods. Imaging of the angiogenic vasculature has been successfully carried out in solid tumours using microparticles of iron oxide (MPIO) conjugated to a Arg‐Gly‐Asp peptide (RGD) targeting integrin α v β 3 . The aim of this study was to determine whether RGD‐MPIO could be used to identify angiogenic blood vessels in brain metastases in vivo. A mouse model of intracerebrally implanted brain macrometastasis was established through intracerebral injection of 4T1‐GFP cells. T 2 *‐weighted imaging was used to visualise MPIO‐induced hypointense voxels in vivo, and Prussian blue staining was used to visualise MPIO and endogenous iron histologically ex vivo. The RGD‐MPIO showed target‐specific binding in vivo, but the sensitivity of the agent for visualising angiogenic vessels per se was reduced by the presence of endogenous iron‐laden macrophages in larger metastases, resulting in pre‐existing hypointense areas within the tumour. Further, our data suggest that peptide‐targeted MPIO, but not antibody‐targeted MPIO, are taken up by perivascular macrophages within the macrometastatic microenvironment, resulting in additional nonspecific contrast. While pre‐MPIO imaging will circumvent the issues surrounding pre‐existing hypointensities and enable detection of specific contrast, our preliminary findings suggest that the use of antibodies rather than peptides as the targeting ligand may represent a preferable route forward for new angiogenesis‐targeted molecular MRI agents.
Location: United Kingdom of Great Britain and Northern Ireland
No related grants have been discovered for Jessica Buck.