Role of Transmembrane Water Exchange in Glioma Invasion/Migration: In Vivo Preclinical Study by Relaxometry at Very Low Magnetic Field

Ruggiero, María; Itto, Hamza Aït; Baroni, Simona; Pierre, Sandra; Boutonnât, Jean; Broche, Lionel; Aime, Silvio; Berger, F.; Crich, Simonetta Geninatti; Lahrech, Hana

doi:10.3390/cancers14174180

Cited by 8 publications

(7 citation statements)

References 45 publications

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“…The method brings relevant information on the water cycling across the cell membrane related to the ongoing metabolism. The obtained results are consistent with previously reported observations made with a relaxometric approach lacking spatial resolution [56,57] . One can envision several applications for targeting and responsive agents that affect water proton relaxation rates whose changes can be efficiently detected through their impact on the intracellular CEST response.…”

Section: Discussionsupporting

confidence: 91%

A Magnetic Resonance Imaging‐Chemical Exchange Saturation Transfer (MRI‐CEST) Method for the Detection of Water Cycling across Cellular Membranes

Di Gregorio,

Papi,

Conti

et al. 2024

Angew Chem Int Ed

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Water cycling across the membrane transporters is considered a hallmark of cellular metabolism and it could be of high diagnostic relevance in the characterization of tumors and other diseases. The method relies on the response of intracellular proton exchanging molecules to the presence of extracellular Gd‐based contrast agents (GBCAs). Paramagnetic GBCAs enhances the relaxation rate of water molecules in the extracellular compartment and, through membrane exchange, the relaxation enhancement is transferred to intracellular molecules. The effect is detected at the MRI‐CEST (Magnetic Resonance Imaging ‐ Chemical Exchange Saturation Transfer) signal of intracellular proton exchanging molecules. The magnitude of the change in the CEST response reports on water cycling across the membrane. The method has been tested on RBC and on orthotopic murine models of breast cancer with different degree of malignancy (4T1, TS/A and 168FARN). The distribution of voxels reporting on membrane permeability fits well with the cells’ aggressiveness and act as an early reporter to monitor therapeutic treatments.

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Section: Discussionsupporting

confidence: 91%

A Magnetic Resonance Imaging‐Chemical Exchange Saturation Transfer (MRI‐CEST) Method for the Detection of Water Cycling across Cellular Membranes

Di Gregorio,

Papi,

Conti

et al. 2024

Angew Chem Int Ed

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“…Tumour size estimation summarises the tumour size measurements obtained by all imaging modalities for all the patients. There was no statistically signi cant bias in the lesion size measured from FCI at ultra-low eld (in particular at 22 mT) compared to HE histology (39 [31][32][33][34][35][36][37][38][39][40][41][42][43] 5a, showing the regions corresponding to the tumour (as indicated by arrows), but larger in FCI than detected by MG and US. For P2, US, MG, and MRI detect only the invasive core (ILC, ROIs in blue), not showing the surrounding DCIS area.…”

Section: Fci Imagesmentioning

confidence: 90%

“…These agree with the literature, supporting the claim that T 1 relaxation at ultra-low elds in living tissues is a relevant biomarker discriminating invasion from non-invasion. This phenomenon is linked to the transmembrane water exchange, which has been found to be more rapid in tissues with glioma cells invasion 12,33 . Also, QP peak amplitudes were markedly higher for non-invasive tumours, although not signi cantly (0.9 [0.7-1.8] s − 1 in non-invasive vs 0.5 [0.06-1.0] s − 1 in invasive, Z = -1.5, p = 0.171, Fig.…”

Section: Fci Biomarkers Of Breast Cancer Invasionmentioning

confidence: 99%

Field Cycling Imaging: a novel modality to characterise breast cancer at low and ultra-low magnetic fields below 0.2T

Mallikourti,

Ross,

Maier

et al. 2024

Preprint

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We propose Field-Cycling Imaging (FCI), a new MRI technology accessing a range of low and ultra-low magnetic fields (2mT to 0.2T), to acquire longitudinal relaxation time over 4 orders of magnitude of field strength, and covering the whole body. FCI obtains the Nuclear Magnetic Relaxation Dispersion (NMRD) profiles of tissues, which probes molecular dynamics at micro- to nanometer scales. We present a prospective study including 10 female patients with breast cancers. Low magnetic fields clearly differentiate tumours from adipose and glandular tissues and discriminates true tumour extent beyond that of conventional imaging, matching the true pathological size of the lesion. Using our FCI prototype, T1 variations at low and ultra-low field discriminate invasive from non-invasive cancers in patients (p < 0.05). To our knowledge, we described the first application of in vivo FCI in breast cancer, demonstrating relevant biomarkers that complement diagnosis of current imaging modalities, non-invasively and without contrast agents.

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“…One possible solution to the poor differentiation of glioma infiltration from surrounding edema is represented in the study by Zakharova and colleagues [ 193 ], who analyzed 50 cases of high-grade glioma and showed that diffusion kurtosis MRI biomarkers pinpointed structural tissue alterations in the brain tissue surrounding the tumor masses, delineating the invasive tumor borders in otherwise normally-appearing white matter. Moreover, Ruggiero and colleagues [ 194 ] conducted a preclinical evaluation of fast-field cycling nuclear magnetic resonance (FFC-NMR) and found that T1-relaxation at very low magnetic field through this sequence can successfully discern between proliferating and invasive/migrating glioma tissue, highlighting the promise of low-magnetic field relaxometry for future implementation in glioma patients. Finally, Hu et al leveraged multi-parametric MRI techniques such as diffusion tensor imaging (DTI) and dynamics susceptibility contrast MRI (DSC-MRI) and combined it with spatially-matched multi-omic analysis to characterize the biology of invasive non-enhancing tumor borders [ 195 ].…”

Section: Therapeutic Targets Of Glioma Invasionmentioning

confidence: 99%

Intrinsic and Microenvironmental Drivers of Glioblastoma Invasion

De Fazio,

Pittarello,

Gans

et al. 2024

IJMS

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Gliomas are diffusely infiltrating brain tumors whose prognosis is strongly influenced by their extent of invasion into the surrounding brain tissue. While lower-grade gliomas present more circumscribed borders, high-grade gliomas are aggressive tumors with widespread brain infiltration and dissemination. Glioblastoma (GBM) is known for its high invasiveness and association with poor prognosis. Its low survival rate is due to the certainty of its recurrence, caused by microscopic brain infiltration which makes surgical eradication unattainable. New insights into GBM biology at the single-cell level have enabled the identification of mechanisms exploited by glioma cells for brain invasion. In this review, we explore the current understanding of several molecular pathways and mechanisms used by tumor cells to invade normal brain tissue. We address the intrinsic biological drivers of tumor cell invasion, by tackling how tumor cells interact with each other and with the tumor microenvironment (TME). We focus on the recently discovered neuronal niche in the TME, including local as well as distant neurons, contributing to glioma growth and invasion. We then address the mechanisms of invasion promoted by astrocytes and immune cells. Finally, we review the current literature on the therapeutic targeting of the molecular mechanisms of invasion.

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Role of Transmembrane Water Exchange in Glioma Invasion/Migration: In Vivo Preclinical Study by Relaxometry at Very Low Magnetic Field

Cited by 8 publications

References 45 publications

A Magnetic Resonance Imaging‐Chemical Exchange Saturation Transfer (MRI‐CEST) Method for the Detection of Water Cycling across Cellular Membranes

A Magnetic Resonance Imaging‐Chemical Exchange Saturation Transfer (MRI‐CEST) Method for the Detection of Water Cycling across Cellular Membranes

Field Cycling Imaging: a novel modality to characterise breast cancer at low and ultra-low magnetic fields below 0.2T

Intrinsic and Microenvironmental Drivers of Glioblastoma Invasion

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