Drug delivery to tumours using a novel 5-FU derivative encapsulated into lipid nanocapsules

In this work, a novel lipophilic 5-fluorouracil (5-FU) derivative was synthesised and encapsulated into lipid nanocapsules (LNC). 5-FU was modified with lauric acid to give a lipophilic mono-lauroyl-derivative (5-FU-C12, MW of about 342 g/mol, yield of reaction 70%). 5-FU-C12 obtained was efficiently encapsulated into LNC (encapsulation efficiency above 90%) without altering the physico-chemical characteristics of LNC. The encapsulation of 5-FU-C12 led to an increased stability of the drug when in contact with plasma being the drug detectable until 3 h following incubation. Cytotoxicity assay carried out using MTS on 2D cell culture showed that 5-FU-C12-loaded LNC had an enhanced cytotoxic effect on glioma (9L) and human colorectal (HTC-116) cancer cell line in comparison with 5-FU or 5-FU-C12. Then, HCT-116 tumour spheroids were cultivated and the reduction of spheroid volume was measured following treatment with drug-loaded LNC and drugs alone. Similar reduction on spheroids volume was observed following the treatment with drug-loaded LNC, 5-FU-C12 and 5-FU alone, while blank LNC displayed a reduction in cell viability only at high concentration. Globally, our data suggest that the encapsulation increased the activity of the 5-FU-C12. However, in-depth evaluations of LNC permeability into spheroids are needed to disclose the potential of these nanosystems for cancer treatment

Microglia/Neuron Interactions in a murine model of 6‐OHDA‐induced dopaminergic neurodegeneration

Ce travail de thèse porte sur l'étude de la réaction microgliale et des interactions microglie/neurones dans un modèle murin de neurodégénérescence dopaminergique induit par l'injection de 6‐hydroxydopamine (6‐ OHDA). Dans ce modèle, nous décrivons tout d'abord les cinétiques d'activation microgliale, de perte neuronale et d'altérations comportementales en relation avec le déficit dopaminergique. Dans la substance noire lésée ont été observées une perte progressive des neurones dopaminergiques TH+ (Tyrosine Hydroxylase) ainsi qu'une activation microgliale précoce mais transitoire. Le rôle délétère de cette activation microgliale est fortement suggéré par la mise en évidence d'une protection partielle contre la toxicité induite par la 6‐OHDA dans des souris génétiquement modifiées DAP12 Knock‐In, dont la densité microgliale est constitutivement diminuée. Par ailleurs, nous avons identifié différents types de contacts intercellulaires entre les neurones et la microglie de la substance noire lésée. Ces interactions physiques sont matérialisées entre autres sous la forme de contacts intimes entre le corps cellulaire des cellules microgliales et le soma des neurones dopaminergiques. De façon intéressante, ce type d'interaction se met en place quelques jours avant le pic de mort neuronale et dans la grande majorité des cas, concerne des neurones présentant des signes morphologiques d'apoptose. Finalement, nous avons également identifié un nouveau type d'interaction physique entre neurones et microglie sous la forme de ramifications microgliales pénétrant le soma des neurones. Ces interactions s'apparentent aux "tunelling nanotubes" décrits dans la littérature et représentent un type particulier de ramifications microgliales perforantes que nous avons nommées "tunelling ramifications". La présence de vacuoles TH+ dans le cytoplasme de nombreuses cellules microgliales suggère que les ramifications microgliales pénétrantes sont le support d'un processus de microphagocytose ciblant le cytoplasme des neurones dopaminergiques. La fonction précise de ces interactions et les mécanismes moléculaires qui les suscitent restent à définir. Toutefois, ce travail de thèse apporte un ensemble de données originales sur le dialogue microglie/neurones dans un modèle murin de la maladie de ParkinsonThis thesis work is aimed to study microglial reaction and microglia/neuron interactions in a murine model of dopaminergic neurodegeneration induced by the injection of 6‐hydroxydopamine (6‐OHDA). In this model, we first describe the kinetics of microglial activation, neuronal cell loss and behavioral alterations in relation with the dopaminergic defect. In the injured substantia nigra, we observed a progressive loss of TH+ (Tyrosine Hydroxylase ‐positive) dopaminergic neurons and an early but transient microglial activation. The deleterious role of microglial activation is strongly suggested by the observation of a partial neuroprotection against 6‐OHDA‐induced toxicity in genetically DAP12 Knock‐In mice, in which microglial cells are defective in regard to their number and function. In addition, we identified various types of cell‐tocell contacts between neurons and microglia in the injured substantia nigra. Such physical interactions were established between microglia and neuronal cell bodies several days before the peak of neuronal death and in the majority of cases in neurons showing morphological signs of apoptosis. Finally, we also identified a new type of physical interactions consisting in microglial ramifications penetrating the soma of TH+ neurons. These interactions present similarities with the so‐called « tunelling nanotubes » previously described in the literature and represent a particular type of penetrating microglial ramifications the we named "tunelling ramifications.". Interestingly, in the injured substantia nigra, the presence of TH+ vacuoles in the cytoplasm of numerous microglial cells strongly suggests that microglial ramifications support microphagocytosis targeted toward the cytoplasm of dopaminergic neurons. The precise function and molecular mechanisms of such unique interactions need to be further assessed. However, our work provides a set of original data that deepens our knowledge on the dialogue between microglia and neurons in a mouse model of Parkinson's diseas

Drug delivery to tumours using a novel 5-FU derivative encapsulated into lipid nanocapsules

In this work, a novel lipophilic 5-fluorouracil (5-FU) derivative was synthesised and encapsulated into lipid nanocapsules (LNC). 5-FU was modified with lauric acid to give a lipophilic mono-lauroyl-derivative (5-FU-C12, MW of about 342 g/mol, yield of reaction 70%). 5-FU-C12 obtained was efficiently encapsulated into LNC (encapsulation efficiency above 90%) without altering the physico-chemical characteristics of LNC. The encapsulation of 5-FU-C12 led to an increased stability of the drug when in contact with plasma being the drug detectable until 3 h following incubation. Cytotoxicity assay carried out using MTS on 2D cell culture showed that 5-FU-C12-loaded LNC had an enhanced cytotoxic effect on glioma (9L) and human colorectal (HTC-116) cancer cell line in comparison with 5-FU or 5-FU-C12. Then, HCT-116 tumour spheroids were cultivated and the reduction of spheroid volume was measured following treatment with drug-loaded LNC and drugs alone. Similar reduction on spheroids volume was observed following the treatment with drug-loaded LNC, 5-FU-C12 and 5-FU alone, while blank LNC displayed a reduction in cell viability only at high concentration. Globally, our data suggest that the encapsulation increased the activity of the 5-FU-C12. However, in-depth evaluations of LNC permeability into spheroids are needed to disclose the potential of these nanosystems for cancer treatment

In-depth phenotypic characterization of multicellular tumor spheroids: Effects of 5-Fluorouracil.

MultiCellular Tumor Spheroids (MCTS), which mimic the 3-Dimensional (3D) organization of a tumor, are considered as better models than conventional cultures in 2-Dimensions (2D) to study cancer cell biology and to evaluate the response to chemotherapeutic drugs. A real time and quantitative follow-up of MCTS with simple and robust readouts to evaluate drug efficacy is still missing. Here, we evaluate the chemotherapeutic drug 5-Fluorouracil (5-FU) response on the growth and integrity of MCTS two days after treatment of MCTS and for three colorectal carcinoma cell lines with different cohesive properties (HT29, HCT116 and SW480). We found different sensitivity to 5-FU for the three CRC cell lines, ranging from high (SW480), intermediate (HCT116) and low (HT29) and the same hierarchy of CRC cell lines sensitivity is conserved in 2D. We also evidence that 5-FU has a strong impact on spheroid cohesion, with the apparition of a number of single detaching cells from the spheroid in a 5-FU dose- and cell line-dependent manner. We propose an innovative methodology for the chemosensitivity evaluation in 3D MCTS that recapitulates and regionalizes the 5-FU-induced changes within MCTS over time. These robust phenotypic read-outs could be easily scalable for high-throughput drug screening that may include different types of cancer cells to take into account tumor heterogeneity and resistance to treatment

High-Frequency Mechanical Properties of Tumors Measured by Brillouin Light Scattering

International audienceThe structure of tumors can be recapitulated as an elastic frame formed by the connected cytoskeletons of the cells invaded by interstitial and intracellular fluids. The low-frequency mechanics of this poroelastic system, dictated by the elastic skeleton only, control tumor growth, penetration of therapeutic agents, and invasiveness. The high-frequency mechanical properties containing the additional contribution of the internal fluids have also been posited to participate in tumor progression and drug resistance, but they remain largely unexplored. Here we use Brillouin light scattering to produce label-free images of tumor microtissues based on the high-frequency viscoelastic modulus as a contrast mechanism. In this regime, we demonstrate that the modulus discriminates between tissues with altered tumorigenic properties. Our micrometric maps also reveal that the modulus is heterogeneously altered across the tissue by drug therapy, revealing a lag of efficacy in the core of the tumor. Exploiting high-frequency poromechanics should advance present theories based on viscoelasticity and lead to integrated descriptions of tumor response to drugs

Volume of the cohesive core of MCTS under drug treatment after transfer to new wells.

<p>Left. Typical images of spheroid cores at 48h for the three CRC cell lines after administration of 0 <b>μM (A, E, I)</b>, 10 μM <b>(B, F, J)</b> or 100 μM <b>(C, G, K)</b> 5-FU. The dotted circle represents the size of the control MCTS which is reported as a guide for the eye on other panels. Right. Time series of the mean MCTS volume relative to initial volume at day 0 for each particular condition after 5-FU treatment ranging from 0 to 100 μM (only 3 drug concentrations are reported for clarity). <b>(A-D)</b> HT29, <b>(E-H)</b> HCT116 and <b>(I-L)</b> SW480. Error bars: SEM (n = 7–12 for each cell line). Scale bar: 200 μm.</p

3D versus 2D 5-FU effect at 48h.

<p><b>(A)</b> 3D cell survival of HCT116, SW480 and HT29 MCTS 48 hours after 5-FU treatment ranging from 0 to 100 μM. Survival represents the ratio of MCTS volume at 48h for a given drug condition to the volume of control MCTS (n = 7–12). <b>(B)</b> 2D cell survival of HCT116, SW480 and HT29 cell lines 48 hours after 5-FU treatment ranging from 0 to 100 μM. Survival represents the ratio of the normalized cell area at 48h for a given drug condition to the control normalized cell area (no drug) (n = 3). Error bars: SD.</p

IC₅₀ values for 5-FU for the three cell lines at 24h and 48h in 2D versus 3D spheroids.

<p>A range of IC₅₀ values (e.g., 1–2 μM) indicates that the precise IC₅₀ was in between two concentrations tested.</p

Typical phase contrast images of the MCTS growth for the three CRC lines taken at 0h, 24h and 48h in the absence of drug.

<p><b>(A-C)</b> HT29, <b>(D-F)</b> HCT116 and <b>(G-I)</b> SW480. Scale bars: 200 μm.</p

Nature of cells in the outer layerof the SW480 spheroids at 48h.

<p><b>(A-D)</b> Phase contrast and <b>(E-H)</b> corresponding fluorescent images of living cells in green (calcein +) and dead cells in red (PI+) treated with 0, 2, 10 and 100 μM of 5-FU. Compared to control <b>(A,E)</b>, a gradual disaggregation of peripheral cells appears clearly since 2 μM of 5-FU <b>(B,F)</b> to 100 μM <b>(D,H)</b>. Cells in the outer layer are equally dead and living cells. Scale bar: 200 μm.</p