We are always looking for highly-motivated individuals to join the LCPO! Interested undergraduate and graduate students can apply to the following offers. They are also strongly encouraged to contact LCPO's researchers directly.
DEVELOPMENT OF A POST-SURGICAL POLYMER IMPLANT FOR THE TREATMENT OF GLIOBLASTOMA BY PHOTO- OR RADIODYNAMIC THERAPY (PDT/RDT)
Category: Post docs
Duration: 12 months
Salary: Gross : Between 2,750 and 3,035 €, depending on the experience of the candidate.
Laboratory: LCPO / IBGC
Contacts : Elisabeth Garanger
We are looking for a highly motivated chemist ready to interact with biologists and clinicians. Applicants should hold a PhD in Chemistry (Organic, Polymer) with solid expertise in biomacromolecular chemistry, hydrogel formulation and characterization. A know-how in 3D cell culture experiments will be a plus.
This offer is for a 12 month post-doctoral fellowship. A grant has been submitted for the funding of an additional year.
The recruited post-doc will be working with 2 teams:
- At LCPO: Self-Assembly and Life Sciences (Prof. S. Lecommandoux)
- At IBGC: Gbmetabo (Dr. T Daubon)
Applicants are invited to submit a complete CV and a motivation letter to the contact persons indicated below.
Applications will be considered until the position is filled.
- Dr. Elisabeth Garanger, Laboratoire de Chimie des Polymères Organiques (CNRS UMR 5629)
- Dr. Océane Martin, Institut de Biochimie et Génétique Cellulaire (CNRS UMR 5095)
Glioblastoma (GB), a grade IV malignant glioma, is one of the most lethal types of human cancer, due to its aggressive and highly invasive characteristics. Approximately 40% of patients with GB are eligible for surgery, and submitted afterwards to adjuvant radio- and oral chemotherapy. A major challenge for the neurosurgeon is the total removal of cancerous cells from the tumor site. Unfortunately, tumor resection is most of the time subtotal and remaining cancer cells are responsible of local or distant tumor relapses.
We have initiated a multidisciplinary research project involving chemists, biologists and clinicians to develop a post-surgical implant allowing the local and controlled release of a therapeutic active ingredient targeted against GB cells. The implant will consist in a dynamic polymer-based hydrogel whose mechanical properties will be adapted to the brain tissue. This soft hydrogel will be loaded with a nanocarrier consisting of a biocompatible ROS-sensitive polypeptide covalently coupled to a FDA-approved photosensitizing molecule (PS). The ultimate goal is the release of the PS upon local irradiation to induce the apoptosis of remanent GB cell
The recruited post-doc will work on the optimization of the hydrogel (formulation and mechanical properties), loading of the PS-nanocarrier, and evaluate its efficacy in 3D-tumor models.