As far as micromedicines are concerned, we are interested in the microencapsulation of recombinant proteins, to generate microcarriers upon which living cells can be adsorbed, a highly challenging technology. The whole system forms a Pharmacologically Active Microcarrier (PAM) to be used in cell therapy in the context of neurodegenerative diseases. More precisely, the PAMs are used for tissue engineering, they will increase cell survival time as well as the differentiation and integration of grafted cells following transplants in animals, these micromedicines can also activate the regenerative potential of adult stem cells such as the MIAMI cells. Within the domain of nanomedicines, we are pursuing the development of lipid nanocapsules that act as biomimetic nanovectors resembling lipoproteins. We are studying systematically the biodistribution profiles of these nanomedicines depending on their route of administration, local or systemic. In particular, we are trying to define the essential physicochemical parameters of these nanovectors that, after administration, control the targeting of tumours. In the same way, we are trying to understand how these nanomedicines cross biological barriers and how they interact with cells. In terms of preclinical applications, we are focusing on glioblastomas. The route of administration can be systemic or local. The most promising results in terms of survival of tumour-bearing animals were obtained by infusing radioactive nanocapsules intratumourally, in order to achieve an in-situ radiotherapy approach.

Myeloproliferative neoplasms (MPNs, formerly called chronic myeloproliferative disorders) are clonal hematopoietic stem cell disorders characterized by the expansion of one or more of the myeloid lineages, including polymorphonuclear, erythroid, megakaryocytic, and mastocytic. The major complications of MPN are transformation into acute myeloid leukemia (occurring particularly in chronic myelogenous leukemia) and thrombotic and hemorrhagic events (most commonly observed in polycythemia vera and essential thrombocythemia). Renal involvement by MPN is infrequent. MPN-related glomerulopathy enlarges the spectrum of glomerular diseases associated with haematological neoplasms. MPN-related glomerulopathy is an under recognized late renal complication of MPN with poor prognosis. It is characterized clinically by heavy proteinuria and renal insufficiency. The histologic features of MPN-related glomerulopathy include variable degree of mesangial sclerosis and hypercellularity, segmental sclerosis, features of chronic thrombotic microangiopathy, and intracapillary hematopoietic cell infiltration. PDGF and TGFβ likely have a crucial role in the pathogenesis of MPN-related glomerulopathy. Furthermore, aggregation of circulating hematopoietic cells within glomerular capillaries could potentially result in endothelial injury and morphologic changes resembling chronic thrombotic microangiopathy. Greater awareness of this entity is needed to define diagnosis and possible therapies.

Constant renewal of cells occurs in most tissues throughout the adult lifetime and is insured by the activity of resident stem cells. Recent work has demonstrated the presence of adult stem cells in the Drosophila intestine and consequently, the Drosophila intestine has become a powerful model to understand adult stem cells in vivo. In this review, we summarize our current understanding of the mechanisms controlling cell fate decisions of the intestinal stem cells with a particular focus on the role of the Notch pathway in this process. We also summarize what is known about proliferation control of the intestinal stem cells, which is crucial to maintain tissue homeostasis during normal and environmentally stressful conditions.

All cardiomyopathies and more specifically myocardial infarction always evolve to cardiomyocytes death and the ensuing heart failure setting. So far, cardiac regenerative medicine has focused on the use of stem cells and completely ignored the resident cardiomyocytes, assumed in a postmitotic state. However, recent findings in zebrafish and mammalians challenge this view and suggest that these cells have some capacity to proliferate and can contribute to heart regeneration. In this review, we propose an overall synthesis about knowledge of the proliferative and regenerative capacities of resident cardiomyocytes, dealing with some mechanistic aspects. In the future, the accurate identification of molecular mechanisms allowing wake-up of resident cardiomyocyte proliferation will certainly open new therapeutic avenues in cardiac regeneration.

Treatment of acute respiratory distress syndrome (ARDS) has been subject to many researches, sometimes leading to intense controversy. New findings in this field are varied. Effects on prognosis of commonly used treatments for ARDS have recently been investigated. Consistently, prone position, previously known to improve oxygenation without effect on mortality, has been shown to improve survival of the most severely hypoxemic patients. Administration of neuromuscular blocking agents in the acute phase of ARDS has been also shown to be beneficial on survival. In contrast, the exact place of extracorporeal membrane oxygenation (ECMO) in ARDS management remains to be defined despite data suggesting its possible efficiency. In addition, a new era of research has emerged with the advent of cell therapy. Mesenchymal stem cells are able to both promote alveolar epithelium repair and prevent infections. Their efficacy in animal models of ARDS still needs to be confirmed by clinical trials. Finally, other promising therapies including beta-2 adrenergic agonists and omega-3 fatty acids have shown significant limitations in large clinical studies on ARDS.

Central nervous system pathologies are often characterized by the loss of cell populations. A promising therapy now being developed consists in using bioactive materials, associating grafted cells to biopolymers which provide a scaffold for the in vitro building of new tissues, to be implanted in vivo. In the present article, the state of the art of this field, at crossroads between microtechnology and neuroscience, is described in detail; thereafter our own approach and results about interactions between adult human neural stem cells and microstructured polymers are summarized and discussed. In a second part, some central nervous system repair strategies, based on cerebral tissue engineering, are presented. We will report the main results of our studies to work out and characterize in vivo a cerebral bioprosthesis.

The choice of salvage therapy for patients presenting relapsed chronic lymphocytic leukemia (CLL) has to take into account some factors influencing tumor resistance and comorbidities. Since 2010, new drugs targeting the tumor cells' signaling have been proposed for CLL patients. Waiting the results of various clinical trials evaluating these treatments, there is a need to describe the state-of-the-art concerning approved treatments such as chemotherapy and monoclonal antibodies.

Stroke is one of the leading causes of death and disability worldwide. Intravenous recombinant tissue plasminogen activator is the only available therapy for acute ischemic stroke, but its use is limited by a narrow therapeutic window and cannot stimulate endogenous repair and regeneration of damaged brain tissue. Stem cell-based approaches hold much promise as potential novel treatments to restore neurological function after stroke.

Cancer stem cells are a subject of increasing interest in oncology. In particular, several data suggest that cancer stem cells are involved in the mechanisms of tumor radioresistance, and may explain the therapeutic failures after radiotherapy. Because of its poor prognosis and high recurrence rate after irradiation, glioblastoma model is often studied in the search for new radiosensitizers. There are several preclinical data suggesting that cancer stem cells could be a potential therapeutic target for improving the biological effectiveness of radiation therapy. Through the example of glioblastoma, we review the main signaling pathways involved in the mechanisms of radiation resistance of cancer stem cells and for which pharmacological targeting could potentially enhance tumor radiosensitivity.