Your search keyword '"Profico D. C."' showing total 6 results

1. Human neural stem cells derived from fetal human brain communicate with each other and rescue ischemic neuronal cells through tunneling nanotubes

Author

Capobianco, D. L., De Zio, R., Profico, D. C., Gelati, M., Simone, L., D’Erchia, A. M., Di Palma, F., Mormone, E., Bernardi, P., Sbarbati, A., Gerbino, A., Pesole, G., Vescovi, A. L., Svelto, M., and Pisani, F.

Published

2024

2. Phase I clinical trial of intracerebroventricular transplantation of allogeneic neural stem cells in people with progressive multiple sclerosis

Author

Leone, M, Gelati, M, Profico, D, Gobbi, C, Pravata, E, Copetti, M, Conti, C, Abate, L, Amoruso, L, Apollo, F, Balzano, R, Bicchi, I, Carella, M, Ciampini, A, Colosimo, C, Crociani, P, D'Aloisio, G, Di Viesti, P, Ferrari, D, Fogli, D, Fontana, A, Frondizi, D, Grespi, V, Kuhle, J, Laborante, A, Lombardi, I, Muzi, G, Paci, F, Placentino, G, Popolizio, T, Ricciolini, C, Sabatini, S, Silveri, G, Spera, C, Stephenson, D, Stipa, G, Tinella, E, Zarrelli, M, Zecca, C, Ventura, Y, D'Alessandro, A, Peruzzotti-Jametti, L, Pluchino, S, Vescovi, A, Leone M. A., Gelati M., Profico D. C., Gobbi C., Pravata E., Copetti M., Conti C., Abate L., Amoruso L., Apollo F., Balzano R. F., Bicchi I., Carella M., Ciampini A., Colosimo C., Crociani P., D'Aloisio G., Di Viesti P., Ferrari D., Fogli D., Fontana A., Frondizi D., Grespi V., Kuhle J., Laborante A., Lombardi I., Muzi G., Paci F., Placentino G., Popolizio T., Ricciolini C., Sabatini S., Silveri G., Spera C., Stephenson D., Stipa G., Tinella E., Zarrelli M., Zecca C., Ventura Y., D'Alessandro A., Peruzzotti-Jametti L., Pluchino S., Vescovi A. L., Leone, M, Gelati, M, Profico, D, Gobbi, C, Pravata, E, Copetti, M, Conti, C, Abate, L, Amoruso, L, Apollo, F, Balzano, R, Bicchi, I, Carella, M, Ciampini, A, Colosimo, C, Crociani, P, D'Aloisio, G, Di Viesti, P, Ferrari, D, Fogli, D, Fontana, A, Frondizi, D, Grespi, V, Kuhle, J, Laborante, A, Lombardi, I, Muzi, G, Paci, F, Placentino, G, Popolizio, T, Ricciolini, C, Sabatini, S, Silveri, G, Spera, C, Stephenson, D, Stipa, G, Tinella, E, Zarrelli, M, Zecca, C, Ventura, Y, D'Alessandro, A, Peruzzotti-Jametti, L, Pluchino, S, Vescovi, A, Leone M. A., Gelati M., Profico D. C., Gobbi C., Pravata E., Copetti M., Conti C., Abate L., Amoruso L., Apollo F., Balzano R. F., Bicchi I., Carella M., Ciampini A., Colosimo C., Crociani P., D'Aloisio G., Di Viesti P., Ferrari D., Fogli D., Fontana A., Frondizi D., Grespi V., Kuhle J., Laborante A., Lombardi I., Muzi G., Paci F., Placentino G., Popolizio T., Ricciolini C., Sabatini S., Silveri G., Spera C., Stephenson D., Stipa G., Tinella E., Zarrelli M., Zecca C., Ventura Y., D'Alessandro A., Peruzzotti-Jametti L., Pluchino S., and Vescovi A. L.

Abstract

We report the analysis of 1 year of data from the first cohort of 15 patients enrolled in an open-label, first-in-human, dose-escalation phase I study (ClinicalTrials.gov: NCT03282760, EudraCT2015-004855-37) to determine the feasibility, safety, and tolerability of the transplantation of allogeneic human neural stem/progenitor cells (hNSCs) for the treatment of secondary progressive multiple sclerosis. Participants were treated with hNSCs delivered via intracerebroventricular injection in combination with an immunosuppressive regimen. No treatment-related deaths nor serious adverse events (AEs) were observed. All participants displayed stability of clinical and laboratory outcomes, as well as lesion load and brain activity (MRI), compared with the study entry. Longitudinal metabolomics and lipidomics of biological fluids identified time- and dose-dependent responses with increased levels of acyl-carnitines and fatty acids in the cerebrospinal fluid (CSF). The absence of AEs and the stability of functional and structural outcomes are reassuring and represent a milestone for the safe translation of stem cells into regenerative medicines.

Published

2023

3. Culturing and Expansion of “Clinical Grade” Neural Stem Cells from the Fetal Human Central Nervous System

Author

Deleyrolle, LP, Gelati, M, Profico, D, Ferrari, D, Vescovi, A, Gelati M., Profico D. C., Ferrari D., Vescovi A. L., Deleyrolle, LP, Gelati, M, Profico, D, Ferrari, D, Vescovi, A, Gelati M., Profico D. C., Ferrari D., and Vescovi A. L.

Abstract

NSCs have been demonstrated to be very useful in grafts into the mammalian central nervous system to investigate the exploitation of NSC for the therapy of neurodegenerative disorders in animal models of neurodegenerative diseases. To push cell therapy in CNS on stage of clinical application, it is necessary to establish a continuous and standardized, clinical grade (i.e., produced following the good manufacturing practice guidelines) human neural stem cell lines. In this chapter we will illustrate some of the protocols for the production and characterization routinely used into our GMP “cell factory” for the production of “clinical grade” human neural stem cell lines already in use in clinical trials on neurodegenerative diseases, particularly amyotrophic lateral sclerosis (ALS— Clinicaltrials.gov number NCT01640067) and secondary progressive multiple sclerosis (SPMS— Clinicaltrials.gov number NCT03282760).

Published

2022

4. Human Neural Stem Cell-Based Drug Product: Clinical and Nonclinical Characterization

Author

Profico, D, Gelati, M, Ferrari, D, Sgaravizzi, G, Ricciolini, C, Projetti Pensi, M, Muzi, G, Cajola, L, Copetti, M, Ciusani, E, Pugliese, R, Gelain, F, Vescovi, A, Profico D. C., Gelati M., Ferrari D., Sgaravizzi G., Ricciolini C., Projetti Pensi M., Muzi G., Cajola L., Copetti M., Ciusani E., Pugliese R., Gelain F., Vescovi A. L., Profico, D, Gelati, M, Ferrari, D, Sgaravizzi, G, Ricciolini, C, Projetti Pensi, M, Muzi, G, Cajola, L, Copetti, M, Ciusani, E, Pugliese, R, Gelain, F, Vescovi, A, Profico D. C., Gelati M., Ferrari D., Sgaravizzi G., Ricciolini C., Projetti Pensi M., Muzi G., Cajola L., Copetti M., Ciusani E., Pugliese R., Gelain F., and Vescovi A. L.

Abstract

Translation of cell therapies into clinical practice requires the adoption of robust production protocols in order to optimize and standardize the manufacture and cryopreservation of cells, in compliance with good manufacturing practice regulations. Between 2012 and 2020, we conducted two phase I clinical trials (EudraCT 2009-014484-39, EudraCT 2015-004855-37) on amyotrophic lateral sclerosis secondary progressive multiple sclerosis patients, respectively, treating them with human neural stem cells. Our production process of a hNSC-based medicinal product is the first to use brain tissue samples extracted from fetuses that died in spontaneous abortion or miscarriage. It consists of selection, isolation and expansion of hNSCs and ends with the final pharmaceutical formulation tailored to a specific patient, in compliance with the approved clinical protocol. The cells used in these clinical trials were analyzed in order to confirm their microbiological safety; each batch was also tested to assess identity, potency and safety through morphological and functional assays. Preclinical, clinical and in vitro nonclinical data have proved that our cells are safe and stable, and that the production process can provide a high level of reproducibility of the cultures. Here, we describe the quality control strategy for the characterization of the hNSCs used in the above-mentioned clinical trials.

Published

2022

5. Retrieval of germinal zone neural stem cells from the cerebrospinal fluid of premature infants with intraventricular hemorrhage

Author

Fernandez-Munoz, B, Rosell-Valle, C, Ferrari, D, Alba-Amador, J, Montiel, M, Campos-Cuerva, R, Lopez-Navas, L, Munoz-Escalona, M, Martin-Lopez, M, Profico, D, Blanco, M, Giorgetti, A, Gonzalez-Munoz, E, Marquez-Rivas, J, Sanchez-Pernaute, R, Fernandez-Munoz B., Rosell-Valle C., Ferrari D., Alba-Amador J., Montiel M. A., Campos-Cuerva R., Lopez-Navas L., Munoz-Escalona M., Martin-Lopez M., Profico D. C., Blanco M. F., Giorgetti A., Gonzalez-Munoz E., Marquez-Rivas J., Sanchez-Pernaute R., Fernandez-Munoz, B, Rosell-Valle, C, Ferrari, D, Alba-Amador, J, Montiel, M, Campos-Cuerva, R, Lopez-Navas, L, Munoz-Escalona, M, Martin-Lopez, M, Profico, D, Blanco, M, Giorgetti, A, Gonzalez-Munoz, E, Marquez-Rivas, J, Sanchez-Pernaute, R, Fernandez-Munoz B., Rosell-Valle C., Ferrari D., Alba-Amador J., Montiel M. A., Campos-Cuerva R., Lopez-Navas L., Munoz-Escalona M., Martin-Lopez M., Profico D. C., Blanco M. F., Giorgetti A., Gonzalez-Munoz E., Marquez-Rivas J., and Sanchez-Pernaute R.

Abstract

Intraventricular hemorrhage is a common cause of morbidity and mortality in premature infants. The rupture of the germinal zone into the ventricles entails loss of neural stem cells and disturbs the normal cytoarchitecture of the region, compromising late neurogliogenesis. Here we demonstrate that neural stem cells can be easily and robustly isolated from the hemorrhagic cerebrospinal fluid obtained during therapeutic neuroendoscopic lavage in preterm infants with severe intraventricular hemorrhage. Our analyses demonstrate that these neural stem cells, although similar to human fetal cell lines, display distinctive hallmarks related to their regional and developmental origin in the germinal zone of the ventral forebrain, the ganglionic eminences that give rise to interneurons and oligodendrocytes. These cells can be expanded, cryopreserved, and differentiated in vitro and in vivo in the brain of nude mice and show no sign of tumoral transformation 6 months after transplantation. This novel class of neural stem cells poses no ethical concerns, as the fluid is usually discarded, and could be useful for the development of an autologous therapy for preterm infants, aiming to restore late neurogliogenesis and attenuate neurocognitive deficits. Furthermore, these cells represent a valuable tool for the study of the final stages of human brain development and germinal zone biology.

Published

2020

6. Results from Phase I Clinical Trial with Intraspinal Injection of Neural Stem Cells in Amyotrophic Lateral Sclerosis: A Long-Term Outcome

Author

Mazzini, L, Gelati, M, Profico, D, Soraru, G, Ferrari, D, Copetti, M, Muzi, G, Ricciolini, C, Carletti, S, Giorgi, C, Spera, C, Frondizi, D, Masiero, S, Stecco, A, Cisari, C, Bersano, E, Marchi, F, Sarnelli, M, Querin, G, Cantello, R, Petruzzelli, F, Maglione, A, Zalfa, C, Binda, E, Visioli, A, Trombetta, D, Torres, B, Bernardini, L, Gaiani, A, Massara, M, Paolucci, S, Boulis, N, Vescovi, A, Mazzini L., Gelati M., Profico D. C., Soraru G., Ferrari D., Copetti M., Muzi G., Ricciolini C., Carletti S., Giorgi C., Spera C., Frondizi D., Masiero S., Stecco A., Cisari C., Bersano E., Marchi F. D., Sarnelli M. F., Querin G., Cantello R., Petruzzelli F., Maglione A., Zalfa C., Binda E., Visioli A., Trombetta D., Torres B., Bernardini L., Gaiani A., Massara M., Paolucci S., Boulis N. M., Vescovi A. L., Mazzini, L, Gelati, M, Profico, D, Soraru, G, Ferrari, D, Copetti, M, Muzi, G, Ricciolini, C, Carletti, S, Giorgi, C, Spera, C, Frondizi, D, Masiero, S, Stecco, A, Cisari, C, Bersano, E, Marchi, F, Sarnelli, M, Querin, G, Cantello, R, Petruzzelli, F, Maglione, A, Zalfa, C, Binda, E, Visioli, A, Trombetta, D, Torres, B, Bernardini, L, Gaiani, A, Massara, M, Paolucci, S, Boulis, N, Vescovi, A, Mazzini L., Gelati M., Profico D. C., Soraru G., Ferrari D., Copetti M., Muzi G., Ricciolini C., Carletti S., Giorgi C., Spera C., Frondizi D., Masiero S., Stecco A., Cisari C., Bersano E., Marchi F. D., Sarnelli M. F., Querin G., Cantello R., Petruzzelli F., Maglione A., Zalfa C., Binda E., Visioli A., Trombetta D., Torres B., Bernardini L., Gaiani A., Massara M., Paolucci S., Boulis N. M., and Vescovi A. L.

Abstract

The main objective of this phase I trial was to assess the feasibility and safety of microtransplanting human neural stem cell (hNSC) lines into the spinal cord of patients with amyotrophic lateral sclerosis (ALS). Eighteen patients with a definite diagnosis of ALS received microinjections of hNSCs into the gray matter tracts of the lumbar or cervical spinal cord. Patients were monitored before and after transplantation by clinical, psychological, neuroradiological, and neurophysiological assessment. For up to 60 months after surgery, none of the patients manifested severe adverse effects or increased disease progression because of the treatment. Eleven patients died, and two underwent tracheotomy as a result of the natural history of the disease. We detected a transitory decrease in progression of ALS Functional Rating Scale Revised, starting within the first month after surgery and up to 4 months after transplantation. Our results show that transplantation of hNSC is a safe procedure that causes no major deleterious effects over the short or long term. This study is the first example of medical transplantation of a highly standardized cell drug product, which can be reproducibly and stably expanded ex vivo, comprising hNSC that are not immortalized, and are derived from the forebrain of the same two donors throughout this entire study as well as across future trials. Our experimental design provides benefits in terms of enhancing both intra- and interstudy reproducibility and homogeneity. Given the potential therapeutic effects of the hNSCs, our observations support undertaking future phase II clinical studies in which increased cell dosages are studied in larger cohorts of patients. Stem Cells Translational Medicine 2019

Published

2019