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Goulet, Francine

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Goulet

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Francine

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Université Laval. Département de réadaptation

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ncf10214495

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Voici les éléments 1 - 10 sur 24
  • PublicationAccès libre
    Le génie tissulaire au service de la compréhension du vivant
    (Société des Périodiques Flammarion, 2003-10-15) Germain, Lucie; Auger, François A.; Berthod, François; Goulet, Francine; Moulin, Véronique
    Le génie tissulaire est un nouveau domaine, qui permet l’étude des mécanismes physiologiques du vivant. Il s’agit d’une technologie fondée sur la capacité des cellules vivantes, en présence ou non de biomatériaux, à s’assembler en un tissu tridimensionnel. Elle constitue une voie intéressante ouvrant aux chercheurs la possibilité de considérer les cellules dans un contexte proche de celui retrouvé in vivo. Cet article résume les travaux en génie tissulaire menés par le laboratoire d’organogenèse expérimentale (LOEX) au cours des dernières années, dans le but de comprendre certains des mécanismes physiologiques et pathologiques de l’organisme humain. Ainsi, la cicatrisation cutanée, mais aussi les cellules souches, l’angiogenèse et les interactions cellulaires sont des secteurs ayant profité de l’apport du génie tissulaire.
  • PublicationRestreint
    Production of bioengineered cancer tissue constructs in vitro : epithelium–mesenchyme heterotypic interactions
    (Tissue Culture Association, 2001-07-01) Tremblay, Nathalie; Germain, Lucie; Wang, Chang Shu; Auger, François A.; Têtu, Bernard; Goulet, Francine
    A few models have been established to study cancer cells in vitro. However, the cellular interactions have rarely been studied specifically using bioengineered cancer constructs combining human carcinoma cells and tumor-associated fibroblasts. We developed an in vitro model of tridimensional bioengineered cancer tissue constructs (bCTC) by seeding mammary epithelial cancer cells or normal keratinocytes over a mesenchymal layer containing tumor-derived fibroblastic cells or normal skin fibroblasts. After the introduction of epithelial cells, each construct was cultured for another 10 d. Histologic analyses showed that carcinoma cell lines could invade the subjacent mesenchymal layer and that the capacity to migrate was related to the invasive potential of cancer cells and the type of fibroblasts used, while noninvasive populations did not. Of the tested epithelial cells, MDA-MB-231 and, to a lesser degree, HDQ-P1 cell lines were invasive, and the invasion was deeper into the mesenchymal component containing tumor-derived fibroblasts. However, with normal skin fibroblasts, the mesenchymal layer was degraded twice faster than with tumor-derived fibroblastic cells. MDA-MB-231 cells and normal keratinocytes induced the highest level of gelatinase B, and the level was lowest with the MCF-7 cell line. The activated form of gelatinase B was, however, induced to the highest levels in the keratinocyte-seeded bCTC containing tumor-derived but not normal fibroblasts. MDA-MB-231 was the only epithelial cancer cell line whose activity of gelatinase A was reduced when cocultured with tumor-derived fibroblasts but not under normal fibroblast stimulation. Finally, a 50/48-kDa gelatinase band has been observed in bCTCs with noninvasive epithelial cells only. Our study demonstrates the selective secretion of gelatinases according to the phenotype of the cells seeded in the various bCTCs.
  • PublicationRestreint
    Tissue-engineered human skin substitutes developed from collagen-populated hydrated gels : clinical and fundamental applications
    (Springer, 1998-11-01) Germain, Lucie; Auger, François A.; Rouabhia, Mahmoud; Berthod, François; Goulet, Francine; Moulin, Véronique
    The field of tissue engineering has opened several avenues in biomedical sciences, through ongoing progress. Skin substitutes are currently optimised for clinical as well as fundamental applications. The paper reviews the development of collagen-populated hydrated gels for their eventual use as a therapeutic option for the treatment of burn patients or chronic wounds: tools for pharmacological and toxicological studies, and cutaneous models for in vitro studies. These skin substitutes are produced by culturing keratinocytes on a matured dermal equivalent composed of fibroblasts included in a collagen gel. New biotechnological approaches have been developed to prevent contraction (anchoring devices) and promote epithelial cell differentiation. The impact of dermo-epidermal interactions on the differentiation and organisation of bio-engineered skin tissues has been demonstrated with human skin cells. Human skin substitutes have been adapted for percutaneous absorption studies and toxicity assessment. The evolution of these human skin substitutes has been monitored in vivo in preclinical studies showing promising results. These substitutes could also serve as in vitro models for better understanding of the immunological response and healing mechanism in human skin. Thus, such human skin substitutes present various advantages and are leading to the development of other bio-engineered tissues, such as blood vessels, ligaments and bronchi.
  • PublicationAccès libre
    What is new in mechanical properties of tissue-engineered organs
    (Springer, 1999-01-01) Germain, Lucie; Auger, François A.; Berthod, François; Goulet, Francine
    Tissue engineering is a promising new field based on expertise in cell biology, medicine and mechanical engineering. It raises exciting hopes of producing autologous tissue substitutes to replace altered organs. This challenge involves highly specialized technology in order to provide the proper shape to the tissue and promote the maintenance of its native physiological properties. Primary cell populations may lose some of their functional and morphological properties in vitro in the absence of a proper environment. In order to maintain cell integrity, a three-dimensional matrix that mimics the in vivo environment as closely as possible was developed, according to the type of tissue produced [1, 5, 18, 26, 27, 29, 34, 35].
  • PublicationRestreint
    Establishment and characterization of a new cell line derived from a human primary breast carcinoma
    (Elsevier, 2000-07-01) Germain, Lucie; Wang, Chang Shu; Lavoie, Josée; Drouin, Régen; Auger, François; Têtu, Bernard; Champetier, Serge.; Goulet, Francine
    A new cell line, designated HDQ-P1, was successfully established from a primary ductal infiltrating mammary carcinoma by using a 3T3 feeder layer lethally irradiated to 60 Gy. The HDQ-P1 cells have been grown in culture for over 115 passages and have a doubling time of 60 hours. Characterization of the cell line was performed. This included morphology by light and transmission electron microscopy, karyotype, growth rate, telomerase expression, tumor antigen expression, xenograft implantation into nude mice, colony formation in soft agar, TP53 sequencing, and gene copy number of C-MYC, C-ERBB-2, and C-H-RAS oncogenes. The epithelial nature of this cell line was confirmed by ultrastructural analysis, expression of cytokeratins, and epithelial membrane antigen. The HDQ-P1 cells possess an extensively rearranged and polyploid karyotype, with an average of 20 recurrent marker chromosomes. Scatchard analysis demonstrated that both primary tumor and HDQ-P1 cells were estrogen- and progesterone-receptor negative. The HDQ-P1 cells had the same expression of human telomerase reverse transcriptase as other established breast cancer cell lines such as MDA-MB-231, SK-BR-3, and MCF-7. Direct DNA sequencing showed a point mutation which yielded to a stop codon at the amino acid 213 in exon 6 of the TP53 gene. A five-fold amplification of C-MYC was observed in HDQ-P1 cells. No amplification of C-ERBB-2 and C-H-RAS genes were observed. This cell line presents unique characteristics and may prove to be a good experimental model for investigating breast cancer biology.
  • PublicationRestreint
    Production of tissue-engineered three-dimensional human bronchial models.
    (springerLink, 2003-06-01) Boutet, Marianne; Germain, Lucie; Boulet, Louis-Philippe; Paquette, Jean-Sébastien; Auger, François A.; Laviolette, Michel; Bernier, Vincent; Goulet, Francine; Tremblay, Jacques-P.
    We have reported morphological and functional features of cells isolated from human bronchial biopsies. Both epithelial and fibroblastic cells were isolated from the same biopsies using collagenase. A few models have been established to study normal bronchial response to various agents and to understand the mechanisms responsible for some disorders, such as asthma. We produced three-dimensional bronchial equivalents in culture, using human epithelial and fibroblastic cells. We previously showed that peripheral anchorage can prevent the dramatic collagen contraction in gels seeded with fibroblasts when properly adapted to the size and type of cultured tissues. Our bilayered bronchial constructs were anchored and cultured under submerged conditions and at the air-liquid interface. Three culture media were compared. Serum-free medium supplemented with retinoic acid (5 x 10(-8) M) was found to be the best for maintenance of bronchial cell properties in the reconstructed bronchial tissue. Immunohistological and ultrastructural analyses showed that these equivalents present good structural organization, allowing ciliogenesis to occur in culture. Moreover, human bronchial goblet cells could differentiate and secrete mucus with culture time. Laminin, a major constituent of the basement membrane and basal cells, was also detected at the mesenchymoepithelial interface. Such models will be useful for studying human bronchial properties in vitro.
  • PublicationRestreint
    Skin equivalent produced with human collagen
    (Society for In Vitro Biology, 1995-06-01) Noël, Bernard; Tremblay, Nathalie; Germain, Lucie; Auger, François A.; López Valle, Carlos Antonio; Guignard, Rina; Goulet, Francine
    Several studies have recently been conducted on cultured skin equivalent (SE), prepared using human keratinocytes seeded on various types of dermal equivalents (DE). We previously showed the advantages of our anchorage method in preventing the severe surface reduction of DE due to fibroblast contractile properties in vitro. A new anchored human SE was established in our laboratory in order to obtain a bioengineered tissue that would possess the appropriate histological and biological properties. In order to compare the effects of different collagen origins on the evolution of SE in vitro, human keratinocytes were seeded on three types of anchored DE. A comparative study was carried out between bovine SE (bSE), human SE (hSE), and human skin equivalent containing additional dermal matrix components (hSE +). Immunohistological analysis showed that hSE and hSE+ presented good structural organization, including the deposition of several basement membrane constituents. Higher amounts of transglutaminase, ceramides, and keratin 1 were detected in the epidermal layers of all SE when cultured at the air-liquid interface. However, a 92 kDa gelatinase activity was higher in bovine skin equivalent (bSE) compared to hSE cultures. The use of human collagens comparatively to bovine collagen as SE matricial component delayed the degradation of the dermal layer in culture.
  • PublicationAccès libre
    Grafting on nude mice of living skinquivalents produced using human collagens
    (Williams & Wilkins Co, 1996-08-15) Germain, Lucie; Xu, Wen; Auger, François A.; López Valle, Carlos Antonio; Guignard, Rina; Rouabhia, Mahmoud; Goulet, Francine
    Autologous epidermal transplantation for human burn management is an example of a significant breakthrough in tissue engineering. However, the main drawback with this treatment remains the fragility of these grafts during and after surgery. A new human bilayered skin equivalent (hSE) was produced in our laboratory to overcome this problem. The aim of the present work was to study skin regeneration after hSE grafting onto nude mice. A comparative study was carried out over a period of 90 days, between anchored bovine skin equivalent, hSE and hSE+, the latter containing additional matrix components included at concentrations similar to those in human skin in vivo. The addition of a dermal layer to the epidermal sheet led to successful graft take, enhanced healing, and provided mechanical resistance to the grafts after transplantation. In situ analysis of the grafts showed good ultrastructural organization, including the deposition of a continuous basement membrane 1 week after surgery.
  • PublicationAccès libre
    Three-dimensional production of bronchi in vitro
    (Pulsus Group, 1998-01-01) Tremblay, Nathalie; Germain, Lucie; Chakir, Jamila; Boulet, Louis-Philippe; Paquette, Jean-Sébastien; Auger, François A.; Laviolette, Michel; Goulet, Francine
  • PublicationAccès libre
    Tissue-engineered ACL : from the laboratory to the knee Joint
    (Association canadienne d'orthopédie, 2006-08-01) Cloutier, Réjean; Germain, Lucie; Bouchard, Ludovic; Robitaille, Hubert; Auger, François A.; Lamontagne, Jean; Goulet, Francine