Preclinical good laboratory practice-compliant safety study to evaluate biodistribution and tumorigenicity of a cartilage advanced therapy medicinal product (ATMP)

Zscharnack, Matthias, Krause, Christoph, Aust, Gabriela, Thümmler, Christian, Peinemann , Frank, Keller, Thomas, Smink, Jeske J., Holland, Heidrun, Somerson, Jeremy S., Knauer, Jens, Schulz, Ronny M., Lehmann, Jörg

27 July 2015

Background: The clinical development of advanced therapy medicinal products (ATMPs), a new class of drugs, requires initial safety studies that deviate from standard non-clinical safety protocols. The study provides a strategy to address the safety aspects of biodistribution and tumorigenicity of ATMPs under good laboratory practice (GLP) conditions avoiding cell product manipulation. Moreover, the strategy was applied on a human ATMP for cartilage repair.

Bioverteilung

Tumorerzeuger

Sicherheit

ATMP

Knorpelaufbau

Chondrozyten

Biodistribution

Tumorigenicity

Safety

ATMP

Cartilage repair

Chondrocytes

ddc:610

Preclinical good laboratory practice-compliant safety study to evaluate biodistribution and tumorigenicity of a cartilage advanced therapy medicinal product (ATMP)

Zscharnack, Matthias, Krause, Christoph, Aust, Gabriela, Thümmler, Christian, Peinemann, Frank, Keller, Thomas, Smink, Jeske J., Holland, Heidrun, Somerson, Jeremy S., Knauer, Jens, Schulz, Ronny M., Lehmann, Jörg

January 2015

Background: The clinical development of advanced therapy medicinal products (ATMPs), a new class of drugs, requires initial safety studies that deviate from standard non-clinical safety protocols. The study provides a strategy to address the safety aspects of biodistribution and tumorigenicity of ATMPs under good laboratory practice (GLP) conditions avoiding cell product manipulation. Moreover, the strategy was applied on a human ATMP for cartilage repair.

info:eu-repo/classification/ddc/610

ddc:610

Mezenchymové stromální multipotentní buňky v ortopedii: potenciace hojení kosti / Multipotent mesenchymal stromal cells in orthopedic: Potentiation of bone healing

Stehlík, David

January 2015

The aim of the thesis was development of an innovative treatment of bone defects. Human multipotent mesenchymal stromal cells (MSC) play a crucial role in bone healing. Clinical applications of MSC require large amount of cells, which could be obtained by autologous expansion of MSC harvested from bone marrow. As a first step, the standard protocol of MSC expansion based on αMEM medium and fetal bovine serum (FBS) was used. Experiments replacing FBS by pooled human serum (HS) in the culture medium concluded in patenting of a new MSC cultivation protocol (EU 1999250, CR 301141). This one-step cultivation protocol and xenogeneic protein-free cultivation medium is based on CellGro® for Hematopoietic Cells' Medium, HS, human recombinant growth factors, dexamethasone, insulin and ascorbic acid. The preclinical in vitro and in vivo experiments with MSC from both expansion protocols were carried out. Fibrillar polylactic scaffolds were seeded with MSC, cultured, differentiated and implanted in immunodeficient mice (NOD/LtSz-Rag1-). Bone-like mineralized tissue containing vessels was observed. The MSC cultured according to patented method were classified as Advanced-therapy Medicinal Product and has to fulfil the European Medicines Agency regulations to enter the clinical trials. Nevertheless the use of MSC seems...

Mezenchymové stromální multipotentní buňky v ortopedii: potenciace hojení kosti / Multipotent mesenchymal stromal cells in orthopedic: Potentiation of bone healing

Stehlík, David

January 2015

The aim of the thesis was development of an innovative treatment of bone defects. Human multipotent mesenchymal stromal cells (MSC) play a crucial role in bone healing. Clinical applications of MSC require large amount of cells, which could be obtained by autologous expansion of MSC harvested from bone marrow. As a first step, the standard protocol of MSC expansion based on αMEM medium and fetal bovine serum (FBS) was used. Experiments replacing FBS by pooled human serum (HS) in the culture medium concluded in patenting of a new MSC cultivation protocol (EU 1999250, CR 301141). This one-step cultivation protocol and xenogeneic protein-free cultivation medium is based on CellGro® for Hematopoietic Cells' Medium, HS, human recombinant growth factors, dexamethasone, insulin and ascorbic acid. The preclinical in vitro and in vivo experiments with MSC from both expansion protocols were carried out. Fibrillar polylactic scaffolds were seeded with MSC, cultured, differentiated and implanted in immunodeficient mice (NOD/LtSz-Rag1-). Bone-like mineralized tissue containing vessels was observed. The MSC cultured according to patented method were classified as Advanced-therapy Medicinal Product and has to fulfil the European Medicines Agency regulations to enter the clinical trials. Nevertheless the use of MSC seems...

ATMP Process : Improved Energy Efficiency in TMP Refining Utilizing Selective Wood Disintegration and Targeted Application of Chemicals

Gorski, Dmitri

January 2011

This thesis is focused on the novel wood chip refining process called AdvancedThermomechanical Pulp (ATMP) refining. ATMP consists of mechanical pretreatmentof chips in Impressafiner and Fiberizer prior to first stage refining atincreased intensity. Process chemicals (this study was concentrated on hydrogenperoxide and magnesium hydroxide) are introduced into the first stage refiner.It is known that the use of chemicals in TMP process and first stage refining atelevated intensity can reduce the energy demands of refining. The downside is thatthey also alter the character of the produced pulp. Reductions in fibre length andtear index are usually the consequences of refining at elevated intensity. Additionof chemicals usually leads to reduction of the light scattering coefficient. Usingstatistical methods it was shown that it is possible to maintain the TMP character ofthe pulp using the ATMP process. This is explained by a separation of thedefibration and the fibre development phases in refining. This separation allowsdefibration of chips to fibres and fibre bundles without addition of chemicals orincrease in refining intensity. Chemicals are applied in the fibre developmentphase only (first stage refiner). The energy demand in refining to reach tensileindex of 25 Nm/g was reduced by up to 1.1 MWh/odt (42 %) using the ATMPprocess on Loblolly pine. The energy demand in refining of White spruce, requiredto reach tensile index of 30 Nm/g, was reduced by 0.65 MWh/odt (37%).Characterizations of individual fibre properties, properties of sheets made fromlong fibre fractions and model fibre sheets with different fines fractions werecarried out. It was established that both the process equipment configuration (i.e.the mechanical pre‐treatment and the elevated refining intensity) and the additionof process chemicals in the ATMP process influence fibre properties such as external and internal fibrillation as well as the amount of split fibres. Improvementof these properties translated into improved properties of sheets, made from thelong fibre fractions of the studied pulps. The quality of the fines fraction alsoimproved. However, the mechanisms of improvement in the fines quality seem tobe different for fines, generated using improved process configuration andaddition of process chemicals. The first type of fines contributed to better bondingof model long fibre sheets through the densification of the structure. Fines whichhave been influenced by the addition of the process chemicals seemed in additionto improve bonding between long fibres by enhancing the specific bond strength.The improved fibre and fines properties also translated into better airpermeability and surface roughness of paper sheets, properties which areespecially important for supercalendered (SC) printing paper. The magnitude offibre roughening after moistening was mainly influenced by the processequipment configuration while the addition of process chemicals yielded lowestfinal surface roughness due to the lowest initial surface roughness. There was nodifference in how fines fractions from the studied processes influenced the fibreroughening. However, fines with better bonding yielded model fibre sheets withhigher PPS, probably due to their consolidation around fibre joints. Hence, thedecrease in PPS can probably be attributed to the improvements in the long fibrefraction properties while the improvement of fines quality contributed to thereduction of air permeability.The process chemicals, utilized in the ATMP process (Mg(OH)2 and H2O2) alsoproved to be an effective bleaching system. Comparable increases in brightnesscould be reached using the ATMP process and conventional tower bleaching.Maximum brightness of the pulp was reached after approximately 10 minutes ofhigh‐consistency storage after refining or 40 minutes of conventional bleaching.This study was conducted using a pilot scale refiner system operated as a batchprocess. Most of the experiments were performed using White spruce (Piceaglauca). In Paper I, Loblolly pine (Pinus taeda) was used. It is believed that theresults presented in this thesis are valid for other softwood raw materials as well,but this limitation should be considered.

ATMP

TMP

Hydrogen Peroxide

Magnesium Hydroxide

Mechanical Pre-Treatment

Fibre Characterisation

Refiner Bleaching

SC Paper

Newsprint

Cellulose and paper engineering

Cellulosa- och pappersteknik

Isolation et caractérisation des cellules stromales mésenchymateuses multipotentes du tissu adipeux: Étude des sous-populations et comparaison avec la moelle osseuse. / Isolation and characterization of multipotent mesenchymal stromal cells from adipose tissue: study of sub-populations and comparison with bone marrow.

Busser, Hélène

14 December 2015

Multipotent mesenchymal stromal cells (MSC) were first discovered in bone marrow and can be isolated from “virtually all organs”. They could participate in tissue maintenance and self-renewing process. They are able to adhere to plastic surfaces and acquire a fibroblastic shape when isolated. They are characterized by a particular phenotype and are able to differentiate into several cell types if cultivated in a specific induction medium. These characteristics were defined on MSC in culture and do not represent how they may be in situ.MSC present particular properties. They can secrete growth factors and several cytokines that give them a trophic activity on one hand and the ability to modulate the immune system on the other hand. They are also able to differentiate. These different properties make them an attractive candidate for cell therapy.MSC are already the focus of several pre-clinical and clinical studies. Nevertheless, the results of these studies are difficult to interpret due to limited understanding of their basic biology. MSC are poorly defined in situ and are heterogeneous. Their heterogeneity is dictated by their tissue of origin and cell preparation. To date, there is no standard protocol for MSC isolation and culture. This leads to numerous questions regarding patient safety, and these questions require answers.The first part of the work deals with the methods used to optimize the extraction of MSC and purification from adipose tissue, one of the main sources of autologous MSC with bone marrow. Classical methods require an enzymatic digestion step. The enzyme used and the duration of adipose tissue digestion time can induce cellular alterations and modify cell functions. Moreover, the addition of a xenobiotic increases the risk of contamination and complicates the monitoring of good manufacturing practices (GMP). We propose a method that does not require this enzymatic digestion step while being easier, safer, faster, gentler and less expensive. Compared to the classical enzymatic method, our method yields an equivalent number of MSC from adipose tissue while preserving their properties.The second part of this work focuses on the characterization of the MSC subpopulations from adipose tissue and compares them to those from bone marrow, which are the historical gold standard. The study made it possible to deepen the knowledge of MSC surface markers in situ from these 2 sources. It also evaluated the various properties of the isolated subpopulations thanks to the cell surface markers CD271, SUSD2, MSCA-1, CD44 and CD34. We showed that MSC from bone marrow express MSCA-1, CD271 and SUSD2 markers in situ. We also found that a population clearly positive for the CD34 does exist in situ with different properties compared to those of the unselected populations or the negative counterpart. 2 populations that are negative and positive for CD44 also exist with similar properties.In contrast to bone marrow MSC, only one selection was able to effectively isolate MSC from adipose tissue by a positive selection based on the expression of CD34. We also isolated a CD271+ population but only from lipoaspirate samples and not from abdominoplasty samples. Collectively, our results suggest that MSCA-1 seems to be the best marker through which to isolate MSC from bone marrow and that CD34 is the only marker able to positively isolate cells from adipose tissue. Thus, we show that the MSC from the different sources share similar properties although they have specific characteristics. The choice of the source and of the marker with which to isolate a particular subpopulation is important depending on their intended clinical use. / Les cellules stromales mésenchymateuses multipotentes (CSM) ont été mises en évidence dans la moelle osseuse et peuvent être isolées de « virtuellement tous les organes ». Elles participeraient à la maintenance et au renouvellement des tissus. Une fois isolées, elles sont capables d’adhérer à des surfaces en plastique en prenant une forme fibroblastique. Elles sont caractérisées par un phénotype particulier et peuvent se différencier en divers types cellulaires lorsque cultivées dans un milieu d’induction spécifique. Ces caractéristiques ont été définies sur les CSM en culture et ne reflètent pas forcément ce qui se passe in situ.Les CSM présentent des propriétés particulières. Elles peuvent sécréter des facteurs de croissance ainsi que de nombreuses cytokines qui leur permettent d’une part d’avoir une activité trophique et d’autre part de moduler le système immunitaire. Elles sont aussi capables de se différencier. Ces différentes propriétés les rendent particulièrement attractives pour la thérapie cellulaire.Les CSM font déjà l’objet de nombreuses études pré-cliniques et cliniques dont les résultats sont difficilement interprétables car nous n’avons à l’heure actuelle qu’une compréhension limitée de leur biologie de base. Les CSM sont encore mal définies in situ et sont hétérogènes. Cette hétérogénéité provient de leur différence d’origine et de leur préparation cellulaire :il n’existe aucune standardisation des protocoles d’isolation et de culture. Cette hétérogénéité entraine de nombreuses questions relatives à la sécurité du patient qui doivent être élucidées.La première partie de ce travail cherche à optimiser les méthodes d’extraction et de purification des CSM du tissu adipeux humain, la principale source de CSM autologues avec la moelle osseuse. Les méthodes classiques requièrent une étape de digestion enzymatique dont l’enzyme utilisée et le temps de digestion du tissu adipeux peuvent induire des altérations cellulaires et modifier leurs fonctions. De plus, l’adjonction de xénobiotiques augmente le risque de contamination et complique le suivi des bonnes pratiques de fabrication (BPF). Nous proposons une méthode qui s’affranchit de cette étape de digestion enzymatique tout en étant plus facile, plus sûre, plus rapide, moins chère et moins traumatisante pour les cellules. Elle permet d’obtenir un nombre tout aussi important de CSM du tissu adipeux que la méthode enzymatique classique en préservant leurs propriétés.La deuxième partie de ce travail vise à caractériser les sous populations de CSM du tissu adipeux humain en les comparant à celles de la moelle osseuse, source de référence historique. Cette étude a permis d’approfondir la connaissance des marqueurs de surface des CSM de ces 2 sources in situ, tout en évaluant les différentes propriétés des sous-populations isolées grâce aux marqueurs de surface CD271, SUSD2, MSCA-1, CD44 et CD34. Nous avons montré que les CSM de la moelle osseuse expriment les marqueurs MSCA-1, CD271 et SUSD2 in situ et qu’il existait une sous-population clairement positive pour le CD34 avec des propriétés différentes de celles de la population non sélectionnée ou négative pour ce marqueur. Il existe aussi 2 sous-populations positive et négative pour le CD44 avec des propriétés similaires.Contrairement aux CSM de la moelle osseuse, une seule sélection a permis d’isoler efficacement les CSM du tissu adipeux par une sélection positive sur base de l’expression du CD34. Nous avons pu aussi isoler une population CD271+ mais seulement des prélèvements de lipoaspirations et non des abdominoplasties.Au vu de nos résultats, MSCA-1 semble le meilleur marqueur pour isoler les CSM de la moelle osseuse tandis que le CD34 est le seul marqueur capable d’isoler positivement celles du tissu adipeux. Ainsi, nous montrons que les CSM issues de différentes sources partagent des propriétés similaires avec cependant des caractéristiques propres. Le choix de la source et du marqueur pour isoler une sous-population sont donc importants en fonction de leur utilité clinique envisagée. / Doctorat en Sciences biomédicales et pharmaceutiques (Médecine) / info:eu-repo/semantics/nonPublished

Biologie cellulaire

Immunologie

Sciences biomédicales en général

Autres sciences pharmaceutiques

MSC

ADSC

Adipose tissue

Bone marrow

CD34

sub-populations

CD44

MSCA-1

SUSD2

CD271

Collagenase

Cell therapy

ATMP

GMP