Potencial osteogênico in vitro e in vivo de células-tronco mesenquimais de polpa dental e tecido adiposo / In vitro and in vivo osteogenic potential of mesenchymal stem cells from adipose tissue and dental pulp

Felipe Augusto André Ishiy

27 June 2012

Células-tronco humanas derivadas da polpa dental (hDPSCs) e células-tronco humanas derivadas de tecido adiposo (AhSCs) são células multipotentes capazes de diferenciação osteogênica in vitro e in vivo, e promissoras fontes de células para a engenharia de tecido ósseo, dada a sua facilidade de expansão, isolamento e diferenciação. É de grande interesse compreender qual é o melhor tipo celular para diferenciação osteogênica, assim, o objetivo deste estudo foi comparar o potencial de diferenciação osteogênica in vitro e in vivo entre hDPSCs e hASCs. Foram isoladas e estabelecidas seis populações de células-tronco de hDPSCs (entre 7-12 anos) e seis da hASC (de indivíduos com idade entre 30-49 anos). Após a indução in vitro, a diferenciação osteogênica foi comprovado através das colorações de fosfatase alcalina (9 dias) e vermelho de alizarina (14 e 21 dias). A quantificação da mineralização da matriz após 21 dias de diferenciação osteogênica revelou 2,24 mais ossificação das hDPSCs em relação às hASCs. Para realizar o experimento in vivo, foram triados seis biomateriais para verificar qual melhor biomaterial para o nosso modelo, defeito crítico em calvária de Ratos Wistar não imunossuprimidos, com três amostras de hDPSCs. Após 45 dias, CellCeram(TM) exibiu a melhor neoformação óssea in vivo, e foi selecionado para comparar os potenciais osteogênicos in vivo entre hDPSCs e hASCs. Células (10e6) foram associadas a discos de 4,5 mm CellCeram(TM), grupo controle foi realizado através do transplante do biomaterial livre de células. Neoformação óssea foi mensurada 45 dias após a cirurgia através da coloração histológica de hematoxilina / eosina. A formação óssea total foi quantificada através da análise de imagens de todas as ilhas de ossificação. A associação entre hDPSCs e CellCeram(TM) promoveu 7,24 vezes mais neoformação óssea quando comparado com a associação entre esse mesmo material e hASCs (p <0,0001). A utilização de células-tronco adultas para regeneração óssea é uma ótima abordagem para uso terapêutico, e calcular ou predizer o potencial osteogênico das células utilizadas é extremamente importante e necessário para futura aplicação em novas estratégias de bioengenharia de tecido ósseo / Human dental pulp stem cells (hDPSCs) and human adipose-derived stem cells (AhSCs) are multipotent cells capable of undergoing osteogenesis in vitro and in vivo, and promising cell-source populations for bone tissue engineering given their easiness of isolation, expansion and differentiation. It is of great interest to understand which is the best cell type for osteogenic differentiation, thus the aim of this study is to compare the in vitro and the in vivo osteogenic differentiation potentials between DPSCs and ASCs. We isolated six stem cell populations from DPSCs (aged 7-12 years) and six from ASCs (from subjects aged 30-49 years) and cell culture was established. After in vitro induction the populations were able to undergo osteogenic differentiation, as evidenced by alkaline phosphatase (9 days) and alizarin red S (14 and 21 days) stainings. Quantification of matrix mineralization after 21 days of osteogenic differentiation revealed an enhancement of 2.24-fold increase between hDPSCs and hASCs differentiation. To perform the in vivo experiment, we promoted a screening of six scaffolds to find out which would be best scaffold to our model, a calvarial critical-sized defect in Wistar non-immunosuppressed rats, with three different culture samples of hDPSCs. After 45 days, CellCeram(TM) displayed the best in vivo bone neoformation, and was used to compare the in vivo osteogenic potentials between hDPSCs and hASCs. Cells (10e6) were associated to 4.5 mm CellCeram(TM) discs, and control groups were performed transplanting the biomaterial free of cells. Bone healing was measured through histological hematoxylin/eosin staining 45 days after surgery. Newly formed bone was also evaluated by total bone island surface quantification through image analysis. The association between hDPSCs and CellCeram(TM) induced a mean of 7.24 times more bone formation when compared to the association between this same material and hASCs (p<0.0001). The use of adult stem cells for bone regeneration is a robust therapeutic option, and calculate or predicts the osteogenic potential of the cell used are extremely important and necessary to future application, and translation to new strategies in bone tissue engineering

Engenharia de tecidos

Medicina regenerativa

Osteogenic potential of progenitor cells

Regenerative medicine

Tissue engineering

Molecular techniques for therapeutic and diagnostic applications in Mucopolysaccharidosis IIIB and Gaucher disease

Christensen, Chloe L.

22 December 2020

There is an unmet need to develop and test treatments for rare lysosomal disease (LD). Most LDs are present in childhood and do not currently have approved therapies. Rare diseases individually are uncommon but taken together account for a population prevalence of 3.5-5.9% worldwide. Due to their rarity, it often takes significant time and effort to diagnose rare diseases. New diagnostic tools, especially for early detection, will offer an advantage in avoiding this diagnostic odyssey. This dissertation is focused on investigating novel diagnostic and treatment methods in vitro for two neurodegenerative LDs: Gaucher disease (GD) and mucopolysaccharidosis IIIB (MPS IIIB). Mutations in NAGLU and GBA1, the genes that encode for lysosomal hydrolases required for degradation of heparan sulfate and glucocerebrosides, lead to the observed pathogenesis in MPS IIIB and GD, respectively. Since many LDs, including MPS IIIB and some forms of GD, are neurodegenerative, cell and gene-based therapeutic strategies are of significant interest. Therapeutics that offer some symptom mitigation in other LDs, such as enzyme replacement or substrate reduction therapies, do not offer appreciable disease mitigation in MPS IIIB or neurodegenerative GD. Here, a novel compound heterozygous mutation, NAGLUY140C/R297X, that results in approximately 50% residual NAGLU protein and 0.6% NAGLU enzyme activity is reported in NAGLU. Furthermore, a RFLP and site-directed mutagenesis strategy was developed to identify the presence of the relatively common p.R297X mutation in patient cell samples, in addition to two other novel molecular assays for the detection of the p.E153K mutation in NAGLU and p.N370S mutation in GBA1. MPS IIIB and GD human skin fibroblasts were reprogrammed to iPSCs using non-integrating Sendai viral vectors with a reprogramming efficiency of 0.2% and 0.3%, respectively. Resulting iPS cell lines were confirmed as being pluripotent through a barrage of analyses for markers of pluripotency and differentiation. Intriguingly, early passage MPS IIIB iPSCs were found to exhibit increased cell death and spontaneous differentiation to embryoid body-like structures, which was hypothesized to be caused by fibroblast growth factor 2 (FGF2) sequestration or degradation due to inherent heparan sulfate dysregulation. Supplemental FGF2 (100 ng/mL) was found to significantly increase confluency of MPS IIIB iPSCs after 48 hours (n = 5, p ≤ 0.05) and persisting to 96 hrs (n = 5, p ≤ 0.05), thus providing evidence for an important role of FGF2-heparan sulfate interactions in the maintenance of stem cell pluripotency. These findings highlight the importance of considering inherent disease pathology when developing disease models. Three genome editing strategies, CRISPR-Cas9, base and prime editing, are addressed throughout this dissertation. Genome editing outcomes in NAGLU and GBA1, as well as a control gene, HPRT1, are reported in HEK293 cells, human skin fibroblasts, and induced pluripotent stem cells (iPSCs). Although CRISPR-HDR failed to yield mutation correction, base editing of the common p.N370S (c.1226 A>G) in GD skin fibroblasts using with 42% efficiency is reported. Base editing of HPRT1 in HEK293 cells with an overall editing efficiency of 6 ± 0.5% (n = 3), but interestingly, when base editing at the centered nucleotide was analyzed, the editing efficiency increases to 27 ± 4.3% (n = 3). These findings align with other reports of a centered nucleotide preference for base editors and will help direct genome editing strategies in the future. This dissertation describes the first genome editing in NAGLU, and the first base editing in GBA1, and underscores the importance of optimizing genome editing strategies when targeting disease-causing mutations in patient-derived cells. The findings reported here will direct future genome editing strategies for developing cell and gene-based therapies for MPS IIIB and GD. / Graduate / 2021-12-15

iPSCs

Regenerative medicine

Lysosomal disease

MPS IIIB

Gaucher disease

CRISPR-Cas9

Engineering Novel Microbead Encapsulated Three-Dimensional Tumor and Stem Cell Models

January 2020

abstract: Cellular assays are the backbone of biological studies - be it for tissue modeling, drug discovery, therapeutics, or diagnostics. Two-dimensional (2D) cell culture has been deployed for several decades to garner physiologically relevant information and predict data before the cost-intensive animal testing. Although 2D techniques have been valuable for cellular assays, they have a colossal limitation - they do not adequately consider the natural three-dimensional (3D) microenvironment of the cells. As a result, they sometimes provide misleading statistics. Therefore, it is important to develop a 3D model that predicts cellular behaviors and their interaction with neighboring cells and extracellular matrix (ECM) in a more realistic manner. In recent biomedical research, various platforms have been modeled to generate 3D prototypes of tissues, spheroids, in vitro that could allow the study of cellular responses resembling in vivo environments, such as matrices, scaffolds, and devices. But most of these platforms have drawbacks such as lack of spheroid size control, low yield, or high cost associated with them. On the other hand, Amikagel is a low cost, high-fidelity platform that can facilitate the convenient generation of tumor and stem cell spheroids. Furthermore, Amikabeads are aminoglycoside-derived hydrogel microbeads derived from the same monomers as Amikagel. They are a versatile platform with several chemical groups that can be exploited for encapsulating the spheroids and investigating the delivery of bioactive compounds to the cells. This thesis is focused on engineering novel 3D tumor and stem cell models generated on Amikagel and encapsulated in Amikabeads for proximal delivery of bioactive compounds and applications in regenerative medicine. / Dissertation/Thesis / Z-stacks of confocal images of spheroids encapsulated in Amikabeads (compilations of sections) / Masters Thesis Bioengineering 2020

Biomedical engineering

bioactive delivery

drug delivery

regenerative medicine

spheroid culture

stem cell technology

tumor spheroid encapsulation

Emerging role of LRRK2 in human neural progenitor cell cycle progression, survival and differentiation

Milosevic, Javorina, Schwarz, Sigrid C., Ogunlade, Vera, Meyer, Anne K., Storch, Alexander, Schwarz, Johannes

30 November 2015

Despite a comprehensive mapping of the Parkinson's disease (PD)-related mRNA and protein leucine-rich repeat kinase 2 (LRRK2) in the mammalian brain, its physiological function in healthy individuals remains enigmatic. Based on its structural features and kinase properties, LRRK2 may interact with other proteins involved in signalling pathways. Here, we show a widespread LRRK2 mRNA and/or protein expression in expanded or differentiated human mesencephalic neural progenitor cells (hmNPCs) and in post-mortem substantia nigra PD patients. Using small interfering RNA duplexes targeting LRRK2 in hmNPCs following their differentiation into glia and neurons, we observed a reduced number of dopaminergic neurons due to apoptosis in LRRK2 knockdown samples. LRRK2-deficient hmNPCs exhibited elevated cell cycle- and cell death-related markers. In conclusion, a reduction of LRRK2 expression in hmNPCs severely impaired dopaminergic differentiation and/or survival of dopaminergic neurons most likely via preserving or reactivating the cell cycle.

info:eu-repo/classification/ddc/610

ddc:610

iPSC-derived platelets depleted of HLA class-I are inert to anti-HLA class-I and NK cell immunity / HLAクラスIを欠失させたiPS細胞由来血小板は、抗HLAクラスI抗体とNK細胞による免疫機構を回避する

Suzuki, Daisuke

25 May 2020

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第22648号 / 医科博第111号 / 新制||医科||7(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 生田 宏一, 教授 竹内 理, 教授 髙折 晃史 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Platelet

Megakaryocyte

iPSC

HLA class I

Natural killer cell

Regenerative medicine

491

Novel device prototyping for endoscopic cell sheet transplantation using a three-dimensional printed simulator / ３Ｄプリントシミュレータを用いた内視鏡的細胞シート移植デバイスの開発

Osada, Hiroaki

23 March 2021

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23084号 / 医博第4711号 / 新制||医||1049(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 木村 剛, 教授 森本 尚樹, 教授 山下 潤 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Cardiac regenerative medicine

Cell sheet

Cell therapy

Minimally-invasive surgery

Simulator study

490

Stem Cells Based Elastic Matrix Regeneration for Small Abdominal Aortic Aneurysms (AAAs) Repair

Dahal, Shataakshi

15 September 2020

No description available.

Biomedical Engineering

Mechanisms Guiding Neotissue Formation and Remodeling in Tissue Engineered Vascular Grafts

Blum, Kevin Matthew

01 October 2021

No description available.

Biomedical Engineering

Medicine

Polymers

tissue engineering

regenerative medicine

congenital heart disease

fontan

biomaterials

Přizpůsobení fázového složení a mikrostruktury vápenatých fosforečnanů aplikovaných v regenerativní medicíně / Tailoring of phase composition and microstructure of calcium phosphate scaffolds applied in regenerative medicine.

Pejchalová, Lucie

January 2020

Vápenaté fosforečnany jsou nejčastěji využívané keramické materiály v medicíně pro regeneraci kostní tkáně. Vápenaté fosforečnany jsou biokompatibilní, bioaktivní a mezi sebou se odlišují především rozpustností a související degradací v organismu, proto jsou nejčastěji využívány k regeneraci malých defektů nebo jako vrstvy na kovových implantátech. U již zmíněné rozpustnosti materiálu po implantaci, hraje důležitou roli poměr zastoupení jednotlivých vápenatých fosforečnanů, od kterého se pak odvíjí rychlost degradace materiálu v organismu. Tato práce se zabývá vlivem tvarovacích metod na mikrostrukturu a zejména fázové složení vápenatých fosforečnanů. Výchozím materiálem pro pozorování změn ve fázovém složení byl komerční hydroxyapatit, který byl upraven kalcinací při 800 °C po dobu jedné hodiny. Při kalcinaci došlo k vytvoření dvoufázové směsi, obsahující hydroxyapatit a -fosforečnan vápenatý. Tato dvoufázová směs byla poté využita pro přípravu suspenze s plněním 15 obj.%, a také k přímé přípravě polotovarů s různou výslednou mikrostrukturou a fázovým složením. S cílem zjistit vliv procesu byly v této práci porovnány vzorky připravené pomocí metod: freeze-casting, izostatické lisování za studena, uniaxiální lisování a suspenzní odlévání. U polotovarů a slinutých vzorků byla provedena charakterizace mikrostruktury a analýza fázového složení. V práci se potvrdil vliv tvarovací metody na oba stanovené parametry – mikrostrukturu a fázové složení. Nově pak bylo zjištěno, že se zvyšující se hodnotou porozity a velikostí pórů se zvyšuje i zastoupení hydroxyapatitu ve vzorcích. Tento trend byl pozorován u vzorků vykazujících unimodální i bimodální zastoupení velikosti pórů.

A comparative analysis of the regulatory framework of the therapeutic application of stem cell technologies

Laurens, Johannes Bernardus

January 2017

Stem cell technologies as a branch of regenerative medicine are becoming increasingly popular as the science behind it evolves. Therefore, it is important that the regulatory framework pertaining to stem cell technologies be well defined and appropriate to prevent unethical and unscrupulous behaviour on the part of medical practitioners, which gives rise to stem cell tourism. South African legislation pertaining to stem cell technology is regarded as inadequate and dissonant with the Constitution, exacerbating the problem of stem cell tourism and denying patients access to certain stem cell therapies, which ultimately can be viewed as an infringement of their constitutional rights. The United Kingdom (UK) provides a clear-cut regulatory framework, which is not only centred around consent and patient safety but is also conducive to production of stem cell therapies. For such reasons, this dissertation finds the UK framework to be an appropriate benchmark against which the South African regulatory framework can be evaluated. By means of comparison and elaborating on the biology of stem cells in addition to pertinent ethical principles, legislation and human rights of both South Africa and the UK, an argument will be made out that South African legislation pertaining to stem cell therapy and related matters is wanting. Furthermore, analysis will be made of the definition of biological medicine as put forward by the Medicines and Related Substances Control Act 101 of 1965 to conclude that certain stem cell therapies are best excluded from such a definition as such stringent requirements and protocols encumbers access to stem cell therapies and inflates costs. Lastly, remedial measures are proposed to remedy these injustices by proposing for the institution of a specialist adivisary committee to oversee stem cell and related activities. Key Words: Regenerative Medicine; Stem Cells; Stem Cell Regulation; National Health Act; Medicines and Related Substances Control Act; Advanced Therapy Medicinal Product; Human Tissue Authority; Human Fertilisation and Embryology Authority; HTA; HFEA; Medicine and Healthcare Products Regulatory Agency; MHRA; European Medicines Agency; Tissue-engineered Products; Doctor-Patient Relationship; Medical Innovation Bill 2014; Experimental Treatments; Innovative Therapy; Hospital Exemption; Informed Consent; Special Exemption; Autologous Stem Cell Therapy; Stem Cell Transplants; Gene Therapy Advisory Committee. / Dissertation (LLM)--University of Pretoria, 2017. / Public Law / LLM / Unrestricted

UCTD

Regenerative Medicine

Stem Cell Regulation

National Health Act

Human Tissue Authority