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Current in vivo models for investigating human primary bone tumors and cancer metastasis to the bone rely on the injection of human cancer cells into the mouse skeleton. This approach does not mimic species-specific mechanisms occurring in human diseases and may preclude successful clinical translation. We have developed a protocol to engineer humanized bone within immunodeficient hosts, which can be adapted to study the interactions between human cancer cells and a humanized bone microenvironment in vivo. A researcher trained in the principles of tissue engineering will be able to execute the protocol and yield study results within 4-6 months. Additive biomanufactured scaffolds seeded and cultured with human bone-forming cells are implanted ectopically in combination with osteogenic factors into mice to generate a physiological bone 'organ', which is partially humanized. The model comprises human bone cells and secreted extracellular matrix (ECM); however, other components of the engineered tissue, such as the vasculature, are of murine origin. The model can be further humanized through the engraftment of human hematopoietic stem cells (HSCs) that can lead to human hematopoiesis within the murine host. The humanized organ bone model has been well characterized and validated and allows dissection of some of the mechanisms of the bone metastatic processes in prostate and breast cancer.

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Concise Review: Humanized Models of Tumor Immunology in the 21st Century: Convergence of Cancer Research and Tissue Engineering

Holzapfel

Wagner

Thibaudeau

et al. 2015

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Despite positive testing in animal studies, more than 80% of novel drug candidates fail to proof their efficacy when tested in humans. This is primarily due to the use of preclinical models that are not able to recapitulate the physiological or pathological processes in humans. Hence, one of the key challenges in the field of translational medicine is to "make the model organism mouse more human.'' To get answers to questions that would be prognostic of outcomes in human medicine, the mouse's genome can be altered in order to create a more permissive host that allows the engraftment of human cell systems. It has been shown in the past that these strategies can improve our understanding of tumor immunology. However, the translational benefits of these platforms have still to be proven. In the 21st century, several research groups and consortia around the world take up the challenge to improve our understanding of how to humanize the animal's genetic code, its cells and, based on tissue engineering principles, its extracellular microenvironment, its tissues, or entire organs with the ultimate goal to foster the translation of new therapeutic strategies from bench to bedside. This article provides an overview of the state of the art of humanized models of tumor immunology and highlights future developments in the field such as the application of tissue engineering and regenerative medicine strategies to further enhance humanized murine model systems. STEM CELLS 2015;:1696-1704

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Periosteum tissue engineering in an orthotopic in vivo platform

et al. 2017

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Mycophenolate Mofetil Inhibits Tumor Growth and Angiogenesis In Vitro but Has Variable Antitumor Effects In Vivo, Possibly Related to Bioavailability

Koehl

Wagner²,

Stoeltzing³

et al. 2007

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Immune system augmentation via humanization using stem/progenitor cells and bioengineering in a breast cancer model study

Shafiee

McGovern

Lahr

et al. 2018

Intl Journal of Cancer

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Despite significant advances, most current in vivo models fail to fully recapitulate the biological processes that occur in humans. Here we aimed to develop an advanced humanized model with features of an organ bone by providing different bone tissue cellular compartments including preosteoblasts, mesenchymal stem/stromal (MSCs), endothelial and hematopoietic cells in an engineered microenvironment. The bone compartment was generated by culturing the human MSCs, umbilical vein endothelial cells with gelatin methacryloyl hydrogels in the center of a melt-electrospun polycaprolactone tubular scaffolds, which were seeded with human preosteoblasts. The tissue engineered bone (TEB) was subcutaneously implanted into the NSG mice and formed a morphologically and functionally organ bone. Mice were further humanized through the tail vein injection of human cord blood derived CD34+ cells, which then populated in the mouse bone marrow, spleen and humanized TEB (hTEB). 11 weeks after CD34+ transplantation, metastatic breast cancer cells (MDA-MB-231BO) were orthotopically injected. Cancer cell injection resulted in the formation of a primary tumor and metastasis to the hTEB and mouse organs. Less frequent metastasis and lower tumor burden were observed in hematochimeric mice, suggesting an immune-mediated response against the breast cancer cells. Overall, our results demonstrate the efficacy of tissue engineering approaches to study species-specific cancer-bone interactions. Further studies using genetically modified hematopoietic stem cells and bioengineered microenvironments will enable us to address the specific roles of signaling molecules regulating hematopoietic niches and cancer metastasis in vivo.

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Rapamycin blocks hepatoblastoma growth in vitro and in vivo implicating new treatment options in high-risk patients

Wagner¹,

B²,

Lederer³

et al. 2012

European Journal of Cancer

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Presence of rotational errors in long leg radiographs after total knee arthroplasty and impact on measured lower limb and component alignment

Maderbacher

Baier

Benditz

et al. 2017

International Orthopaedics (SICOT)

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Ferdinand Wagner

Species-specific homing mechanisms of human prostate cancer metastasis in tissue engineered bone

Engineering a humanized bone organ model in mice to study bone metastases

Concise Review: Humanized Models of Tumor Immunology in the 21st Century: Convergence of Cancer Research and Tissue Engineering

Periosteum tissue engineering in an orthotopic in vivo platform

Mycophenolate Mofetil Inhibits Tumor Growth and Angiogenesis In Vitro but Has Variable Antitumor Effects In Vivo, Possibly Related to Bioavailability

Immune system augmentation via humanization using stem/progenitor cells and bioengineering in a breast cancer model study

Rapamycin blocks hepatoblastoma growth in vitro and in vivo implicating new treatment options in high-risk patients

Presence of rotational errors in long leg radiographs after total knee arthroplasty and impact on measured lower limb and component alignment

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