A novel orthotopic bladder tumor model with predictable localization of a solitary tumor (original) (raw)
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An Orthotopic Model of Murine Bladder Cancer
Journal of Visualized Experiments, 2011
In this straightforward procedure, bladder tumors are established in female C57 mice through the use of catheterization, local cauterization, and subsequent cell adhesion. After their bladders are transurethrally catheterized and drained, animals are again catheterized to permit insertion of a platinum wire into bladders without damaging the urethra or bladder. The catheters are made of Teflon to serve as an insulator for the wire, which will conduct electrical current into the bladder to create a burn injury. An electrocautery unit is used to deliver 2.5W to the exposed end of the wire, burning away extracellular layers and providing attachment sites for carcinoma cells that are delivered in suspension to the bladder through a subsequent catheterization. Cells remain in the bladder for 90 minutes, after which the catheters are removed and the bladders allowed to drain naturally. The development of tumor is monitored via ultrasound. Specific attention is paid to the catheterization technique in the accompanying video.
Histopathological characterization of a syngeneic orthotopic murine bladder cancer model
International Braz J Urol, 2008
Purpose: We developed and characterized by histopathology and immunohistochemistry a syngeneic murine bladder tumor model derived from the MB49 tumor cell line. Materials and Methods: Bladder tumor implantation was achieved by intravesical instillation of 5 x 10 5 MB49 tumor cells in C57BL/6 mice. A chemical lesion of the bladder was performed in order to promote intravesical tumor implantation. The bladder wall lesion was accomplished by transurethral instillation of silver nitrate (AgNO 3 ). After 15 days, the animals were Results: Twenty-nine out of 30 animals (96.7%) developed intravesical tumors in a 15-day period. Macroscopically, the mean bladder weight was 0.196g (0.069-0.538g), 10 to 15 times the normal bladder weight. The immunohistochemical Conclusions: cauterization is widely described in the literature for syngeneic orthotopic animal models, the technique described in this study represents an alternative for intravesical bladder tumor implantation. Moreover, the histopathology and immunohistochemical analysis of the murine bladder tumor model derived from the MB49 cell line showed a resemblance to human Key words: bladder cancer; intravesical instillation; tumor cell line; mice/c57bl; experimental neoplasm Int Braz J Urol. 2008; 34: 220-9
Development of a murine intravesical orthotopic human bladder cancer (mio-hBC) model
American journal of clinical and experimental urology, 2018
We have developed a murine intravesical orthotopic human bladder cancer (mio-hBC) model for the establishment of superficial urothelial cell carcinomas. In this model we catheterize female atyhmic nude mice and pre-treat the bladder with poly-L-lysine for 15 minutes, followed by intravesical instillation of luciferase-transfected human UM-UC-3 cells. Cancer cells are quantified by bioluminescent imaging which has been validated by small animal ultrasound. Poly-L-lysine pre-treatment increased engraftment rate (84.4%) and resulted in faster growing tumors than trypsin pre-treatment. In addition, tumors respond through a decrease in growth and increase in apoptosis to chemotherapy with mitomycin C. Previous intravesical models utilized KU7 cells which have been later determined to be of non-bladder origin. They display markers consistent with HeLa cells, requiring a need for a true intravesical bladder model. Efficient engraftment and rapid superficial growth patterning of the human b...
A new method of implanting orthotopic rat bladder tumor for experimental therapies
International journal of cancer. Journal international du cancer, 2002
We developed a model of orthotopic transplantation of bladder tumor cells in female Fischer rats using a new reproducible technique. After first performing the mechanical abrasion of a portion of the bladder urothelium with an Abrader inserted transurethrally via a catheter, we administered a suspension of 5-40 x 10(6) viable AY-27 tumor cells in sterile phosphate-buffered saline to the bladder cavity. This rapidly led to a tumor growth incidence of approximately 100%. The induced bladder tumors grew expansively into the bladder cavity from the surface (mucosa) and gradually invaded the submucosa, muscles, serosa and surrounding tissue (high-stage invasive transitional cell carcinoma). Size and staging were related to the quantity of tumor cells instilled into the bladder cavity. This model matches the characteristics of human bladder tumor more closely than other bladder cancer models induced with tumor cells. Moreover, it presents many advantages: the method is reproducible, tumor...
International Journal of Molecular Sciences, 2021
Non-muscle-invasive bladder cancer is the most common form of bladder cancer. The main problem in managing bladder tumors is the high recurrence after the transurethral resection of bladder tumors (TURBT). Our study aimed to examine the fate of intravesically applied cancer cells as the implantation of cancer cells after TURBT is thought to be a cause of tumor recurrence. We established an orthotopic mouse bladder tumor model with MB49-GFP cancer cells and traced them during the first three days to define their location and contacts with normal urothelial cells. Data were obtained by Western blot, immunolabeling, and light and electron microscopy. We showed that within the first two hours, applied cancer cells adhered to the traumatized epithelium by cell projections containing α3β1 integrin on their tips. Cancer cells then migrated through the epithelium and on day 3, they reached the basal lamina or even penetrated it. In established bladder tumors, E-cadherin and desmoplakin 1/2 ...
Animal Models for Basic and Preclinical Research in Bladder Cancer
Bladder Cancer - From Basic Science to Robotic Surgery, 2012
Bladder cancer is one of the most common cancers in the world. In 2006, there were about 61,240 diagnosed cases of bladder cancer and approximately 13,060 deaths attributable to this disease, being the prevalence estimated worldwide more than 1,000,000 patients (Jemal et al., 2006; Lerner, 2005). Taking into account that its incidence seems to be increasing, bladder cancer is clearly a significant public health issue around the world. Thus, it is necessary to intensify research on this topic. Urinary bladder cancer originates mainly from epithelial cells of the urothelium (Lopez-Beltran et al., 2004; Montironi et al., 2005). When initially diagnosed, most bladder cancers (about 70%) do not present muscle invasion, and are thus known as non-muscle invasive bladder cancer (pTa and pT1). In these cases, a simple transurethral resection is sufficient to remove the tumor. However, some patients experience recurrence or even tumor progression. The progression of the tumor involves invasion of tumor cells, which penetrate deeper layers of the bladder such as the detrusor muscle (pT2), perivesical tissue (pT3) and extravesical organs (pT4) (Figure 1). Since this progression threatens the patient's life, more aggressive therapies are necessary (Sobin et al., 1997). Intensive research in bladder cancer, as well as that in most tumors, is being carried out to elucidate the reason for the appearance of tumors, and to find out which factors are involved in their development and which are related to the tumor progression process. These investigations, which provide insights into the biology of the tumor, are essential for the implementation of new therapeutic and/or preventive modalities (Bhattacharya et al., 2010; Zhang et al., 2011). Research on basic science is focused on the mechanisms that lead cells towards transformation and development of cancer, using simple experimental models where it is easier to interpret the results. Cell culture techniques are widely used to study different oncological processes. The cell culture is the growth of any cell type, usually tumor cells, in with nutrient-containing solutions. The cells grow attached to the plastic surface, forming a monolayer, usually in a two-dimensional way. This technique allows studying processes such as mutagenesis, invasion, migration, and production of proteolytic enzymes. Although cell culture is a very important tool, it has certain limitations. Many biological processes depend on the three-dimensional architecture. In addition, monolayer culture is usually
Optimizing Orthotopic Bladder Tumor Implantation in a Syngeneic Mouse Model
The Journal of Urology, 2009
We established a reliable technique for orthotopically implanting bladder tumor cells in a syngeneic mouse model. Materials and Methods: MBT-2 murine bladder cancer cells were transurethrally implanted in the bladder of syngeneic C3H/He mice (Jackson Laboratory, Bar Harbor, Maine). Different chemical pretreatments were used before tumor implantation, including phosphate buffered saline (control), HCl, trypsin and poly-L-lysine. MBT-2 cells (1 ϫ 10 6 or 2 ϫ 10 6) were instilled into the intravesical space after chemical pretreatment. Tumor take and bladder tumor volume were determined by micro ultrasound. Bladders were harvested at the end of the study to measure bladder weight and for histopathological examination. Results: Bladder pretreatment with HCl in 5 preparations was discontinued due to significant adverse reactions, resulting in death in 1 mouse, and severe bladder inflammation and hematuria 3 days after pretreatment in 2. Pretreatment with phosphate buffered saline, trypsin and poly-L-lysine in 6 animals each was tolerated well without significant adverse reactions or mortality. The tumor take rate in the control, trypsin and poly-L-lysine pretreatment groups was 33%, 83% and 83%, respectively. The take rate was higher in mice instilled with 2 ϫ 10 6 cells than in those with 1 ϫ 10 6 cells (93% vs 73%, p Ͻ0.05). Conclusions: We report a reliable, feasible method of orthotopically implanting bladder tumor cells into a syngeneic mouse model. Poly-L-lysine and trypsin are useful adjunctive pretreatment agents to improve bladder tumor uptake. This model may be suitable to evaluate treatment paradigms for bladder cancer.
BMC cancer, 2017
Novel theranostic options for high-risk non-muscle invasive bladder cancer are urgently needed. This requires a thorough evaluation of experimental approaches in animal models best possibly reflecting human disease before entering clinical studies. Although several bladder cancer xenograft models were used in the literature, the establishment of an orthotopic bladder cancer model in mice remains challenging. Luciferase-transduced UM-UC-3LUCK1 bladder cancer cells were instilled transurethrally via 24G permanent venous catheters into athymic NMRI and BALB/c nude mice as well as into SCID-beige mice. Besides the mouse strain, the pretreatment of the bladder wall (trypsin or poly-L-lysine), tumor cell count (0.5 × 106-5.0 × 106) and tumor cell dwell time in the murine bladder (30 min - 2 h) were varied. Tumors were morphologically and functionally visualized using bioluminescence imaging (BLI), magnetic resonance imaging (MRI), and positron emission tomography (PET). Immunodeficiency o...
A new in vivo model to study invasion and metastasis of human bladder carcinoma
Cancer research, 1987
An animal model to investigate the invasive and metastatic properties of human bladder transitional cell carcinoma (HTCC) was established. Two long-term HTCC cell lines (RT4 and EJ) and one HTCC cell line derived in our laboratory (LD-71) were tumorigenic when injected s.c. into nude mice but had little potential to invade locally or metastasize before the animals succumbed to tumor burden. Experimental lung metastases were, however, observed in approximately 60% of animals given injections of RT4 or EJ cell lines in the tail vein. The cells were also implanted transurethrally into the urinary bladders of athymic mice. RT4 cells, which were originally isolated from a superficial papillary tumor, produced histologically noninvasive tumors after transurethral inoculation with no evidence of metastasis. In contrast EJ cells, which were originally isolated from a more aggressive tumor, produced invasive tumors in nude mouse bladders and metastasized to the lungs spontaneously. The invas...