A "المريض مثل" مثلي مسانج نموذج الفأر من سرطان الكبد الانبثاث
Summary
انتشار النقيلي من السرطان هو السبب الرئيسي للوفيات المرتبطة بالسرطان. ونحن نقدم وصفا متعمقة لمنهجية عملية جراحية بقائنا لإنشاء نظام نموذجي الماوس مسانج مثلي "المريض مثل" لدراسة آليات الانبثاث في أورام الجهاز الصلبة.
Abstract
The majority of cancer-related deaths are caused by the metastasis of the cancer rather than the primary tumor itself. Yet, the underlying mechanisms of cancer metastasis are still unclear. Animal models are essential for elucidating the mechanisms and for evaluating novel strategies for the treatment of metastatic cancers. Here, an in-depth description of a “patient-like” orthotopic syngeneic mouse model for exploring the mechanisms of metastasis of solid organ tumors is provided. The survival surgical implantation of BNL 1ME A.7R.1 mouse hepatocellular carcinoma cells directly into the liver (the organ of origin) of the inbred wild-type immune competent laboratory mouse strain, BALB/c is described. The success and reproducibility of this methodology recommends it for widespread use in elucidating the biological mechanisms of solid organ cancer metastasis.
Introduction
Hepatocellular carcinoma (HCC) is one of the most lethal cancers, with poor prognosis and low life expectancy. Nearly all cancer-related deaths are due to the metastatic spread of the disease from the originating organ to additional distant organs2-6.HCC progression is a complex process. Therefore, being able to model the tumor microenvironment that is naturally found in metastatic HCC in animal models can prove to be a successful and useful way to reveal relevant mechanisms in humans.7Unfortunately, the mechanisms of cancer metastasis are still largely unclear. Therefore, there is a need to establish animal models that will enable us to elucidate the underlying molecular mechanisms of metastases of cancers such as HCC3,5.
Mouse model systems are a very useful approach for delineating mechanisms and evaluating novel strategies for treatment of metastatic human cancers5,8. The various mouse model systems that presently exist are a testament to efforts of researchers to correctly depict the complexity of the disease5,8,9.
Ogunwobi and colleagues recently used a survival surgical approach to demonstrate establishment of a novel orthotopic syngeneic mouse model for the study of metastasis in HCC3. Their work established a “patient-like” mouse model that recapitulates features of aggressive and metastatic HCCs3. They further demonstrated that this mouse model system can be used to study the biology of circulating tumor cells, and that this holds potential for gaining novel insights into the mechanisms of cancer metastasis3.
The aim of this paper is to describe in detail the methodology used in establishing this “patient-like” orthotopic syngeneic mouse model of HCC metastasis3. The methodology of how to implant BNL 1ME A.7R.1 mouse HCC cells directly into the liver (the organ of origin) of the inbred wild-type immune competent laboratory mouse strain, BALB/c3 using survival surgery will be described. Unlike other mouse xenograft tumor models where human tumor cells are implanted into immune deficient mice, this system is syngeneic and is, therefore, suitable for studying the role of the immune system in tumor metastasis3,5,8. This approach will likely gain widespread use for studying the mechanisms of metastasis in solid organ cancers.
Protocol
Representative Results
Discussion
في هذه المقالة يتم إعطاء وصف متعمقة للطريقة التي تم الإبلاغ عنها مؤخرا من قبل Ogunwobi وزملاؤه من إنشاء الناجح لنموذج الفأر مسانج مثلي من سرطان الكبد ورم خبيث (الشكل 2) 3. معدل تأخذ من أورام لهذا الإجراء مرتفع عموما. وقد لاحظنا سابقا بمعدل اتخاذ الورم من 100٪ <s…
Divulgazioni
The authors have nothing to disclose.
Acknowledgements
We would like to thank Pascal DuBois for proof-reading the article. The authors would also like to thank the personnel of the Animal Facility at Hunter College of The City University of New York. This work was supported by a NIH RCMI grant to Hunter College.
Materials
| Micro Dissecting Tweezer | Roboz | (RS-5040) | Tip .20 x .12mm |
| Graefe Micro Dissecting Forceps, serrated curved tip | Roboz | (RS-5111) | 1 X 2 teeth, curved tip width 0.6mm |
| Micro Dissecting Retractor-Agricola (3 by 3 prongs) | Roboz | (RS-6501) | Blunt 3 X 3 prongs, depth 4mm, spread 25mm |
| Micro Dissecting Retractor-Goldstein (3 by 3 prongs) | Roboz | (RS-6503) | Blunt, 3 X 3 prongs, depth 4mm, spread 19mm |
| Jameson Caliper (Measures tumors) | Roboz | (RS-6466) | 80mm/3 inch scale, chrome plated |
| Micro Dissecting Scissors, large ring sissors, straight and sharp | Roboz | (RS-5852) | 23mm blades, length 4 inches, flat shanks and large rings |
| Scalpel with blades, for delicate dissecting procedures | Roboz | (RS-9861-36) | |
| Scalpel handle | Roboz | (RS-9884) | Solid |
| Littauer Stitch Sissors | Roboz | (RS-7074) | Length 4.5 inches |
| Brown needle holder, for easy suture tying | Roboz | (RS-7960) | Convex jaw, fine serrations |
| Reflex 7MM wound clips with reflex 7 clip applier | Roboz | (RS-9262) | safe, secure alternative method of wound closure |
| Instrument tray and lid | Roboz | RT-1350S | |
| Mini-clipper with detachable blade | Roboz | (RS-5903) | |
| Germinator 500 (the Germ Terminator) Dry Sterilizer | Roboz | Ds-400, Ds-401, DS-501 | For fast decontamination of micro-dissecting instruments. Instruments decontaminate within 15 seconds. |
| Microinjection needles | VWR | BD305125 | 25G Needle |
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