请输入关键字
请输入关键字
订购
*国家
中国
美国
中国香港
中国澳门
中国台湾
阿尔巴尼亚
阿尔及利亚
阿根廷
阿拉伯联合酋长国
阿鲁巴
阿曼
阿塞拜疆
阿森松岛
埃及
埃塞俄比亚
爱尔兰
爱沙尼亚
安道尔
安哥拉
安圭拉
安提瓜和巴布达
奥地利
奥兰群岛
澳大利亚
巴巴多斯
巴布亚新几内亚
巴哈马
巴基斯坦
巴拉圭
巴勒斯坦领土
巴林
巴拿马
巴西
白俄罗斯
百慕大
保加利亚
北马里亚纳群岛
贝宁
比利时
冰岛
波多黎各
波兰
波斯尼亚和黑塞哥维那
玻利维亚
伯利兹
博茨瓦纳
不丹
布基纳法索
布隆迪
朝鲜
赤道几内亚
丹麦
德国
迪戈加西亚岛
东帝汶
多哥
多米尼加共和国
多米尼克
俄罗斯
厄瓜多尔
厄立特里亚
法国
法罗群岛
法属波利尼西亚
法属圭亚那
法属南部领地
梵蒂冈
菲律宾
斐济
芬兰
佛得角
福克兰群岛
冈比亚
刚果(布)
刚果(金)
哥伦比亚
哥斯达黎加
格恩西岛
格林纳达
格陵兰
格鲁吉亚
古巴
瓜德罗普
关岛
圭亚那
哈萨克斯坦
海地
韩国
荷兰
荷属加勒比区
荷属圣马丁
黑山
洪都拉斯
基里巴斯
吉布提
吉尔吉斯斯坦
几内亚
几内亚比绍
加拿大
加纳
加纳利群岛
加蓬
柬埔寨
捷克
津巴布韦
喀麦隆
卡塔尔
开曼群岛
科科斯(基林)群岛
科摩罗
科索沃
科特迪瓦
科威特
克罗地亚
肯尼亚
库克群岛
库拉索
拉脱维亚
莱索托
老挝
黎巴嫩
立陶宛
利比里亚
利比亚
联合国
列支敦士登
留尼汪
卢森堡
卢旺达
罗马尼亚
马达加斯加
马恩岛
马尔代夫
马耳他
马拉维
马来西亚
马里
马其顿
马绍尔群岛
马提尼克
马约特
毛里求斯
毛里塔尼亚
美国本土外小岛屿
美属萨摩亚
美属维尔京群岛
蒙古
蒙特塞拉特
孟加拉国
秘鲁
密克罗尼西亚
缅甸
摩尔多瓦
摩洛哥
摩纳哥
莫桑比克
墨西哥
纳米比亚
南非
南极洲
南乔治亚和南桑威奇群岛
南苏丹
瑙鲁
尼加拉瓜
尼泊尔
尼日尔
尼日利亚
纽埃
挪威
诺福克岛
帕劳
皮特凯恩群岛
葡萄牙
日本
瑞典
瑞士
萨尔瓦多
萨摩亚
塞尔维亚
塞拉利昂
塞内加尔
塞浦路斯
塞舌尔
沙特阿拉伯
圣巴泰勒米
圣诞岛
圣多美和普林西比
圣赫勒拿
圣基茨和尼维斯
圣卢西亚
圣马丁岛
圣马力诺
圣皮埃尔和密克隆群岛
圣文森特和格林纳丁斯
斯里兰卡
斯洛伐克
斯洛文尼亚
斯瓦尔巴和扬马延
斯威士兰
苏丹
苏里南
所罗门群岛
索马里
塔吉克斯坦
泰国
坦桑尼亚
汤加
特克斯和凯科斯群岛
特里斯坦-达库尼亚群岛
特立尼达和多巴哥
突尼斯
图瓦卢
土耳其
土库曼斯坦
托克劳
瓦利斯和富图纳
瓦努阿图
危地马拉
委内瑞拉
文莱
乌干达
乌克兰
乌拉圭
乌兹别克斯坦
希腊
西班牙
西撒哈拉
新加坡
新喀里多尼亚
新西兰
匈牙利
休达及梅利利亚
叙利亚
牙买加
亚美尼亚
也门
伊拉克
伊朗
以色列
意大利
印度
印度尼西亚
英国
英属维尔京群岛
英属印度洋领地
约旦
越南
赞比亚
泽西岛
乍得
直布罗陀
智利
中非共和国
*省份
*城市
*姓名
*电话
*单位
*职位
*邮箱
*请输入验证码
*验证码
B-NDG mice-PDX
Strain Name 

NOD.CB17-PrkdcscidIl2rgtm1/Bcgen

Common Name 

B-NDG  mice

Background

NOD-scid

Catalog number  110586
Aliases  Male: Prkdc (-/-), Il2rg (X-/Y); Female: Prkdc (-/-), Il2rg (X-/X-)
NCBI Gene ID
16186

PDX tumor models and efficacy evaluation
 in B-NDG mice

PDX models are successfully established in B-NDG mice 


from clipboard

from clipboard

from clipboard

PDX (Patient-derived xenograft) models were successfully established in B-NDG mice. (A) General construction flow of the PDX model; (B) General information of tumor to be collected and the validation methods for the PDX model. (C) 248 PDX models derived from 9 types of tumors have been successfully established with B-NDG mice in Biocytogen by now.


General information of a pancreatic cancer PDX model—BP0062 

from clipboard

Growth curve and STR identification for different generation of PDX tumor


from clipboard

from clipboard

Pancreatic cancer BP0062 can successfully establish PDX model. Primary tumor sample was obtained from patient undergoing surgery for pancreatic ductal adenocarcinoma. Tumor pieces were subcutaneously inoculated into B-NDG mice. (A) Growth curve of passage 4, 5, 6 of the PDX tumor; (B) STR identification results of passage 1 and passage 5. Results showed that PDX model was successfully established in B-NDG mice implanted with pancreatic cancer BP0062. The STR of 5th generation of tumor cells is 100% matched to that of 1st generation, indicating that there was no change in the genetic background of the 5th generation of tumor tissue. Values are expressed as mean ± SEM. 


Histopathological analysis of different generation of PDX tumor tissue 

from clipboard

Histopathological analysis of BP0062 PDX tumor in B-NDG mice. Tumor tissue was collected from PDX model established with Pancreatic cancer BP0062 and analyzed with H&E staining. Results showed that patient-derived xenografts were found to well recapitulate the structures in original patient sample and maintain similar heterogeneity in different generations. 


Expression analysis of CLDN18.2 and EGFR in PDX tumor by IHC staining

from clipboard

Immunohistochemical analysis of CLDN18.2 and EGFR in different generation of BP0062 PDX tumor tissue. Human CLDN18.2 and EGFR were respectively detected with anti-human CLDN18.2 antibody or anti-human EGFR antibody. The results showed that the number and distribution of CLDN18.2+ cells or EGFR+ cells in different generation of PDX tumor were obviously different (brown), indicating that the heterogeneity was maintained in different generation of PDX models.


In vivo efficacy verification of small molecule drugs for EGFR target with PDX model BP0062 in B-NDG mice

from clipboard

Antitumor activity of EGFR targeted drugs in PDX model BP0062 of pancreatic cancer established with B-NDG mice. (A) Molecular targeted small-molecule anti-cancer drugs slightly inhibited tumor growth of BP0062 in B-NDG mice. PDX tumor pieces of BP0062 were subcutaneously implanted into B-NDG mice (female, 6 week-old, n=6). Mice were grouped when tumor volume reached approximately 100 mm3, at which time they were treated with different targeted drugs and schedules indicated in panel (B) Body weight changes during treatment. As shown in panel A, Molecular targeted small-molecule anti-cancer drugs were efficacious, demonstrating that PDX model of BP0062 can be used to establish tumor model and provide a powerful preclinical pancreatic tumor model with EGFR positive cells. Values are expressed as mean ± SEM.


In vivo efficacy verification of ADC drugs with NSCLC PDX model BP0638 in B-NDG mice

from clipboard

from clipboard

Antitumor activity of HER2-targeting and TROP2-targeting ADC drugs in NSCLC PDX model. (A) Expression analysis of HER2 and TROP2 in NSCLC (Non small Cell Lung Cancer) PDX (BP0638) tumor tissue by immunohistochemistry. The results showed both HER2 and TROP were low expression in this PDX model. (B) Efficacy verification of ADC drugs. PDX tumor pieces of BP0638 were subcutaneously implanted into B-NDG mice (n=5). Mice were grouped when tumor volume reached approximately 250-300 mm3, at which time they were treated with (HER2/TROP2-BsADC), two parental mono ADCs of the BsADC and other three commercial-derived ADC drugs (sacituzumab govitecan, disitamab vedotin, trastuzumab deruxtecan). The results showed that HER2/TROP2-BsADC had a stronger and longer inhibitory effect on tumor growth than ADCs. This inhibition was dose-dependent. Therefore, NSCLC PDX model of BP0638 provides a powerful preclinical NSCLC model for efficacy evaluation of various types of ADC drugs. Values are expressed as mean ± SEM.


In vivo efficacy verification of chemotherapy drugs with AML PDX model BP2010 in B-NDG mice

from clipboard

Antitumor activity of small molecule drugs in AML PDX model BP2010 established with B-NDG mice. According to the proportion of hCD45 in peripheral blood, PDX model mice were divided into 2 groups. One group of mice had a proportion of hCD45 in blood greater than 10% and the proportion of hCD45 in the blood of the other group of mice was between 1% and 10%. Each group was then divided into two sub-groups: the vehicle group and the treatment group. Mice in the treatment group were injected intravenously with daunorubicin and subcutaneously with cytarabine. The results showed that the efficacy of the group with low proportion of hCD45 (1%-10%) was better than that of the group with high proportion of hCD45 (>10%). Therefore, AML PDX model of BP2010 provides a powerful preclinical AML model for efficacy evaluation of chemotherapy drugs. Values are expressed as mean ± SEM.


In vivo efficacy verification of anti-human CD47 antibody with AML PDX model BP2010 in B-NDG mice

from clipboard

Antitumor activity of anti-human CD47 antibody in AML PDX model BP2010 established with B-NDG mice. (A) Human CD47 was highly expressed on the surface of tumor cells of BP2010; (B) The proportion of hCD45+ cells in the anti-human CD47 antibody treatment group was significantly reduced. PDX tumor cells of BP2010 were injected into B-NDG mice via tail vein (female, n=7). Mice were grouped when hCD45+ cells of PB reached approximately 1%, at which time they were treated with anti-human CD47 antibody Hu5F9 (in house) and schedules indicated in panel; (C) The survival rate of mice in the treatment group was significantly improved; (D) Body weight changes during treatment. The results indicated that AML PDX model of BP2010 provides a powerful preclinical AML model for efficacy evaluation of anti-human CD47 antibodies. Values are expressed as mean ± SEM.


Animal breeding and maintenance


1. Breeding facilities
  • B-NDG mice are housed in strict SPF (specific pathogen free)-level isolator or IVCs (individually ventilated cages) in our facility.
  • However, given the varying management of animal facilities and microbial levels, we cannot guarantee that mice will grow healthy in all IVC environments. To improve facility standards, strict sanitation procedures are recommended: 
  • The material of the cages should be non-toxic and harmless, which are easy to clean and disinfect.
  • The cages need to be sterilized by autoclaving or Co-60 irradiation and changed regularly
  • The bedding need to be sterilized by autoclaving; 
  • The food need to be sterilized by Co-60 irradiation before use; 
  • All mouse-related operations should be carried out in laminar flow hoods.
  • The cleaner the environment, the more it can ensure the healthy growth of mice for a longer time! 


2. Food

  • “Irradiated Transgenic Lab Rat and Mouse Diet (1010082)” produced by Jiangsu Xietong Pharmaceutical Bio-engineering Co., Ltd. is recommended for breeding B-NDG mice. 


3. Water

  • The autoclaved acidified water (pH 2.5-3.0) is recommended to prevent infection by Pseudomonas and Staphylococcus aureus.


4. Bedding

  • We recommend using shavings or corn cob and placing the nest paper in the cage. 
  • The bedding also need to be sterilized by autoclaved or Co-60 irradiation.
  • The shavings need to be replaced weekly and the corn cob need to be replaced every two weeks. 
  • The bedding needs to be replaced in laminar flow hoods. Mice need to be transferred into new cages using sterilized forceps, avoiding direct hand contact with the mice.