鸡胚模型在生物研究中的应用进展

实验动物模型在预防、诊断、治疗疾病和探讨疾病的发生机制等方面起到了至关重要的作用。鸡胚发育过程清楚,利用鸡胚本身的结构特点,可作为研究与胚胎发育相关的生物学实验模型。另外,鸡胚绒毛尿囊膜（CAM）血管丰富,是天然免疫缺陷宿主,可作为血管药理学、肿瘤学等方面研究的一个较为理想的实验模型。本文综述了鸡胚模型在生物实验研究中的应用进展。     

The chick embryo chorioallantoic membrane as an in vivo experimental model to study human neuroblastoma

The chick embryo chorioallantoic membrane (CAM) has long been a favored system for the study of tumor angiogenesis because at the stage of development when generally tumor grafts are placed (6–10 days of incubation), the chick’s immunocompetent system is not fully developed and the conditions for rejection have not yet been established. All studies for mammalian neoplasms, including neuroblastoma, have used tumor cell lines, tumor bioptic specimens, cell suspensions derived from tumors, and mouse tumor xenografts bioptic specimens. CAM can also be used to study the effects of antiangiogenic molecules on tumor cell suspensions of tumor bioptic specimens. This review article summarizes and discusses the literature data on the use of the CAM as an in vivo experimental model to study human neuroblastoma.     

An assay for cancer stem cell-induced angiogenesis on chick chorioallantoic membrane

Angiogenesis is generally involved in tumor growth and metastasis. Cancer stem cells (CSCs) are considered to facilitate the angiogenesis. Therefore, CSCs could be the effective targets to stop angiogenesis. Recently, our group successfully generated CSC models from induced pluripotent stem cells (iPSCs) in the presence of conditioned medium derived from cancer derived cells. These novel model CSCs has been characterized by highly tumorigenic, angiogenic and metastatic potentials in vivo. The angiogenic potential of CSCs has been explained by the expression of both angiogenic factors and their receptors implying the angiogenesis in autocrine manner. In this protocol we optimized the method to evaluate tumor angiogenesis with the CSC model, which was described effective to assess sorafenib as an antiangiogenic drug, on chick chorioallantoic membrane (CAM) assay. Our results demonstrate that CSCs developed from iPSCs and CAM assay are a robust and cost-effective tool to evaluate tumor angiogenesis with CSCs. Collectively, CSCs in CAM assay could serve as a very useful model for the screening of potential therapeutic agents targeting tumor angiogenesis.     

The effect of early prenatal hypercapnia on the vascular network in the chorioallantoic membrane of the chicken embryo

Over the last decade, the poultry sector has sought to develop novel ways to monitor chicken embryonic growth, health, and quality to control and optimize egg incubation conditions, particularly the concentration of dissolved gases (O(2), CO(2)). One of the parameters, which may change under different gas concentrations, is the angiogenesis in the chorioallantoic membrane (CAM), the organ for gas exchange of the chicken embryo. In this study, a newly developed methodology was used to quantify the angiogenesis in the CAM under normal and early hypercapnic conditions (i.e., increased CO(2) concentrations). Two experiments were conducted in which the same CO(2) profile was applied. The development of the vascular system was monitored from embryonic day (ED) 10 until ED 14 in Experiment 1, and until ED 16 in Experiment 2. This development was characterized by two different parameters-the vascular fraction (VF) as a measure for the density of the vascular network and the fractal dimension (FD) as a measure for the degree of branching of the vascular network. Moreover, in Experiment 2, embryo weights were compared between both groups. The proposed methodology showed that differences in the development of the vascular system could be observed across groups but also as function of the ED. Both VF and FD and the embryo weights were shown to be higher in the hypercapnia group compared to the control group.     

Antiangiogenic effect of sulphated and nonsulphated glycosaminoglycans and polysaccharides in the chick embryo chorioallantoic membrane

The inhibiting effect of sulphated and nonsulphated glycosaminoglycans and polysaccharides on the normal outgrowth of capillaries was tested in the chick embryo chorioallantoic membrane (CAM) with and without the presence of hydrocortisone. An antiangiogenic response to 50 µg of heparin and heparan sulphate (without hydrocortisone present) was observed in 38.8% and 23.1% of the CAMS, respectively, while the antiangiogenic response rate for dermatan sulphate, chondroitin sulphate A or C, hyaluronic acid and keratan sulphate was 15.9–0%. All sulphated homopolysaccharides tested were more effective than the naturally occurring glycosaminoglycans. Nonsulphated dextran and (methyl) cellulose had no antiangiogenic effect, while largely desulphated heparin retained such an effect. Hydrocortisone generally improved the antiangiogenic effect, a 100% response was obtained when it was combined with cellulose sulphate or fucoidan (polyfucose sulphate derived from marine algae), but the antiangiogenic effect of the largely desulphated heparin was unaffected by the presence of hydrocortisone. The results show that different polysulphated polysaccharides also have an antiangiogenic effect, without the addition of corticosteroids. The effect was apparently independent of their degree of sulphation, but the glycosidic structure may be of critical importance.     

The role of fibroblast growth factor-2 in the vascularization of the chick embryo chorioallantoic membrane

The CAM is an extraembryonic membrane which serves as a gas exchange surface and its respiratory function is provided by an extensive capillary network. The development of the vascular system of the CAM is a complex, highly regulated process that depends on genetic and epigenetic factors expressed by endothelial and non-endothelial cells. In spite of the evidence that several growth factors are angiogenic in the CAM assay, poorly investigated is their role in the development of the CAM's vascular system. This article reviews our studies concerning the role of exogenous and endogenous fibroblast growth factor-2 (FGF-2) in the CAM vascularization. The findings in all these studies support the importance of FGF-2 as an autocrine paracrine stimulator of angiogenesis and its key role in the development of the vascular system in the avian embryo.     

The chick embryo chorioallantoic membrane as a model for tumor biology

Among the in vivo models, the chick embryo chorioallantoic membrane (CAM) has been used to implant several tumor types as well as malignant cell lines to study their growth rate, angiogenic potential and metastatic capability. This review article is focused on the major compelling literature data on the use of the CAM to investigate tumor growth and the metastatic process.     

The potential of spatially resolved spectroscopy for monitoring angiogenesis in the chorioallantoic membrane

Over the last decade, the poultry sector has sought to develop ways to monitor chicken embryonic development as to optimize the incubation conditions. One of the parameters of development which may change under different incubation conditions is the angiogenesis in the chorioallantoic membrane (CAM). To be able to quantify these changes in the angiogenesis and detect long-term effects on health, a non-destructive technique is necessary. In this article, the first steps toward such a non-destructive technique are successfully taken. A spatially resolved spectroscopy set-up is built and tested for its potential to measure changes in angiogenesis with incubation time, and differences between a normal and hypercapnic incubation. In this first study, reflectance measurements are performed directly on the CAM as the eggshell considerably complicates the analysis. This issue should be addressed in future research to come to a really non-destructive technique. An experiment was conducted in which one group was incubated under normal conditions, and another under early prenatal hypercapnic conditions (i.e., increased CO(2) concentrations). The angiogenesis in the CAM was measured at embryonic day (ED) 10, 13, and 16. The measurements showed a clear blood spectrum with an increasing amount of blood in time, and significant differences in the reflectance as function of the source-detector distances. However, no significant differences between the hypercapnia and the control group could be detected.     

Methylene blue inhibits angiogenesis in chick chorioallontoic membrane through a nitric oxide-independent mechanism

Angiogenesis is the process of generating new blood vessels from preexisting vessels and is considered essential in many pathological conditions. The purpose of the present study was to evaluate the effect of methylene blue in chick chorioallantoic membrane angiogenesis model in vivo. In this well characterized model, methylene blue inhibited angiogenesis in a concentration-dependent manner. In addition, when methylene blue was combined with sodium nitroprusside, a spontaneous generator of nitric oxide, an inhibition of angiogenesis was evident which was comparable with that observed by the application of methylene blue alone. Sodium nitroprusside, alone, caused a significant inhibition in basal angiogenesis. These results provide evidence that methylene blue inhibits angiogenesis independently of nitric oxide pathway and suggest that methylene blue may be useful for treating angiogenesis-dependent human diseases.     

Chick embryo chorioallantoic membrane (CAM): an alternative predictive model in acute toxicological studies for anti-cancer drugs

The chick embryo chorioallantoic membrane (CAM) is a preclinical model widely used for vascular and anti-vascular effects of therapeutic agents in vivo. In this study, we examine the suitability of CAM as a predictive model for acute toxicology studies of drugs by comparing it to conventional mouse and rat models for 10 FDA-approved anticancer drugs (paclitaxel, carmustine, camptothecin, cyclophosphamide, vincristine, cisplatin, aloin, mitomycin C, actinomycin-D, melphalan). Suitable formulations for intravenous administration were determined before the average of median lethal dose (LD₅₀) and median survival dose (SD₅₀) in the CAM were measured and calculated for these drugs. The resultant ideal LD₅₀ values were correlated to those reported in the literature using Pearson’s correlation test for both intravenous and intraperitoneal routes of injection in rodents. Our results showed moderate correlations (r²=0.42 − 0.68, P<0.005–0.05) between the ideal LD₅₀ values obtained using the CAM model with LD₅₀ values from mice and rats models for both intravenous and intraperitoneal administrations, suggesting that the chick embryo may be a suitable alternative model for acute drug toxicity screening before embarking on full toxicological investigations in rodents in development of anticancer drugs.     

Gastrulating chick embryo as a model for evaluating teratogenicity: a comparison of three approaches

BACKGROUND: Teratology studies must be carefully designed to minimize potential secondary effects of vehicle and delivery routes. A systematic method to evaluate chick models of early embryogenesis is lacking. METHODS: We investigated 3 experimental approaches that are popular for studies of early avian development, in terms of their utility for teratogen assessment starting at gastrulation. These included in vitro embryo culture, egg windowing followed by direct application of a carrier vehicle to the embryo, and injection of a carrier vehicle into the egg yolk. We also developed a morphologically based scoring system to assess development of the early embryo. RESULTS: The in vitro culture and egg windowing approaches both caused an unacceptably high incidence of central nervous system and cardiac abnormalities in vehicle-treated embryos, which made it difficult to identify teratogen-specific defects. In contrast, exposing chick embryos to vehicle via direct egg yolk injection did not induce developmental anomalies. CONCLUSIONS: Optimization of the exposure route of potential toxicants to the embryo is critical because control treatments can cause developmental anomalies. In ovo yolk injection minimizes perturbation of young embryos and may be appropriate for teratogen delivery.     

The chick embryo: hatching a model for contemporary biomedical research

Animal models play a crucial role in fundamental and medical research. Progress in the fields of drug discovery, regenerative medicine and cancer research among others are heavily dependent on in vivo models to validate in vitro observations, and develop new therapeutic approaches. However, conventional rodent and large animal experiments face ethical, practical and technical issues that limit their usage. The chick embryo represents an accessible and economical in vivo model, which has long been used in developmental biology, gene expression analysis and loss/gain of function experiments. It is also an established model for tissue/cell transplantation, and because of its lack of immune system in early development, the chick embryo is increasingly recognised as a model of choice for mammalian biology with new applications for stem cell and cancer research. Here, we review novel applications of the chick embryo model, and discuss future developments of this in vivo model for biomedical research.     

The effects of chemical irritants and tobacco smoke condensate on the chorioallantoic membrane of the fertile hen's egg

The effects of various materials on the chorioallantoic membrane of the 10-day incubated fertile hen's egg have been studied. A detailed sequential histological study of the effects of croton oil and tobacco smoke condensate showed that both substances caused local haemorrhage and necrosis, followed by hyperplasia. The degree of thickening was found to be both dose-and time-dependent. From these observations a test procedure for comparing the irritant activity of tobacco smoke condensates has been developed; this procedure involves measuring the maximum thickness of the membranes 72 h after application of the condensates.     

Insulin synthesis in chick embryo retinas during development

Retinas of chick embryos contain insulin (1) and further, are capable of synthesizing it, as demonstrated by incubating retinas at different ages (7th–18th day) with [³H]leucine. The synthesized radioactive insulin was isolated and assayed by means of a HPLC procedure. The synthesis of insulin was found to be highest in the youngest retinas studied (day 7), afterwards it declined with age except for an increment found at 14–15 day. Explants of chick embryo retinas, cultured in vitro, rapidly degraded insulin. Nevertheless, the content of immunoreactive insulin in retinal explants diminished slowly with the age of culture, so that, after 8 days of incubation, it was about 60% of the content found in the retinas at the beginning of incubation. This was proof that cultured explants are capable of efficiently synthesizing insulin. The synthesized [³H]insulin was released from explants into the medium. This was evident also after 6–8 days in culture.     

Perfluorocarbon-based medium for culture of the early chick embryo heart

Summary In an attempt to prolong the survival of the explanted early chick embryo heart, hearts at stages 10 to 28 were cultured in supplemented Dulbecco's modified Eagle's medium with or without the perfluorocarbon, perfluorotributylamine. The perfluorocarbon was added to the standard culture medium in a 50∶50 (vol/vol) mixture. Explants were evaluated daily and were harvested for light microscopy after 2 to 10 d in culture. The tubular shape of the explants was generally maintained for 2 d in culture, after which the hearts became dilated or spherical. Beating was noted in some of the explants on Day 2 in culture but not thereafter. Microscopic evaluation showed patchy areas of necrosis in all explants by Day 3, although large areas of viable epithelioid cells were documented as long as 7 d after explantation. State 16 to 18 hearts cultured in the presence of perfluorocarbon were more likely to maintain tubular architecture on microscopy than hearts cultured in standard medium. Hearts cultured from later stages showed no improvement in appearance with the presence of perfluorocarbon and there was a suggestion of increased necrosis in later-stage explants cultured with pefluorocarbon for 4 d. Further modification of the culture system will be required to prolong explant survival and development beyond 2 d.     

Glutamine synthetase induction in chick embryo retina monolayers

Induction of glutamine synthetase (GS) by cortisol has been shown to occur in monolayer cultures of cells obtained by enzymatic dissociation of retinas from 8- and 12-day-old chick embryos with papain (0.1%) or trypsin (0.25%). Although essentially sigle cells when plated, monolayers obtained by enzymatic dissociation show significant aggregation by 4–6 h. Monolayers prepared by mechanical dispersion (cells forced through successively smaller gage needles) are minimally inducible, perhaps owing to poor viability in such cultures. Storage at 4°C for 24 h prior to treatment with cortisol significantly elevated both basal GS activity and inducibility in whole (but not in monolayer) retina cultures.     

Effect of thymosin peptides on the chick chorioallantoic membrane angiogenesis model

The effect of α- and β-thymosin peptides, namely prothymosin α (ProTα), thymosin α₁ (Tα1), parathymosin α (ParaTα), thymosin β₄ (Tβ4), thymosin β₁₀ (Tβ10), and thymosin β₉ (Tβ9), on the angiogenesis process was investigated using the chick chorioallantoic membrane as an in vivo angiogenesis model. The thymosin peptides tested were applied in 10 μl aliquots containing 0.01–4 nmoles of Tβ4, Tβ10 or Tβ9, 0.016–6.66 nmoles of Tα1, 4.1 pmoles–1.66 nmoles of ProTα, and 4.4 pmoles–1.76 nmoles of ParaTα. Phorbol 12-myristate 13-acetate and hydrocortisone were also used as positive and negative control, respectively. Tβ4, ProTα and Tα1 were found to enhance angiogenesis, while Tβ10, Tβ9 and ParaTα exhibited an inhibitory effect on the angiogenesis process. When mixtures of Tβ4 and Tβ10 containing active amounts of the two peptides at different proportions were applied, the promoting effect of Tβ4 on angiogenesis was reversed in the presence of increasing concentrations of Tβ10 and vice versa. The effect of Tβ10, Tβ9, ProTα and ParaTα, in parallel with Tβ4 and Tα1, on the angiogenesis process was investigated for the first time as far as we know and the results of this study offer more insight into the biological regulatory roles of thymosin peptides, and provide helpful information about their therapeutic potential. Whether these agents could be used either as inhibitors of angiogenesis in disease states where uncontrolled angiogenesis is involved, e.g. in carcinogenesis, or as angiogenesis promoters that could be useful in wound healing, fracture repair, peptic ulcers etc., remains to be further studied.