The rationale and future potential of angiogenesis inhibitors in neoplasia.

Malignant tumours are angiogenesis-dependent diseases. Several experimental studies suggest that primary tumour growth, invasiveness and metastasis require neovascularisation. Tumour-associated angiogenesis is a complex multistep process under the control of positive and negative soluble factors. A mutual stimulation occurs between tumour and endothelial cells by paracrine mechanisms. Angiogenesis is necessary, but not sufficient, as the single event for tumour growth. There is, however, compelling evidence that acquisition of the angiogenic phenotype is a common pathway for tumour progression, and that active angiogenesis is associated with other molecular mechanisms leading to tumour progression. Experimental research suggests that it is possible to block angiogenesis by specific inhibitory agents, and that modulation of angiogenic activity is associated with tumour regression in animals with different types of neoplasia. The more promising angiosuppressive agents for clinical testing are: naturally occurring inhibitors of angiogenesis (angiostatin, endostatin, platelet factor-4 and others), specific inhibitors of endothelial cell growth (TNP-470, thalidomide, interleukin-12 and others), agents neutralising angiogenic peptides (antibodies to fibroblast growth factor or vascular endothelial growth factor, suramin and analogues, tecogalan and others) or their receptors, agents that interfere with vascular basement membrane and extracellular matrix [metalloprotease (MMP) inhibitors, angiostatic steroids and others], antiadhesion molecules antibodies such as antiintegrin alpha v beta 3, and miscellaneous drugs that modulate angiogenesis by diverse mechanisms of action. Antiangiogenic therapy is to be distinguished from vascular targeting. Gene therapy aimed to block neovascularisation is also a feasible anticancer strategy in animals bearing experimental tumours. Antiangiogenic therapy represents one of the more promising new approaches to anticancer therapy and it is already in early clinical trials. Because angiosuppressive therapy is aimed at blocking tumour growth indirectly, through modulation of neovascularisation, antiangiogenic agents need to be developed and evaluated as biological response modifiers. Therefore, adequate and well designed clinical trials should be performed for a proper evaluation of antiangiogenic agents, by determination and monitoring of surrogate markers of angiogenic activity.     

Antiangiogenic agents targeting vascular endothelial growth factor and its receptors in clinical development

There is ample therapeutic opportunity for the use of antiangiogenic inhibitors in the clinic, as there are several human diseases that are dependent upon angiogenesis [1]. However, no disease has attracted as much attention as a target for antiangiogenic therapy as malignant disorders. There is a vast amount of literature acting as proof-of-principle for the use of angiogenic inhibitors as effective agents for blocking tumour-induced angiogenesis and subverting tumour growth and disease dissemination. One of the unique attractions of targeting tumour angiogenesis is that vascular endothelial cells are a genetically stable population in which acquisition of therapeutic resistance might be less efficient than in genetically unstable tumour cells [2,3]. This review covers inhibitors that target the tumour angiogenic agent vascular endothelial growth factor and its receptors as one such antiangiogenic approach. Many agents in this class are in clinical trials with limited reports of toxicity and some early evidence of clinical benefit.     

Antineovascular therapy, a novel antiangiogenic approach

Angiogenesis is a crucial event in tumour growth, since the growth of tumour cells depends on the supply of essentials such as oxygen and nutrients. Therefore, suppression of angiogenesis is expected to show potent therapeutic effects on various cancers. Additionally, this 'antiangiogenic therapy' is thought not only to eradicate primary tumour cells, but also suppress tumour metastases through disruption of haematogenous metastatic pathways. Tumour dormancy therapy does not aim to disrupt newly formed angiogenic vessels but aims to inhibit further formation of neovessels through inhibiting certain processes of angiogenesis. This raises a question of whether or not these antiangiogenic agents bring complete cure of tumours as complete cut-off of oxygen and nutrients is not expected by the treatment with these agents. This paper will review a novel antiangiogenic therapy, antineovascular therapy (ANET). ANET is categorised in antiangiogenic therapy but is different from tumour dormancy therapy using conventional angiogenic inhibitors: ANET aims to disrupt neovessels rather than to inhibit neovessel formation. ANET is based on the fact that angiogenic endothelial cells are growing cells and would be effectively damaged by cytotoxic agents when the agents are effectively delivered to the neovessels. The complete eradication of angiogenic endothelial cells may cause complete cut-off of essential supplies to the tumour cells and lead to indirect but strong cytotoxicity instead of cytostasis caused by the inhibition of angiogenesis. For the purpose of ANET, an angiogenic vasculature-targeting probe has been developed, by which cytotoxic anticancer agents are actively delivered to the angiogenic endothelial cells by using drug delivery system (DDS) technology. Another way to damage newly formed vessels by cytotoxic agents is achieved by metronomic-dosing chemotherapy. This chemotherapy shifts the target of chemotherapeutic agents from tumour cells to angiogenic endothelial cells by selective dosing schedule. Similarly, the shift of target from tumour cells to angiogenic endothelial cells enhanced therapeutic efficacy of cancer photo-dynamic therapy (PDT): in this antiangiogenic PDT, photosensitizers are delivered more to neovessel endothelial cells than to tumour cells. These therapeutic strategies would be clinically applied in the future.     

Antiangiogenic agents targeting vascular endothelial growth factor and its receptors in clinical development

There is ample therapeutic opportunity for the use of antiangiogenic inhibitors in the clinic, as there are several human diseases that are dependent upon angiogenesis [1]. However, no disease has attracted as much attention as a target for antiangiogenic therapy as malignant disorders. There is a vast amount of literature acting as proof-of-principle for the use of angiogenic inhibitors as effective agents for blocking tumour-induced angiogenesis and subverting tumour growth and disease dissemination. One of the unique attractions of targeting tumour angiogenesis is that vascular endothelial cells are a genetically stable population in which acquisition of therapeutic resistance might be less efficient than in genetically unstable tumour cells [2,3]. This review covers inhibitors that target the tumour angiogenic agent vascular endothelial growth factor and its receptors as one such antiangiogenic approach. Many agents in this class are in clinical trials with limited reports of toxicity and some early evidence of clinical benefit.     

Do not say ever never more: the ins and outs of antiangiogenic therapies

Angiogenesis has been described as one of the hallmarks of cancer, playing an essential role in tumor growth, invasion, and metastasis. Antiangiogenic therapy was initially perceived as a "magic bullet" that could eventually be used for the treatment of any type of cancer. For this reason inhibition of angiogenesis has become a major challenge in the development of new anticancer agents, with a countless number of antiangiogenic strategies being tested in preclinical and clinical trials. The initial pessimism about the usefulness of the antiangiogenic therapeutic approach for cancer, derived from the poor results obtained in clinical trials, turned into euphoria after the approvals of the anti-VEGF monoclonal antibody bevacizumab and the multitargeted tyrosine kinase inhibitors sunitinib, sorafenib and pazopanib. Nowadays the clinical development of antiangiogenic therapies seems to be unstoppable, not only for cancer, but also for an increasing number of non-neoplasic angiogenesis-related diseases. Nevertheless, careful analysis of the clinical results reveals that therapy with angiogenesis inhibitors often does not prolong survival of cancer patients for more than months. This fact, combined with the high prices of the new antiangiogenic therapies have made a number of oncologists to doubt if they offer "good value". Moreover, recent experimental findings suggest that some antiangiogenic drugs could promote tumor invasiveness and metastasis. The success in the discovery and pharmacological development of future generations of angiogenesis inhibitors will benefit from further advances in the understanding of the mechanisms involved in human angiogenesis.     

Antiangiogenesis and radiotherapy: what is the role of combined modality treatment?

The formation of new blood vessels is a prerequisite for the growth of primary and metastatic tumour. Thus, strategies that aim at the inhibition of tumour angiogenesis have gained considerable interest in recent years. Furthermore, there is a need to identify the role of antiangiogenic agents in conjunction with conventional anticancer modalities like chemotherapy or radiotherapy. It is the objective of this review to summarise experimental data for different antiangiogenic agents used for combined modality experiments with radiotherapy. Promising data have been reported for a series of antiangiogenic agents for combined modality treatment with radiotherapy using tumour growth delay as the primary end-point. Yet, the results from different agents with various tumour lines are contradictory in part. Furthermore, enhancement of local tumour control, the main objective of curative radiotherapy, has so far been demonstrated for only two agents (DC101 and CA4DP), while experiments using TNP-470 even revealed a reduction of local tumour control when combined with irradiation. Finally, detailed studies investigating the modulation of normal tissue reactions for the combination of radiotherapy and inhibitors of angiogenesis are pending so far. Thus, experimental data currently available do not consistently support the beneficial effects of combined modality treatment with inhibitors of angiogenesis and radiotherapy. We therefore conclude that there is still a long way to go until we know which antiangiogenic agent will clinically be suitable for what tumour entity for combined treatment of radiotherapy and inhibitors of angiogenesis.     

Perindopril: possible use in cancer therapy

Since angiogenesis is essential for the growth of any solid tumor, emerging efforts are being made to develop antiangiogenic therapy. To date, however, no antiangiogenic agent has become widely available for the clinical setting. Angiotensin I-converting enzyme (ACE) inhibitors are commonly used as antihypertensive agents and it has recently been suggested that they decrease the risk of cancer. Studies have found that an ACE inhibitor, perindopril, is a potent inhibitor of experimental tumor development and angiogenesis at a clinically comparable dose. The potent angiogenic factor, vascular endothelial growth factor (VEGF), is significantly suppressed by perindopril and also inhibits VEGF-induced tumor growth. In vitro studies showed that perindopril is not cytotoxic to either tumor cells or endothelial cells. Since perindopril is already in widespread clinical use without serious side effects, it may represent a potential new strategy for anticancer therapy.     

Angiogenesis inhibitors: implications for combination with conventional therapies

Angiogenesis is associated with tumor development and malignancy and is a validated target for cancer treatment. Preclinical and clinical evidence substantiates the feasibility of combining angiogenesis inhibitors with conventional anticancer therapy. This review discusses recent progress in combining antiangiogenic drugs, mainly acting on the VEGF/VEGFR pathway, with chemotherapy and other conventional therapies. Strategies for the optimization of combination therapy and the selection of appropriate treatment regimens are examined. As new drugs are entering clinical trials, reliable biomarkers are needed to stratify patients for antiangiogenic therapy, to identify resistant patients and to monitor response to treatment.     

Antiangiogenic drugs: current knowledge and new approaches to cancer therapy

Angiogenesis--process of new blood-vessel growth from existing vasculature--is an integral part of both normal developmental processes and numerous pathologies such as cancer, ischemic diseases and chronic inflammation. Angiogenesis plays a crucial role facilitating tumour growth and the metastatic process, and it is the result of a dynamic balance between proangiogenic and antiangiogenic factors. The potential to block tumour growth and metastases by angiogenesis inhibition represents an intriguing approach to the cancer treatment. Angiogenesis continues to be a topic of major scientific interest; and there are currently more antiangiogenic drugs in cancer clinical trials than those that fit into any other mechanistic category. Based on preclinical studies, researchers believe that targeting the blood vessels which support tumour growth could help treatment of a broad range of cancers. Angiogenic factors or their receptors, endothelial cell proliferation, matrix metalloproteinases or endothelial cell adhesion, are the main targets of an increasing number of clinical trials approved to test the tolerance and therapeutic efficacy of antiangiogenic agents. Unfortunately, contrary to initial expectations, it has been described that antiangiogenic treatment can cause different toxicities in cancer patients. The purpose of this article is to provide an overview of current attempts to inhibit tumour angiogenesis for cancer therapy.     

Antiangiogenic effects of flavonoids and chalcones.

Angiogenesis, the development of new blood vessels from the existing vasculature, is essential in normal developmental processes. Uncontrolled angiogenesis is a major contributor to a number of disease states such as inflammatory disorders, obesity, asthma, diabetes, cirrhosis, multiple sclerosis, endometriosis, AIDS, bacterial infections and autoimmune disease. It is also considered a key step in tumour growth, invasion, and metastasis. Angiogenesis is required for proper nourishment and removal of metabolic wastes from tumour sites. Therefore, modulation of angiogenesis is considered as therapeutic strategies of great importance for human health. Numerous bioactive plant compounds are recently tested for their antiangiogenic potential. Among the most frequently studied are polyphenols present in fruits and vegetables. Plant polyphenols inhibit angiogenesis and metastasis through regulation of multiple signalling pathways. Specifically, flavonoids and chalcones regulate expression of VEGF, matrix metalloproteinases (MMPs), EGFR and inhibit NFkappaB, PI3-K/Akt, ERK1/2 signalling pathways, thereby causing strong antiangiogenic effects. This review focuses on the antiangiogenic properties of flavonoids and chalcones and examines underlying mechanisms.     

Tumour endoproteases: the cutting edge of cancer drug delivery?

Despite progression in anticancer drug development and improvements in the clinical utilization of therapies, current treatment regimes are still dependent upon the use of systemic antiproliferative cytotoxic agents. Although these agents are unquestionably potent, their efficacy is limited by toxicity towards 'normal' cells and a lack of tumour selective targeting, resulting in a therapeutic index which is modest at best. Consequently, the development of more tumour selective cancer treatments, with better discrimination between tumour and normal cells is unequivocally an important goal for cancer drug discovery. One such strategy is to exploit the tumour phenotype as a mechanism for tumour-selective delivery of potent therapeutics. An exciting approach in this area is to develop anticancer therapeutics as prodrugs, which are non-toxic until activated by enzymes localized specifically in the tumour. Enzymes suitable for tumour-activated prodrug development must have increased activity in the tumour relative to non-diseased tissue and an ability to activate the prodrug to its active form. One class of enzyme satisfying these criteria are the tumour endoproteases, particularly the serine- and metallo-proteases. These proteolytic enzymes are essential for tumour angiogenesis, invasion and metastasis, the major defining features of malignancy. This review describes the concept behind development of tumour-endoprotease activated prodrugs and discusses the various studies to date that have demonstrated the huge potential of this approach for improvement of cancer therapy.     

Angiogenesis modulation in cancer research: novel clinical approaches

Angiogenesis--the formation of new blood vessels--is essential for tumour progression and metastasis. Consequently, the modulation of tumour angiogenesis using novel agents has become a highly active area of investigation in cancer research, from the bench to the clinic. However, the great therapeutic potential of these agents has yet to be realized, which could, in part, be because the traditional strategies that are used in clinical trials for anticancer therapies are not appropriate for assessing the efficacy of agents that modulate angiogenesis. Here, we discuss methods for monitoring the biological activity of angiogenic modulators, and innovative approaches to trial design that might facilitate the integration of these agents into anticancer therapy.     

Targeting Angiogenesis for Treatment of Human Cancer

Recent advances in cancer research highlighted the importance of target-specific drug discovery. In view of these advances, the most important mechanism in tumour growth is its ability to stimulate the formation of blood capillaries around itself called tumour-driven angiogenesis. Hence targeting the angiogenesis, inhibits the growth of blood vessels around it and responsible for death of the tumour due to starvation and accumulation of toxic waste. The therapy, thus, indirectly cytotoxic to the tumour cells by targeting newly developing blood vessels. In this review, we summarised the various antiangiogenic agents with their clinical uses and current status.     

Angiogenesis and angiogenesis inhibitors: a new potential anticancer therapeutic strategy

Tumor cells cannot grow as a mass above 2 to 3 mm3 because diffusion is insufficient for oxygen and glucose requirements, unless the tumor induces a blood supply. This mechanism of induction of a new blood supply from pre-existing vascular bed is called angiogenesis. Furthermore, tumor invasiveness and metastasis require neovascularization. In fact, recent published studies suggest that acquisition of the angiogenic phenotype is a common pathway for tumor progression and neovascularization is linked with other molecular steps leading to tumor progression. Angiogenic process is a complex multi-step cascade under the control of positive and negative soluble factors. A paracrine interaction occurs between tumor and endothelial cells. Angiogenesis involves: endothelial cell proliferation, migration and tubule formation with associated changes in the extra-cellular matrix, allowing subsequent new vessel growth toward the tumor. Each of the above steps may represent a target for antiangiogenic therapy. Antiangiogenesis is to be distinguished from direct targeting and destruction of tumor vasculature (vascular targeting). Inhibition of angiogenesis represents one of the more promising, new approaches, to anticancer treatment and its already in early clinical trials. This review takes into consideration: (i) the biological mechanism underlining angiogenesis process; (ii) the method to assess tumor angiogenesis activity; (iii) inhibition of angiogenesis as an anticancer therapy; (iv) the methodology for the clinical development of angiogenesis inhibitors, that should be considered biological response modifiers; (v) some angiogenesis antagonists that are in development and leader compounds that are under clinical trial.     

Realgar transforming solution suppresses angiogenesis and tumor growth by inhibiting VEGF receptor 2 signaling in vein endothelial cells

Realgar (As₄S₄), as an arsenic sulfide mineral drug, has a good therapeutic reputation for anticancer in Traditional Chinese Medicine, and has recently been reported to inhibit angiogenesis in tumor growth. However, considering the poor solubility and low bioavailability of realgar, large dose of realgar and long period of treatment are necessary for achieving the effective blood medicine concentration. In present study, we resolved the crucial problem of poor solubility of realgar by using intrinsic biotransformation in microorganism, and investigated underlying mechanisms of realgar transforming solution (RTS) for antiangiogenesis. Our results demonstrated that RTS had a strong activity to inhibit HUVECs proliferation, migration, invasion, and tube formation. Moreover, RTS inhibited VEGF/bFGF-induced phosphorylation of VEGFR2 and the downstream protein kinases including ERK, FAK, and Src. In vivo zebrafish and chicken chorioallantoic membrane model experiments showed that RTS remarkably blocked angiogenesis. Finally, compared with the control, administration of 2.50 mg/kg RTS reached more than 50% inhibition against H22 tumor allografts in KM mice, but caused few toxic effects in the host. The antiangiogenic effect was indicated by CD31 immunohistochemical staining and alginate-encapsulated tumor cell assay. In summary, our findings suggest that RTS inhibits angiogenesis and may be a potential drug candidate in anticancer therapy.     

Drug inhibition of angiogenesis

Cancer is one of the leading causes of death in the Western world. Though advances in cancer therapy and diagnosis have considerably improved life expectancy, the overall survival rate of patients still remains poor - disseminated cancer at presentation and acquisition of tumour resistance are two reasons for this. Angiogenesis is one of the crucial steps in the pathogenesis of tumours. Drug inhibition of angiogenesis is an area of intense research and at least 10000 cancer patients worldwide have received some form of experimental antiangiogenic therapy. More than 300 angiogenesis inhibitors have been discovered to date; 80 antiangiogenic drugs are currently in clinical trials, 12 of which target the key angiogenic factor vascular endothelial growth factor. A convincing regression of tumours has been reported for drugs against this target. Antiangiogenic therapy has raised the hopes both of cancer sufferers and of the physicians looking after them. A concerted international effort by cancer researchers and the pharmaceutical industry will help to further develop this novel treatment strategy for cancer.     

A cannabinoid quinone inhibits angiogenesis by targeting vascular endothelial cells

Recent findings on the inhibition of angiogenesis and vascular endothelial cell proliferation by anthracycline antibiotics, which contain a quinone moiety, make this type of compound a very promising lead in cancer research/therapy. We have reported that a new cannabinoid anticancer quinone, cannabidiol hydroxyquinone (HU-331), is highly effective against tumor xenografts in nude mice. For evaluation of the antiangiogenic action of cannabinoid quinones, collagen-embedded rat aortic ring assay was used. The ability of cannabinoids to cause endothelial cell apoptosis was assayed by TUNEL staining and flow cytometry analysis. To examine the genes and pathways targeted by HU-331 in vascular endothelial cells, human cDNA microarrays and polymerase chain reaction were used. Immunostaining with anti-CD31 of tumors grown in nude mice served to indicate inhibition of tumor angiogenesis. HU-331 was found to be strongly antiangiogenic, significantly inhibiting angiogenesis at concentrations as low as 300 nM. HU-331 inhibited angiogenesis by directly inducing apoptosis of vascular endothelial cells without changing the expression of pro- and antiangiogenic cytokines and their receptors. A significant decrease in the total area occupied by vessels in HU-331-treated tumors was also observed. These data lead us to consider HU-331 to have high potential as a new antiangiogenic and anticancer drug.     

Contrast agents and applications to assess tumor angiogenesis in vivo by magnetic resonance imaging

Angiogenesis plays a key role in the development of cancer and is precondition for tumor growth, invasion and spread. Therefore, numerous angiogenesis inhibitors have been developed, of which some show potential to defeat cancer in preclinical and clinical trials. However, response to antiangiogenic treatments is often delayed and marked by high interindividual variability making a closely mashed and efficient observation of the patient necessary. Therefore, surrogate markers which specifically catch early response to tumor therapy are highly desirable. Functional parameters like relative blood volume, perfusion and vessel permeability can be assessed using T(1) and T(2)*-weighted dynamic contrast-enhanced (DCE) MRI. Various reports are available on this topic but results are controversial. During antiangiogenic therapies some authors describe pronounced changes in blood volume: others find effects only on vessel permeability or perfusion. These conflictive observations can be attributed to the different tumor models, therapies, measurement techniques and contrast agents (CA). Particularly the choice of the optimal CA is considered to be essential for a successful characterization of tumor angiogenesis. Often therapy effects on vessel permeability only become apparent, when blood pool CA are used. This article reviews the current state of DCE and molecular MRI of angiogenesis. Besides a general introduction of the different measurement and postprocessing methods and its previous applications, design, structure and use of different types of CA are the main focus of this article.     

Last generation of amino-bisphosphonates (N-BPs) and cancer angio-genesis: a new role for these drugs?

Bisphosphonate (BPs) therapy has become a standard of care for patients with malignant bone disease. In addition, preclinical and preliminary clinical data suggest that BPs exert their direct or indirect antitumoral effects on cancer growth factor release, on cancer cell adhesion, invasion and viability, on cancer angiogenesis and on cancer cell apoptosis. Here, after a brief analysis on clinical indications, on the last generation amino-bisphosphonates (N-BP) and on biochemical pathways as molecular targets of BPs, we will discuss the molecular mechanisms of these antitumor effects. Recent evidence suggests that part of the antitumor activity of bisphosphonates may be attributed to an antiangiogenic effect. For this reason, we will analyse all the in vitro and in vivo preclinical reports and the first clinical evidence of anti-angiogenic activity exerted by this class of drugs. Several patents have been reported in the review, considering the recents activities observed for these drugs. Taking together all the major results obtained in the described studies, it is possible to affirm that BPs, particularly zoledronic acid and pamidronate, could potentially represent a very powerful tool for angiogenesis inhibition leading to a better control of cancer growth and progression. The translation into the clinical setting of the preclinical evidence of an antiangiogenic power of these drugs is becoming an imperative need and should represent the objective of future clinical trials.