Metal complexes with aromatic N-containing ligands as potential agents in cancer treatment

Cisplatin (cis-Diamminedichloroplatinum(II)) is now clinically used as one of the most effective anticancer drugs in the treatment of a variety of human solid tumors, such as genitourinary. Unfortunately, its usefulness is limited due to development of resistance in tumor cells and its significant side effects. Thus, a continuing effort is being made to develop analogs to overcome the above shortcomings. However, direct structural analogs of cisplatin have not shown greatly improved clinical efficacy in comparison with the parent drug. The explanation for this finding is that all cis-[PtX(2)(amine)(2)] compounds have shown similar DNA-binding modes, thereby resulting in similar biological consequences. One approach is to look beyond structure-activity on the basis of cisplatin analogs antitumor agents, by identifying novel materials that can be utilized as building blocks. These may have DNA binding modes quite different from that of cisplatin. The introduction of such aromatic N-containing ligands as pyridine, imidazole and 1,10-phenanthroline, and their derivatives (whose donor properties are somewhat similar to the purine and pyrimidine bases) to antitumor agents is drawing attention. Many platinum and non-platinum metal complexes such as palladium, ruthenium, rhodium, copper, and lanthanum, with these aromatic N-containing ligands, have shown very promising antitumor properties in vitro and in vivo in cisplatin-resistant model systems or against cisplatin-insensitive cell lines. For example, one Ru(III) compound, [ImH][trans-Cl(4)(Me(2)SO)(Im)Ru(III)] (Im = imidazole, NAMI-A) successfully entered phase I clinical trials. In this review, medicinal chemistry, DNA binding modes, and the development status of these metal complexes are discussed.     

Lanthanides as anticancer agents

The application of inorganic chemistry to medicine is a rapidly developing field, and novel therapeutic and diagnostic metals and metal complexes are now having an impact on medical practice. Advances in biocoordination chemistry are crucial for improving the design of compounds to reduce toxic side effects and understand their mechanisms of action. A lot of metal-based drugs are widely used in the treatment of cancer. The clinical success of cisplatin and other platinum complexes is limited by significant side effects acquired or intrinsic resistance. Therefore, much attention has focused on designing new coordination compounds with improved pharmacological properties and a broader range of antitumor activity. Strategies for developing new anticancer agents include the incorporation of carrier groups that can target tumor cells with high specificity. Also of interest is to develop complexes that bind to DNA in a fundamentally different manner than cisplatin, in an attempt to overcome the resistance pathways that have evolved to eliminate the drug. This review focuses on recent advances in developing lanthanide anticancer agents with an emphasis on lanthanide coordination complexes. These complexes may provide a broader spectrum of antitumor activity. They were compared with classical platinum anticancer drugs. Lanthanides are also of interest because of their therapeutic radioisotopes. The dominant pharmacological applications of lanthanides are as agents in radioimmunotherapy and photodynamic therapy.     

Drug discovery research on in vivo antitumor-active azolato-bridged dinuclear Pt(II) complexes

Cis-diamminedichloridoplatinum(II) (cisplatin), which was first introduced as a clinical anticancer agent in the 1970s, is still among the most-utilized agents in current cancer chemotherapy. The discovery of cisplatin antitumor activity has catalyzed drug discovery research on antitumor platinum coordination compounds with improved efficacy. Some of new compounds show fewer side effects or expanded clinical applications. Apart from some clinical inconveniences, such as side effects, the high therapeutic efficacy of platinum-based agents implies that further modifications may lead to more effective anticancer platinum drugs which are effective against cancers that are typically resistant to chemotherapy, such as pancreatic cancer, and platinum-refractory cancer. Most of the cisplatin analogs cause cross-resistance to cisplatin, probably because of the similar biological consequences. It is suggested that platinum complexes which interact with DNA; the most probable target molecule, through a mechanism different from that of cisplatin can provide unique anticancer spectra required for next-generation anticancer drugs. Therefore, we synthesized a series of azolato-bridged dinuclear Pt(II) complexes with a general formula, [{cis-Pt(NH(3))(2)}(2)(μ-OH)(μ-azolato)](2+), which can form 1,2-intrastrand crosslinks with a minimal DNA distortion, whereas clinical platinum-based drugs provide 1,2-intrastrand crosslink with severe DNA distortion. Indeed, they exhibit much higher in vitro cytotoxicity than cisplatin, and we have recently found one of the dinuclear Pt(II) complexes exhibits markedly high in vivo antitumor efficacy against pancreatic cancer. Here, I update our drug-discovery research on the series of azolato-bridged dinuclear Pt(II) complexes that may be more effective and safer than current anticancer chemotherapeutic agents.     

Platinum group antitumor chemistry: design and development of new anticancer drugs complementary to cisplatin

In the next two decades, the world is expected to see around 20 million cases of cancer. Moreover, the types of cancer will vary considerably from country to other. Therefore, all efforts will be needed to face such a vast diversity of problems. With current annual sales of about $500 millions, the platinum(II) complex known as cisplatin [cis-(NH3)2PtCl2] is still one of the most effective drugs to treat testicular, ovarian, bladder and neck cancers. Since it was launched in 1978 there has been a rapid expansion in research to find new, more effective metal-based anticancer drugs and to study their interactions with biological systems. This study gives an up to date overview of the anticancer chemistry of the platinum group elements platinum, palladium, and nickel with an emphasis on the new strategies used in the development of new antitumor agents. Methodologies for application of bulky aromatic or aliphatic nitrogen ligands, chiral organic moieties, chelates containing other donor atoms than nitrogen, and biologically active ligands in the design of agents analogous to cisplatin are presented. The review also aims to highlight the class of the unconventional complexes that violate the empirical structure-activity rules (SAR) of platinum compounds and the common features and structural differences between the most successful anticancer complexes that are currently in human clinical trials.     

铂类抗肿瘤药物的研究现状

自从顺铂作为第一代抗肿瘤药物被开发利用以来，人们一直在寻找广谱、高活性、低毒性和无交叉耐药性的铂类抗肿瘤药物，合成和筛选出各种铂络合物。分别介绍根据不同设计思路合成的四价铂络合物、具有活性配体的铂络合物、生物载体为配体的靶向铂络合物、反式铂络合物和具有立体位阻效应的铂络合物及其抗肿瘤活性，综述当前铂类抗肿瘤药物的研究现状。     

Platinum complexes as anticancer agents

The application of inorganic chemistry to medicine is a rapidly developing field, and novel therapeutic and diagnostic metal complexes are now having an impact on medical practice. Advances in biocoordination chemistry are crucial for improving the design of compounds to reduce toxic side effects and understand their mechanisms of action. Cisplatin, as one of the leading metal-based drugs, is widely used in the treatment of cancer. Significant side effects and drug resistance, however, have limited its clinical applications. Biological carriers conjugated to cisplatin analogs have improved specificity for tumor tissue, thereby reducing side effects and drug resistance. Platinum complexes with distinctively different DNA binding modes from that of cisplatin also exhibit promising pharmacological properties. This review focuses on recent advances in developing platinum anticancer agents with an emphasis on platinum coordination complexes.     

Current status of and future perspectives for platinum antitumor drugs

Cisplatin, a simple inorganic compound, has been one of the leading antitumor drugs for near 30 years. However, cisplatin has several drawbacks such as toxicity and drug resistance. Therefore, much attention has been focused on the development of new platinum complexes with improved pharmacological properties and a broader spectrum of activity to tumors. The recent advance of research on the molecular mechanisms of drug action and the cellular mechanisms of the emergence of resistance to cisplatin assists the rational design of new classes of platinum antitumor drugs, though details of both mechanisms still remain elusive. Information on DNA binding mode of platinum complexes, recognition and repair of DNA damage is instructive. Since several not cis isomers but trans isomers and not neutral complexes but cation complexes have been found active in vitro and in vivo, the early empirical structure-activity relationships of cisplatin analogues should be reevaluated. The hypothesis that platinum complexes which bind to DNA in a different manner will have different pharmacological properties has been tested, and now cationic multi-nuclear complexes and even trans-platinum complexes comprise unique classes of antitumor platinum-based agents with chemical and biological properties different from cisplatin. These new type platinum complexes are often effective to acquired cisplatin resistant tumor cells. In conclusion, the following complexes appear to offer great potential as new antitumor agents: (1) Complexes with distinctively different DNA interaction modes from cisplatin, which may circumvent intrinsic and acquired resistance to cisplatin through eluding the vigilance of DNA repair systems and (2) complexes with different tissue distribution or mechanisms of membrane transport which may exhibit a different spectrum of activity.     

Gold coordination complexes as anticancer agents

Metal ions are known to bind with nucleic acids and thereby alter their conformation and biological function. The metal ion-base interaction depends on the nature of both metal and bases; a certain site of coordination is preferred. One of the most notable successes for inorganic drugs has been the effectiveness of platinum complexes against cancer. These advances have spurred a surge of investigations to identify new inorganic agents for use in chemotherapy with improved specificity and decreased toxic side effects. Gold(I) and gold(III) complexes, the last isostructural and isoelectronic with platinum(II) complexes, are potentially attractive as anticancer agents. The design of an effective anticancer agent is a complicated game that must encompass not only the drug's inherent inhibitory properties but also its delivery, dosage, and residence time in vivo. Gold(I) and gold(III) complexes overcome some of these challenges by forming strong covalent attachments to targets. Au(III) isoelectronic with Pt(I1)-d8 system usually forms square planar complexes in solution. Since the square planar geometry of Pt(II) is important for its action as an anticancer drug, Au(III) compounds also can be used for the same purpose with the added advantage of decreased toxicity. This, together with the recent finding that certain transitional metal complexes like Au and Pt complexes have been found to be potentially useful in cancer chemotherapy, created a renewed interest in the study of the interactions of metal ions with respect to the site of binding and the structure and stability of the complexes. This work was motivated by the thought that information on the variety of Au(III) complexes and their effects can be obtained by studying the properties of Au complexes with various ligands. Various studies in the past have shown that Au complexes are very attractive in view of their application as anticancer agents.     

Development and current status of unconventional platinum anticancer complexes

Cisplatin is routinely employed for the treatment of testicular, ovarian cancer and head/neck tumors. Typical doses administrated to patients are 100 mg/day for up to five days. It is believed that the mechanism of action appears to be the binding of cis-Pt(NH3)(2) unit to DNA at two neighboring guanine bases. In the years following the introduction of cisplatin, the design of new platinum anticancer drugs concentrated mainly on direct cisplatin analogies, which stuck to the set of structure-activity relationships summarized by Clear and Hoeschele in 1973. Lately, some pioneering strategies towards the synthesis of novel platinum anticancer drugs based on the improved understanding of the mechanism of platinum resistance have emerged. Those are based on either changing the coordinated nitrogen ligand or altering the leaving groups. Other strategies have been shifted to discover "non classical" drugs that can act in a way different from cisplatin. Abnormal structures that violate the empirical structure-activity relationships of platinum compounds and multinuclear complexes are examples of these compounds. Several review articles appeared during recent years dealing with the synthesis, preclinical screening, and mechanism of action of platinum-based anticancer drugs. In this review, the progress in the field of anticancer chemistry based on unconventional platinum antitumor agents during the last 10 years will be highlighted. Most of the complexes that illustrate the recent and the previous prominent strategies will be presented.     

Recent developments in the field of tumor-inhibiting metal complexes

25 years after the first approval of cisplatin in the clinic against a number of cancer diseases, cisplatin and related compounds continue to be among the most efficient anticancer drugs used so far. Efforts are focused to develop novel platinum- and non-platinum-based antitumor drugs to improve clinical effectiveness, to reduce general toxicity and to broaden the spectrum of activity. In the field of non-platinum compounds exhibiting anticancer properties, ruthenium complexes are very promising, showing activity on tumors which developed resistance to cisplatin or in which cisplatin is inactive. Furthermore, general toxicity was found to be very low. The first ruthenium compound NAMI-A entered phase I clinical trials in 1999 as an antimetastatic drug, whereas the ruthenium complex KP1019 will enter phase I clinical trials in 2003 as an anticancer drug which is among others very active against colon carcinomas and their metastases. Remarkable progress is also seen in developing tumor inhibiting gallium compounds. One of them, KP46, will also enter phase I clinical trials in 2003. This article reviews briefly the achievements in the field of anticancer metal complexes focusing the discussion onto the impact of the group of Bioinorganic Chemistry at the Department of Inorganic Chemistry at the University of Vienna. The development of pH sensitive platinum prodrugs, platinum-based drug targeting strategies with low-molecular-weight carriers, kinetically inert platinum(IV) complexes, as well as tumor inhibiting non-platinum anticancer drugs based on ruthenium and gallium is covered in the following sections.     

Application of metal ions and their complexes in medicine II. Application of platina complexes in the treatment of tumor

The rapid development of inorganic medical chemistry opens enormous potential for various applications of a range of inorganic substances in the medicine. Thus inorganic chemistry offers real possibilities to pharmaceutical industries, which used to be dominated by organic chemistry alone. The field has particularly been stimulated by the success-story of cisplatin, which is the World's best selling anticancer drug. Nowadays orally administered Pt(IV) complexes with reduced toxicity, and activity against resistant tumors are on various phases of clinical trial.     

Recent developments in the field of anticancer platinum complexes

Cisplatin, carboplatin and oxaliplatin continue to be among the most efficient anticancer drugs in world-wide clinical use so far. In particular, cisplatin has shown a remarkable therapeutic efficacy in a broad spectrum of solid tumors and outstanding activity against metastatic testicular germ-cell cancer with cure rates of about 90% of cases. Nevertheless, the dose-limiting severe toxic side-effects of platinum-based chemotherapy, the problem of inherent or therapy-induced resistance, the limited activity in a range of tumors, and the meager tumor selectivity are the motivation for tremendous efforts and inventions in the development of novel anticancer platinum drugs. This article reviews the most recent patents in this field of research, covering the following strategies in the design of promising anticancer platinum complexes: (i) synthesis of new anticancer platinum complexes, using combinatorial chemistry and high throughput synthesis and screening, (ii) activation of platinum complexes in the tumor tissue, (iii) accumulation of platinum complexes at the tumor site, (iv) novel platinum complexes, displaying activity against cisplatin resistant cells and as inhibitors of specific biological functions, and (v) direct derivatives of classical anticancer platinum drugs in clinical use.     

Tuning the Activity of Platinum(IV) Anticancer Complexes through Asymmetric Acylation

Platinum(II) anticancer drug cisplatin is one of the most important chemotherapeutic agents in clinical use but is limited by its high toxicity and severe side effects. Platinum(IV) anticancer prodrugs can overcome these limitations by resisting premature aquation and binding to essential plasma proteins. Structure-activity relationship studies revealed a link between the efficacy of platinum(IV) complexes with the nature of their axial ligands, which can be modified to enhance the properties of the prodrug. The existing paradigm of employing platinum(IV) complexes with symmetrical axial carboxylate ligands does not fully exploit their vast potential. A new approach was conceived to control properties of platinum(IV) prodrugs using contrasting axial ligands via sequential acylation. We report a novel class of asymmetric platinum(IV) carboxylates based on the cisplatin template containing both hydrophilic and lipophilic ligands on the same scaffold designed to improve their aqueous properties and enhance their efficacy against cancer cells in vitro.     

Zinc complexes developed as metallopharmaceutics for treating diabetes mellitus based on the bio-medicinal inorganic chemistry

Biological trace metals such as iron, zinc, copper, and manganese are essential to life and health of humans, and the success of platinum drugs in the cancer chemotherapy has rapidly grown interest in developing inorganic pharmaceutical agents in medicinal chemistry, that is, medicinal inorganic chemistry, using essential elements and other biological trace metals. Transition metal complexes with unique chemical structures may be useful alternatives to the drugs available to address some of the incurable diseases. In this review, we emphasize that metal complexes are an expanding of interest in the research field of treatment of diabetes mellitus. Especially, orally active anti-diabetic and anti-metabolic syndrome zinc complexes have been developed and progressed since the discovery in 2001, where several highly potent anti-diabetic zinc complexes with different coordination structures have quite recently been disclosed, using experimental diabetic animals. In all of the complexes discussed, zinc is found to be biologically active and function by interacting with some target proteins related with diabetes mellitus. The design and screening of zinc complexes with higher activity is not efficient without consideration of the translational research. For the development of a clinically useful metallopharmaceutics, the research of zinc complexes on the long-term toxicity including side effects, clear-cut evidence of target molecule for the in vivo pharmacological action, and good pharmacokinetic property are essential in the current and future studies.     

铂类抗癌药物脂质体的研究进展*

目前在药物靶向性给药系统中，脂质体是最成熟和最先进的药物载体之一。脂质体已应用于许多细胞毒抗癌药物的靶向剂型的开发中，例如多柔比星（阿霉素）、紫杉醇和铂类抗癌药物。脂质体可以减少药物的毒副作用，提高抗癌疗效，甚至克服顺铂耐药性。现综述铂类抗癌药物脂质体的临床前和临床研究的进展情况。     

铂类抗肿瘤配合物的研究进展

铂类药物因抗癌谱广、疗效显著而在临床中被广泛使用。自1978年顺铂应用于临床以来,卡铂、奥沙利铂相继被美国FDA批准,乐铂、奈达铂和依铂分别在中国、日本以及韩国上市。然而,铂类药物的毒副作用和耐药性大大限制了其应用和开发。为提高铂类药物的疗效以及克服其缺陷,大量的新型铂类配合物被设计合成,并在不同阶段开展疗效试验。除与顺铂类似的铂(Ⅱ)配合物之外,近年来作为前药的铂(Ⅳ)配合物也被广泛研究。从铂(Ⅱ)配合物和铂(Ⅳ)配合物2个方面,总结近年来铂类抗肿瘤配合物取得的研究进展,并对配体的选择与配合物设计、作用机制、抗肿瘤效果以及临床应用前景进行概述,以期对今后的新药开发和临床应用有所裨益。     

Novel approaches towards development of non-classical platinum-based antineoplastic agents: design of platinum complexes characterized by an alternative DNA-binding pattern and/or tumor-targeted cytotoxicity

Cisplatin is an essential antineoplastic agent whose introduction in clinical use revolutionized the treatment of several solid malignancies, especially those of germinative origin. The unfavorable toxicological profile of this drug, however as well as the resistance of some common malignancies solicited the search of platinum complexes, characterized by lower toxicity and/or broader antitumor spectrum. Thus during the last three decades a plethora of several thousand platinum coordination compounds have been synthesized and evaluated as potential antineoplastic agents. Despite of the numerous compounds investigated however only few of the proved to be of clinical significance and actually none of them could be considered as an ideal substitute for cisplatin regarding both lower toxicity and broader spectrum of anticancer activity. To a great extent the platinum-based drug discovery was confined at structural modification of the parent compound in line with the classic structure-activity relationship concept. Conversely, since the majority of platinum complexes developed so far are closely related structural analogues of cisplatin, it is not surprising that they produce similar cellular effects and any altered pattern of antitumor activity and/or toxicity is likely to be due to pharmacokinetic, rather than truly mechanistic, factors. Studies over the last few years have shown that the structural resemblance to cisplatin is not an absolute requirement for cytotoxicity, which broadens the search for cisplatin analogues towards non-classical compounds with prominent structural/pharmacodynamic dissimilarity to the prototype. This review covers the major approaches to elaboration of non-classical platinum complexes with emphasis on complexes interacting with DNA in a cisplatin-dissimilar fashion and complexes with tumor-targeted cytotoxicity.     

What does the future hold for photo-oxidizing Ru(II) complexes with polyazaaromatic ligands in medicinal chemistry?

Since the discovery of cisplatin, the search for diagnostic or therapeutic agents based on other metals, has expanded intensively owing to the numerous possibilities offered by coordination chemistry. This mini-review focuses on recent advances in the search for Ru(II) polyazaaromatic complexes of potential interest as molecular tools applied to cellular diagnostics or as specific cellular photo-reagents for future biomedical applications. The interaction of Ru(II) polyazaaromatic complexes with living cells is reported, as well as the photo-reaction mechanisms of photo-oxidizing Ru(II) complexes with nucleic acids. The novel strategies currently developed to improve their reactivity and specificity towards DNA, more particularly in the gene-silencing framework, are also discussed.     

Searching for the magic bullet: anticancer platinum drugs which can be accumulated or activated in the tumor tissue

Cisplatin, carboplatin and oxaliplatin are anticancer drugs, which are efficiently used in the clinics all over the world. Besides a remarkable therapeutic efficacy in a series of solid tumors and outstanding activity of cisplatin against testicular germ-cell cancer, the platinum-based therapy is in part accompanied by a set of severe toxic side-effects. The design of platinum complexes being equipped with an exclusive selectivity for the tumoral tissue and exhibiting a lack of systemic toxicity ('magic bullets') is the great hope in the fight against cancer and also a motor within the expanding field of bioinorganic chemistry. In this review article, two promising strategies, namely accumulation and activation of tumor inhibiting platinum complexes specifically at the tumor site is presented, demonstrating a stepwise approach towards the 'magic bullet' concept propagated by Paul Ehrlich.