Glucocorticoids-based prodrug design: Current strategies and research progress.

Attributing to their broad pharmacological effects encompassing anti-inflammation, antitoxin, and immunosuppression, glucocorticoids (GCs) are extensively utilized in the clinic for the treatment of diverse diseases such as lupus erythematosus, nephritis, arthritis, ulcerative colitis, asthma, keratitis, macular edema, and leukemia. However, long-term use often causes undesirable side effects, including metabolic disorders-induced Cushing's syndrome (buffalo back, full moon face, hyperglycemia, etc.), osteoporosis, aggravated infection, psychosis, glaucoma, and cataract. These notorious side effects seriously compromise patients' quality of life, especially in patients with chronic diseases. Therefore, glucocorticoid-based advanced drug delivery systems for reducing adverse effects have received extensive attention. Among them, prodrugs have the advantages of low investment, low risk, and high success rate, making them a promising strategy. In this review, we propose the strategies for the design and summarize current research progress of glucocorticoid-based prodrugs in recent decades, including polymer-based prodrugs, dendrimer-based prodrugs, antibody-drug conjugates, peptide-drug conjugates, carbohydrate-based prodrugs, aliphatic acid-based prodrugs and so on. Besides, we also raise issues that need to be focused on during the development of glucocorticoid-based prodrugs. This review is expected to be helpful for the research and development of novel GCs and prodrugs.

Design, Synthesis, and Evaluation of Carbonate-Linked Halogenated Phenazine-Quinone Prodrugs with Improved Water-Solubility and Potent Antibacterial Profiles.

Pathogenic bacteria have devastating impacts on human health as a result of acquired antibiotic resistance and innate tolerance. Every class of our current antibiotic arsenal was initially discovered as growth-inhibiting agents that target actively replicating (individual, free-floating) planktonic bacteria. Bacteria are notorious for utilizing a diversity of resistance mechanisms to overcome the action of conventional antibiotic therapies and forming surface-attached biofilm communities enriched in (non-replicating) persister cells. To address problems associated with pathogenic bacteria, our group is developing halogenated phenazine (HP) molecules that demonstrate potent antibacterial and biofilm-eradicating activities through a unique iron starvation mode of action. In this study, we designed, synthesized, and investigated a focused collection of carbonate-linked HP prodrugs bearing a quinone trigger to target the reductive cytoplasm of bacteria for bioactivation and subsequent HP release. The quinone moiety also contains a polyethylene glycol group, which dramatically enhances the water-solubility properties of the HP-quinone prodrugs reported herein. We found carbonate-linked HP-quinone prodrugs 11, 21-23 to demonstrate good linker stability, rapid release of the active HP warhead following dithiothreitol (reductive) treatment, and potent antibacterial activities against methicillin-resistant Staphylococcus aureus (MRSA), methicillin-resistant Staphylococcus epidermidis, and Enterococcus faecalis. In addition, HP-quinone prodrug 21 induced rapid iron starvation in MRSA and S. epidermidis biofilms, illustrating prodrug action within these surface-attached communities. Overall, we are highly encouraged by these findings and believe that HP prodrugs have the potential to address antibiotic resistant and tolerant bacterial infections.

Photoactivatable nanoagonists chemically programmed for pharmacokinetic tuning and in situ cancer vaccination.

Immunotherapy holds great promise for the treatment of aggressive and metastatic cancers; however, currently available immunotherapeutics, such as immune checkpoint blockade, benefit only a small subset of patients. A photoactivatable toll-like receptor 7/8 (TLR7/8) nanoagonist (PNA) system that imparts near-infrared (NIR) light-induced immunogenic cell death (ICD) in dying tumor cells in synchrony with the spontaneous release of a potent immunoadjuvant is developed here. The PNA consists of polymer-derived proimmunoadjuvants ligated via a reactive oxygen species (ROS)-cleavable linker and polymer-derived photosensitizers, which are further encapsulated in amphiphilic matrices for systemic injection. In particular, conjugation of the TLR7/8 agonist resiquimod to biodegradable macromolecular moieties with different molecular weights enabled pharmacokinetic tuning of small-molecule agonists and optimized delivery efficiency in mice. Upon NIR photoirradiation, PNA effectively generated ROS not only to ablate tumors and induce the ICD cascade but also to trigger the on-demand release of TLR agonists. In several preclinical cancer models, intravenous PNA administration followed by NIR tumor irradiation resulted in remarkable tumor regression and suppressed postsurgical tumor recurrence and metastasis. Furthermore, this treatment profoundly shifted the tumor immune landscape to a tumoricidal one, eliciting robust tumor-specific T cell priming in vivo. This work highlights a simple and cost-effective approach to generate in situ cancer vaccines for synergistic photodynamic immunotherapy of metastatic cancers.

In Vitro Properties and Pharmacokinetics of Temporarily PEGylated Onc72 Prodrugs.

The favorable properties of antimicrobial peptides (AMPs) to rapidly kill pathogens are often limited by unfavorable pharmacokinetics due to fast degradation and renal clearance rates. Here, a prodrug strategy linking proline-rich AMP Onc72 to polyethylene glycol (PEGs) with average molecular weights of 5 and 20 kDa via a peptide linker containing a protease cleavage site is tested for the first time in vivo. Onc72 is released from these 5k- and 20k-prodrugs in mouse serum with half-life times (t1/2 ) of 8 and 14 h, respectively. Importantly, PEGylation protects Onc72 from proteolytic degradation providing a prolonged release of Onc72, balancing the degradation of free Onc72, and leading to relatively stable Onc72 concentrations and high antibacterial activities. The prodrugs are not hemolytic on human erythrocytes and show only slight cytotoxic effects on human cell lines indicating promising safety margins. When administered subcutaneously to female CD-1 mice, the prodrugs elimination t1/2 are 66 min and ≈5.5 h, respectively, compared to 43 min of free Onc72. The maximal Onc72 plasma levels are obtained ≈1 and ≈8 h postadministration, respectively. In conclusion, the prodrugs provide extended elimination t1/2 and a constant release of Onc72 in mice, potentially limiting adverse effects and increasing efficacy.

Several non-salt and solid thienopyridine derivatives as oral P2Y12 receptor inhibitors with good stability.

A series of novel thienopyridine derivatives were designed and synthesized as P2Y12 receptor inhibitors. Several solid compounds were assessed for inhibitory effect where they exhibited stronger potency than clopidogrel. Compound 6b and 6g were evaluated for metabolism to verify that they could overcome clopidogrel resistance and for toxicity where they showed lower toxicity than prasugrel. Compound 6b exhibited lower risk of bleeding than prasugrel and showed good stability under stress testing. Overall, as a promising antiplatelet agent, representative compound 6b showed the following advantages: (1) no drug resistance for CYP2C19 poor metabolizers; (2) higher potency than clopidogrel; (3) lower toxicity than prasugrel; (4) lower risk of bleeding than prasugrel; (5) good stability as a non-salt solid.

The Application of Prodrug-based Drug Delivery Strategy in Anticancer Drugs.

Cancer is the second leading cause of human death after cardiovascular disease, and the most used drugs in clinics are cytotoxic agents. However, these drugs have some inherent disadvantages, such as the risk of toxicity, low selectivity, poor solubility, and so on. To overcome these shortcomings, a variety of drug delivery strategies based on prodrugs have been developed. The application of drug delivery systems can optimize ADME properties of cytotoxic agents and improve their selectivity at the target, thereby greatly enhancing the anticancer effect in clinics. At present, it has become mainstream in drug design. This review systematically summarized the studies of prodrug- based drug delivery systems over the past five to ten years, according to four aspects, solubility, controlled release, in situ concentration, and targeting.

Transition Metal-mediated Uncaging Chemistry in Prodrug Design.

Uncaging chemistry catalyzed by transition metals is developed from deprotection reactions and metal-organic catalytic reactions. Also, it has the characteristics of high efficiency, simplicity and rapidity in the living biological system. In the past decade, metal encapsulation systems (such as nanoparticles) and metal complexes have been developed to reveal the reactivity of transition metals (including palladium, ruthenium, and gold) in biological systems. Metal nanostructures provide huge possibilities for targeted drug delivery, detection, diagnosis and imaging. So far, palladium, ruthenium and gold nano-architectures have dominated the field, but there are some problems that hinder their wide application in clinical practice. In this review, based on palladium, ruthenium, gold and their complexes, the application of prodrug design through uncaging reaction has been widely discussed.

Drug/Lead Compound Hydroxymethylation as a Simple Approach to Enhance Pharmacodynamic and Pharmacokinetic Properties.

Hydroxymethylation is a simple chemical reaction, in which the introduction of the hydroxymethyl group can lead to physical-chemical property changes and offer several therapeutic advantages, contributing to the improved biological activity of drugs. There are many examples in the literature of the pharmaceutical, pharmacokinetic, and pharmacodynamic benefits, which the hydroxymethyl group can confer to drugs, prodrugs, drug metabolites, and other therapeutic compounds. It is worth noting that this group can enhance the drug's interaction with the active site, and it can be employed as an intermediary in synthesizing other therapeutic agents. In addition, the hydroxymethyl derivative can result in more active compounds than the parent drug as well as increase the water solubility of poorly soluble drugs. Taking this into consideration, this review aims to discuss different applications of hydroxymethyl derived from biological agents and its influence on the pharmacological effects of drugs, prodrugs, active metabolites, and compounds of natural origin. Finally, we report a successful compound synthesized by our research group and used for the treatment of neglected diseases, which is created from the hydroxymethylation of its parent drug.

Pró-Fármacos dendriméricos potencialmente ativos em Malária e Tuberculose: Síntese e avaliação da atividade biológica / Dendrimeric prodrugs potentially active in malaria and tuberculosis: Synthesis and evaluation of biological activity

HIV/AIDS, tuberculose, malária e as doenças tropicais negligenciadas representam uma grande preocupação em Saúde em muitas regiões do mundo. Os fármacos disponíveis para o tratamento apresentam diversos problemas, tais como toxicidade e resistência ao parasita. Mesmo com esse triste panorama, o investimento em pesquisa nessa área é, ainda, pouco significativo. Assim, dentre os métodos de modificação molecular para melhorar propriedades farmacêuticas, farmacocinéticas e/ou farmacodinâmica de compostos bioativos destaca-se a latenciação. Já os dendrímeros vêm despertando interesse em aplicações biológicas, principalmente como transportadores de fármacos, além de atuarem como transportadores de genes, imagem em diagnóstico e compostos com ação per se. Face ao exposto e tendo em vista o caráter promissor dos dendrímeros como sistemas de drug delivery, o objetivo deste trabalho foi a síntese de pró-fármacos dendriméricos potencialmente ativos em malária e tuberculose. Os dendrímeros de Bis-MPA (gerações 0, 1 e 2) foram sintetizados pelo grupo do Professor Scott Grayson, da Tulane University (EUA). No Brasil, foram feitas as funcionalizações destes compostos, através do acoplamento do ácido succínico (que funciona como espaçante) e as moléculas ativas. Selecionaram-se as seguintes substâncias: (1) primaquina, com ação antimalárica e (2) isoniazida, de ação nos primeiros estágios da tuberculose. Foram sintetizados os pró-fármacos dendriméricos de isoniazida nas gerações 0 e 1 (G0-Iso e G1-Iso), e primaquina nas gerações 0, 1 e 2 (G0-Pq, G1-Pq e G2Pq). Importante mencionar que os resultados de Ressonância Magnética e Nuclear de 1H e de 13C demostraram as obtenções dos respectivos produtos, porém contendo impurezas. Já a análise do resultado proveniente da espectrometria de massas do composto G0-Iso revelou a presença de um subproduto ciclizado da isonizaida succinoilada (CIso-Suc), o qual pode ser um potencial pró-fármaco ou apresentar atividade per se. Como não se conhece este composto, o laboratório coordenado pela Profas Elizabeth Igne Ferreira e Jeanine Giarolla manifestou interesse em pesquisa-lo, principalmente quanto suas propriedades físico- químicas, bem como quanto à atividade biológica. Assim, utilizando metodologia analítica previamente estabelecida para o G0-Iso, os estudos de estabilidade química da CIso-Suc, em diferentes valores de pH, demonstraram a capacidade da forma ciclizada em se converter no protótipo Iso-Suc, majoritariamente em pH 7,4 e 8,5. Como perspectivas, destaca-se a avaliação da estabilidade enzimática deste potencial derivado. Ressalta-se, ainda, a a avaliação da respectiva atividade antimicobacteriana. Em relação aos pró-fármacos, as necessidades de aprimoramentos das sínteses são, também, evidenciadas. Uma vez sintetizados e caracterizados, estes últimos derivados serão avaliados quanto à atividade biológica. Ademais, estudos computacionais, sobretudo simulações de docking molecular, foram desenvolvidos com intuito de se entender o modo de interação de alguns compostos com alvos biológicos pré-determinados

HIV/AIDS, tuberculosis, malaria and neglected diseases are a major health concern in many regions of the world. The drugs available present various problems, such as toxicity and parasite resistance. Even with this sad outlook, research investment in this area is still insignificant. Among the molecular modification methods to improve the pharmaceutical, pharmacokinetic and/or pharmacodynamic properties we stands out prodrug design. On the other hand, dendrimers are arousing interest in biological applications, mainly as drug carriers, besides gene delivery, diagnostic imaging, as well as acting as compounds with activity per se. Considering that, added to the promising dendrimer drug delivery features, the aim of this study was to synthesize potentially active dendrimer prodrugs in malaria and tuberculosis. Bis-MPA dendrimers (generations 0, 1 and 2) were synthesized by the group of Professor Scott Grayson of Tulane University (USA). Herein in Brazil, the compounds were functionalized by coupling succinic acid (spacer group), as well as the active molecules. We selected the following substances: (1) primaquine, with antimalarial action and (2) isoniazid, acting in the early stages of tuberculosis. Isoniazid dendrimer prodrugs were synthesized generations 0 and 1 (G0-Iso and G1-Iso), and primaquine in generations 0, 1 and 2 (G0-Pq, G1-Pq and G2-Pq). It is important to mention that the results related to Nuclear and Magnetic Resonance 113C showed chemical structures features, however with impurities. Analysis of the mass spectrometry regarding G0-Iso has revealed the presence of a cyclized by-product of succinylated isonized (CIso-Suc), which may be a potential prodrug or may presentactivity itself. Using the analytical methodology performed for G0-Iso, ICso-Suc demonstrated its ability to convert the Iso-Suc prototype at different pH values, especially at pH 7.4 and 8.5. As perspectives, we highlight the determinations of the chemical stability of ICsoSuc at pH 1.5 and 6.0, as well as the evaluation of the enzymatic stability. We will also investigate the respective antimicobacterial activities. Regarding prodrugs, the needs for synthesis enhancements are also necessary. Once synthesized and characterized, these latter derivatives will be evaluated for biological activity. Moreover, computational studies, especially molecular docking simulations, were developed in order to understand the mode of interaction of some compounds with predetermined biological targets

Perspectives About Self-Immolative Drug Delivery Systems.

Self-immolative drug delivery system is one of the delivery systems, which have drawn attention, in recent research, highlighting the improvement they generate in drug selectivity and efficacy. Self-immolative linkers, or spacers, are covalent groups, which have the role of cleavaging two bonds between a protector group and a drug, in the case of drug delivery systems, after a stimuli.The cascade of reactions allows to control the release of the drug. The choice of the adequate self-immolative linker is essential and depend on many variables and goals as well. Many approaches can be explored when designing a system adequate for achieving these goals, especially prodrugs. Some of the most used stimuli-responses for self-immolative drugs - enzyme triggers, chemical triggers, as pH, redox system, 1,4-, 1,6-, 1,8-eliminations, photodegradable triggers, multiple triggers, among others - are described in this ten-year review, along with their application as theranostic agents. We intend that the examples presented in this review inspire researchers working on drug delivery systems to further explore their application.

Brain Delivery of Thyrotropin-Releasing Hormone via a Novel Prodrug Approach.

Using thyrotropin-releasing hormone (TRH) as a model, we explored whether synergistic combination of lipoamino acid(s) and a linker cleaved by prolyl oligopeptidase (POP) can be used as a promoiety for prodrug design for the preferential brain delivery of the peptide. A representative prodrug based on this design principle was synthesized, and its membrane affinity and in vitro metabolic stability, with or without the presence of a POP inhibitor, were studied. The in vivo formation of TRH from the prodrug construct was probed by utilizing the antidepressant effect of the peptide, as well as its ability to increase acetylcholine (ACh) synthesis and release. We found that the prototype prodrug showed excellent membrane affinity and greatly increased metabolic stability in mouse blood and brain homogenate compared to the parent peptide, yet a POP inhibitor completely prevented prodrug metabolism in brain homogenate. In vivo, administration of the prodrug triggered antidepressant-like effect, and microdialysis sampling showed greatly increased ACh release that was also antagonized upon a POP inhibitor treatment. Altogether, the obtained promising exploratory data warrant further investigations on the utility of the prodrug approach introduced here for brain-enhanced delivery of small peptides with neurotherapeutic potential.

Is prodrug design an approach to increase water solubility?

Water solubility has been identified as a critical parameter and the main responsible by affecting poor performance of oral drug delivery. Poorly soluble drugs can originate unsatisfactory ADME properties leading to low oral bioavailability, insufficient chemical stability, low half-life, fast pre-systemic metabolism and difficulties in formulation. In this context, the prodrug design is an alternative in order to improve physicochemical, biopharmaceutical and pharmacokinetic properties such as permeability, solubility, bioavailability, chemical stability and metabolism of molecules presenting poor drug-like properties. In this article we highlight the importance of the prodrug design in the early stages of drug discovery and development process, in an attempt to diminish the attrition rate and end up falling into the valley of death. Selected examples of this strategy are provided in this review and they are classified by some basic functional groups that are amenable to the prodrug approach with the aim of increasing aqueous solubility of poorly water-soluble compounds. Over the past decade, the number of approved prodrugs is considerable among all drugs launched in the market, emphasizing the importance of this tool on drug design. It is reported that 10% of all marketed drug worldwide can be classified as prodrugs. Furthermore, prodrugs designed to be more water soluble launched in the past decade are summarized in a table to have a closer look and finally state that the prodrug design is an amenable approach to increase water solubility.

Amino Acids in the Development of Prodrugs.

Although drugs currently used for the various types of diseases (e.g., antiparasitic, antiviral, antibacterial, etc.) are effective, they present several undesirable pharmacological and pharmaceutical properties. Most of the drugs have low bioavailability, lack of sensitivity, and do not target only the damaged cells, thus also affecting normal cells. Moreover, there is the risk of developing resistance against drugs upon chronic treatment. Consequently, their potential clinical applications might be limited and therefore, it is mandatory to find strategies that improve those properties of therapeutic agents. The development of prodrugs using amino acids as moieties has resulted in improvements in several properties, namely increased bioavailability, decreased toxicity of the parent drug, accurate delivery to target tissues or organs, and prevention of fast metabolism. Herein, we provide an overview of models currently in use of prodrug design with amino acids. Furthermore, we review the challenges related to the permeability of poorly absorbed drugs and transport and deliver on target organs.

Toxicity mechanism-based prodrugs: glutathione-dependent bioactivation as a strategy for anticancer prodrug design.

INTRODUCTION: 6-Mercaptopurine (6-MP) and 6-thioguanine (6-TG), two anticancer drugs, have high systemic toxicity due to a lack of target specificity. Therefore, increasing target selectivity should improve drug safety. Areas covered: The authors examined the hypothesis that new prodrug designs based upon mechanisms of kidney-selective toxicity of trichloroethylene would reduce systemic toxicity and improve selectivity to kidney and tumor cells. Two approaches specifically were investigated. The first approach was based upon bioactivation of trichloroethylene-cysteine S-conjugate by renal cysteine S-conjugate ß-lyases. The prodrugs obtained were kidney-selective but exhibited low turnover rates. The second approach was based on the toxic mechanism of trichloroethylene-cysteine S-conjugate sulfoxide, a Michael acceptor that undergoes rapid addition-elimination reactions with biological thiols. Expert opinion: Glutathione-dependent Michael addition-elimination reactions appear to be an excellent strategy to design highly efficient anticancer drugs. Targeting glutathione could be a promising approach for the development of anticancer prodrugs because cancer cells usually upregulate glutathione biosynthesis and/or glutathione S-transferases expression.

PEGylated prodrugs of antidiabetic peptides amylin and GLP-1.

Agonists of the glucagon-like peptide-1 (GLP-1) receptor and analogs of human amylin have been studied for almost two decades due to their therapeutic potential to treat diabetes mellitus and obesity. Both native peptides exhibit unfavorable pharmacokinetics. Even optimized analogs less prone to proteolysis have to be applied at least daily or once-weekly utilizing microsphere formulations or fusion to proteins. Thus, innovative approaches allowing tuning the drug levels to achieve beneficial therapeutic responses and prolonged application intervals are demanded. PEGylation, i.e., conjugation of polyethylene glycol (PEG), has enhanced the bioavailability of several drugs but does not appear to be useful for amylin and GLP-1. Thus, we developed a traceless prodrug strategy using protease-cleavable peptide linkers that can release therapeutic peptides. Specifically, the release kinetics of linker sequences LVPR, LDPR, and LVPRLVPR were tested in combination with GLP-1 analog taspoglutide, amylin, and amylin analog pramlintide in mouse serum. The linkers allowed tuning the taspoglutide release over more than one order of magnitude providing stable serum levels from ~0.08 to 3 µmol/L for ~20 h. Amylin and pramlintide levels were ~20 nmol/L and stable for at least 24 h. Importantly, all peptide therapeutics were protected against proteolytic degradation within the prodrug, especially the N-terminal sequences near the PEG. Thus, taspoglutide was released even after an incubation period of 24 h in serum with the content of degraded taspoglutide being below 2% in the prodrug at this time point. This PEG-prodrug technology could provide precisely tuned long-acting anti-diabetic and anti-obesity therapies and even once-monthly administration intervals when combined with other formulation strategies.

Synthesis, stability and activity of the prodrugs of dihydroorotate dehydrogenase inhibitors / 药学学报

This study was conducted to improve structural instability of a highly active DHODH inhibitor A found in our group. Twelve prodrugs were synthesized by modifying the carboxyl group. The enzyme activity test of 12 prodrugs A1−A12 demonstrated that A1−A5 displayed weak inhibitory activity, and A6−A12 displayed no activity, which met the action mechanism of designed prodrug. The structural stability of A1−A12 in methanol and pH 2.0, 9.0 buffers were tested, and the results showed that A12 could avoid intramolecular ring-formation in CH3OH, A1−A8 were easily hydrolyzed under acidic conditions, and A9−A12 were inclined to hydrolyze under alkaline conditions. The cell proliferation inhibitory activity of 12 prodrugs were evaluated, in which compound A12 displayed excellent activity (IC50=0.63 μmol·L−1) similar to brequinar. These results laid a good foundation for conducting further vivo studies.

Structure-based model profiles affinity constant of drugs with hPEPT1 for rapid virtual screening of hPEPT1's substrate.

The human proton-coupled peptide transporter (hPEPT1) with broad substrates is an important route for improving the pharmacokinetic performance of drugs. Thus, it is essential to predict the affinity constant between drug molecule and hPEPT1 for rapid virtual screening of hPEPT1's substrate during lead optimization, candidate selection and hPEPT1 prodrug design. Here, a structure-based in silico model for 114 compounds was constructed based on eight structural parameters. This model was built by the multiple linear regression method and satisfied all the prerequisites of the regression models. For the entire data set, the r(2) and adjusted r(2) values were 0.74 and 0.72, respectively. Then, this model was used to perform substrate/non-substrate classification. For 29 drugs from DrugBank database, all were correctly classified as substrates of hPEPT1. This model was also used to perform substrate/non-substrate classification for 18 drugs and their prodrugs; this QSAR model also can distinguish between the substrate and non-substrate. In conclusion, the QSAR model in this paper was validated by a large external data set, and all results indicated that the developed model was robust, stable, and can be used for rapid virtual screening of hPEPT1's substrate in the early stage of drug discovery.

Antichagásicos e leishmanicidas potenciais: estudo das condições de síntese de pró-fármacos dendriméricos de 3-hidroxiflavona / Potential antichagasic and leishmanicide compounds: study of synthesis conditions of 3-hydroxyflavone dendrimer prodrugs

INTRODUÇÃO: A doença de Chagas e a leishmaniose são doenças tropicais supernegligenciadas, que afetam regiões de extrema pobreza. Os fármacos disponíveis para estas duas doenças são escassos, de eficácia limitada, de alta toxicidade e suscitam casos de resistência. OBJETIVO: Considerando-se a necessidade de desenvolvimento de novos agentes antichagásicos e leishmanicidas, a importância da latenciação no aprimoramento de fármacos/compostos bioativos e a versatilidade de transportadores dendriméricos, o objetivo deste trabalho foi a síntese de pró-fármacos dendriméricos de primeira geração de 3-hidroxiflavona, composto que apresenta potencial atividade tripanomicida e leishmanicida. Desta forma, pretendeu-se obter liberação controlada, melhora da permeabilidade, toxicidade reduzida e aumento da eficácia deste agente bioativo. MATERIAL E MÉTODOS: Para a obtenção desses dendrímeros empregaram-se as abordagens divergente e convergente, compostas por várias etapas de síntese com reações de proteção, desproteção e acoplamentos. RESULTADOS E DISCUSSÃO: A abordagem convergente apresentou problemas sintéticos, devido à instabilidade dos derivados contendo 3-hidroxiflavona nas diferentes condições reacionais e de purificação testadas. No entanto, há indícios da síntese dos pró-fármacos dendriméricos de 3-hidroxiflavona, mas esses compostos apresentam-se impuros. Devido a essa instabilidade e a dificuldade de purificação na abordagem convergente, optou-se pela síntese divergente, no qual o composto bioativo é acoplado na etapa final. Os estudos sintéticos mostraram a obtenção dos intermediários puros formados pelos focos centrais propano- e hexano-diamina acoplados ao ácido málico protegido. CONCLUSÃO: Há indicativos da obtenção de pró-fármacos dendriméricos de 3-hidroxiflavona, ainda que impuros. As maiores dificuldades encontradas foram a purificação e a estabilidade dos compostos obtidos

INTRODUCTION: Chagas' disease and leishmaniasis are super neglected tropical diseases that affect primarily areas of extreme poverty. The drugs available for these diseases are scarce and of limited effectiveness, toxic and rouse resistance. OBJECTIVE: Considering that the development of new antichagasic and leishmanicide agents are urgently needed, the importance of prodrug design to the improvement of drugs and bioactive compounds and the versatility of dendrimers as drug carriers, the objective of this work was the synthesis of dendrimer prodrug of 3-hydroxyflavone, which shows potential antichagasic and leishmanicide activities. Thus, we intended to obtain controlled release, improvement of the permeability, reduction of the toxicity and increase of efficacy of this bioactive agent. MATERIAL AND METHODS: Convergent and divergent approaches have been used to synthesize those compounds. Synthetic steps consist of protection, deprotection and coupling reactions. RESULTS AND DISCUSSION: The convergent approach presented problems due to the instability of the 3-hydroxyflavone derivatives, in different reaction and purification conditions. However, there is evidence of the synthesis of dendrimer prodrugs, though still impure. Due to instability and purification difficulty of intermediate, we performed the divergent synthesis. We obtained the pure intermediates composed by cores propanediamine and hexanediamine coupled to the protected malic acid as spacer group. CONCLUSION: Synthetic studies suggested the synthesis of dendrimer prodrugs, although impure. The greatest difficulties were the purification and the instability of compounds

Targeted prodrug approaches for hormone refractory prostate cancer.

Due to the propensity of relapse and resistance with prolonged androgen deprivation therapy (ADT), there is a growing interest in developing non-hormonal therapeutic approaches as alternative treatment modalities for hormone refractory prostate cancer (HRPC). Although the standard treatment for HRPC consists of a combination of ADT with taxanes and anthracyclines, the clinical use of chemotherapeutics is limited by systemic toxicity stemming from nondiscriminatory drug exposure to normal tissues. In order to improve the tumor selectivity of chemotherapeutics, various targeted prodrug approaches have been explored. Antibody-directed enzyme prodrug therapy (ADEPT) and gene-directed enzyme prodrug therapy (GDEPT) strategies leverage tumor-specific antigens and transcription factors for the specific delivery of cytotoxic anticancer agents using various prodrug-activating enzymes. In prostate cancer, overexpression of tumor-specific proteases such as prostate-specific antigen (PSA) and prostate-specific membrane antigen (PSMA) is being exploited for selective activation of anticancer prodrugs designed to be activated through proteolysis by these prostate cancer-specific enzymes. PSMA- and PSA-activated prodrugs typically comprise an engineered high-specificity protease peptide substrate coupled to a potent cytotoxic agent via a linker for rapid release of cytotoxic species in the vicinity of prostate cancer cells following proteolytic cleavage. Over the past two decades, various such prodrugs have been developed and they were effective at inhibiting prostate tumor growth in rodent models; several of these prodrug approaches have been advanced to clinical trials and may be developed into effective therapies for HRPC.

Peptidophospholipids: synthesis, phospholipase A2 catalyzed hydrolysis, and application to development of phospholipid prodrugs.

New phospholipid analogues incorporating sn-2-peptide substituents have been prepared to probe the fundamental structural requirements for phospholipase A2 catalyzed hydrolysis of PLA2-directed synthetic substrates. Two structurally different antiviral oligopeptides with C-terminal glycine were introduced separately at the sn-2-carboxylic ester position of phospholipids to assess the role of the α-methylene group adjacent to the ester carbonyl in allowing hydrolytic cleavage by the enzyme. The oligopeptide-carrying phospholipid derivatives were readily incorporated into mixed micelles consisting of natural phospholipid (dipalmitoyl phosphatidylcholine, DPPC) and Triton X-100 as surfactant. Hydrolytic cleavage of the synthetic peptidophospholipids by the phospholipase A2 occurred slower, but within the same order of magnitude as the natural substrate alone. The results provide useful information toward better understanding the mechanism of action of the enzyme, and to improve the design and synthesis of phospholipid prodrugs targeted at secretory PLA2 enzymes.