Potentiation of ovarian OCa-1 tumor radioresponse by poly (L-glutamic acid)-paclitaxel conjugate

Contrasting Properties of Polymeric Nanocarriers for MRI-Guided Drug Delivery

Poor pharmacokinetics and low aqueous solubility combined with rapid clearance from the circulation of drugs result in their limited effectiveness and generally high therapeutic doses. The use of nanocarriers for drug delivery can prevent the rapid degradation of the drug, leading to its increased half-life. It can also improve the solubility and stability of drugs, advance their distribution and targeting, ensure a sustained release, and reduce drug resistance by delivering multiple therapeutic agents simultaneously. Furthermore, nanotechnology enables the combination of therapeutics with biomedical imaging agents and other treatment modalities to overcome the challenges of disease diagnosis and therapy. Such an approach is referred to as "theranostics" and aims to offer a more patient-specific approach through the observation of the distribution of contrast agents that are linked to therapeutics. The purpose of this paper is to present the recent scientific reports on polymeric nanocarriers for MRI-guided drug delivery. Polymeric nanocarriers are a very broad and versatile group of materials for drug delivery, providing high loading capacities, improved pharmacokinetics, and biocompatibility. The main focus was on the contrasting properties of proposed polymeric nanocarriers, which can be categorized into three main groups: polymeric nanocarriers (1) with relaxation-type contrast agents, (2) with chemical exchange saturation transfer (CEST) properties, and (3) with direct detection contrast agents based on fluorinated compounds. The importance of this aspect tends to be downplayed, despite its being essential for the successful design of applicable theranostic nanocarriers for image-guided drug delivery. If available, cytotoxicity and therapeutic effects were also summarized.

A hindsight reflection on the clinical studies of poly(l-glutamic acid)-paclitaxel

Chemotherapy for cancer treatment is limited by the excessive toxicity to normal tissues. The design of chemodrug-loaded nanoformulations provides a unique approach to improve the treatment efficacy while minimizing toxicity. Despite the numerous publications of nanomedicine for the last several decades, however, only a small fraction of the developed nanoformulations have entered clinical trials, with even fewer being approved for clinical application. Poly(l-glutamic acid)-paclitaxel (PG-TXL) belongs to the few formulations that reached phase III clinical trials. Unfortunately, the development of PG-TXL stopped in 2016 due to the inability to show significant improvement over current standard care. This review will provide an overview of the preclinical and clinical evaluations of PG-TXL, and discuss lessons to be learned from this ordeal. The precise identification of suitable patients for clinical trial studies, deep understanding of the mechanisms of action, and an effective academic-industry partnership throughout all phases of drug development are important for the successful bench-to-bedside translation of new nanoformulations. This article is categorized under: Implantable Materials and Surgical Technologies > Nanomaterials and Implants Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease Biology-Inspired Nanomaterials > Peptide-Based Structures.

Synthetic nanoparticles for delivery of radioisotopes and radiosensitizers in cancer therapy

Radiotherapy has been, and will continue to be, a critical modality to treat cancer. Since the discovery of radiation-induced cytotoxicity in the late 19th century, both external and internal radiation sources have provided tremendous benefits to extend the life of cancer patients. Despite the dramatic improvement of radiation techniques, however, one challenge persists to limit the anti-tumor efficacy of radiotherapy, which is to maximize the deposited dose in tumor while sparing the rest of the healthy vital organs. Nanomedicine has stepped into the spotlight of cancer diagnosis and therapy during the past decades. Nanoparticles can potentiate radiotherapy by specifically delivering radionuclides or radiosensitizers into tumors, therefore enhancing the efficacy while alleviating the toxicity of radiotherapy. This paper reviews recent advances in synthetic nanoparticles for radiotherapy and radiosensitization, with a focus on the enhancement of in vivo anti-tumor activities. We also provide a brief discussion on radiation-associated toxicities as this is an area that, up to date, has been largely missing in the literature and should be closely examined in future studies involving nanoparticle-mediated radiosensitization.

Glutamic acid and its derivatives: candidates for rational design of anticancer drugs

Throughout the history of human civilizations, cancer has been a major health problem. Its treatment has been interesting but challenging to scientists. Glutamic acid and its derivative glutamine are known to play interesting roles in cancer genesis, hence, it was realized that structurally variant glutamic acid derivatives may be designed and developed and, might be having antagonistic effects on cancer. The present article describes the state-of-art of glutamic acid and its derivatives as anticancer agents. Attempts have been made to explore the effectivity of drug-delivery systems based on glutamic acid for the delivery of anticancer drugs. Moreover, efforts have also been made to discuss the mechanism of action of glutamic acid derivatives as anticancer agents, clinical applications of glutamic acid derivatives, as well as recent developments and future perspectives of glutamic acid drug development have also been discussed.

Targeted imaging of tumor-associated M2 macrophages using a macromolecular contrast agent PG-Gd-NIR813

Tumor-associated macrophages (TAMs) are diverse population containing multiple subtypes. M2 macrophages promote tumor growth and metastasis, in part by secreting a wide range of proangiogenic factors and growth factors. Selective depletion of M2 macrophages has been evaluated as a novel approach to anti-cancer therapy. In this study, a dual magneto-optical imaging probe, PG-Gd-NIR813 was synthesized and evaluated for non-invasive assessment of TAMs after intravenous injection. PG-Gd-NIR813 injected in nude rats bearing C6 tumors showed high uptake of the polymeric contrast agent in the tumor at 1 and 48 h after injection both in vivo and ex vivo optical imaging. T(1)-weighted MR imaging results showed accumulation of PG-Gd-NIR813 into the tumor necrotic area, which was confirmed by TUNEL staining of resected tumors. The uptake of PG-Gd-NIR813 within tumor necrosis decreased after animals were treated by the macrophage-depleting agent. Immunohistochemical staining demonstrated that PG-Gd-NIR813 colocalized with CD68 (marker for macrophages) and CD169 (marker for activated macrophages), but not with CD163 (residential macrophages). Using combined near-infrared fluorescence imaging and magnetic resonance imaging (MRI), we demonstrated that the accumulation of PG-Gd-NIR813 in tumors was mediated through M2 TAMs. Therefore, poly(L-glutamic acid) based reagents could be potentially used to image response to antitumor therapies targeted at M2 TAMs. Furthermore, poly(L-glutamic acid) is a promising carrier for candidate immunotherapeutics targeting M2 TAMs.

Polymer-drug conjugates: recent development in clinical oncology

Targeted drug delivery aims to increase the therapeutic index by making more drug molecules available at the diseased sites while reducing systemic drug exposure. In this update, we provide an overview of polymer-drug conjugates that have advanced into clinical trials. These systems use synthetic water-soluble polymers as the drug carriers. The preclinical pharmacology and recent data in clinical trials with poly(l-glutamic acid)-paclitaxel (PG-TXL) are discussed. This is followed by a summary of a variety of polymeric conjugates with chemotherapeutic agents. Results from early clinical trials of these polymer-drug conjugates have demonstrated several advantages over the corresponding parent drugs, including fewer side effects, enhanced therapeutic efficacy, ease of drug administration, and improved patient compliance. Collectively, these data warrant further clinical development of polymer-drug conjugates as a new class of anticancer agents.

Design, synthesis and applications of hyaluronic acid-paclitaxel bioconjugates

Paclitaxel (1a), a well known antitumor agent adopted mainly for the treatment of breast and ovarian cancer, suffers from significant disadvantages such as low solubility, certain toxicity and specific drug-resistance of some tumor cells. To overcome these problems extensive research has been carried out. Among the various proposed strategies, the conjugation of paclitaxel (1a) to a biocompatible polymer, such as hyaluronic acid (HA, 2), has also been considered. Coupling a bioactive compound to a biocompatible polymer offers, in general, many advantages such as better drug solubilization, better stabilization, specific localization and controlled release. Hereafter the design, synthesis and applications of hyaluronic acid-paclitaxel bioconjugates are reviewed. An overview of HA-paclitaxel combinations is also given.

Paclitaxel: a review of adverse toxicities and novel delivery strategies

Better known as Taxol (Bristol-Myers Squibb), paclitaxel is the first member of the taxane family to be used in cancer chemotherapy. The taxanes exert their cytotoxic effect by arresting mitosis through microtubule stabilization, resulting in cellular apoptosis. The use of paclitaxel as a chemotherapeutic agent has become a broadly accepted option in the treatment of patients with ovarian, breast and non-small cell lung cancers, malignant brain tumors, and a variety of other solid tumors. However, significant toxicities, such as myelosuppression and peripheral neuropathy, limit the effectiveness of paclitaxel-based treatment regimens. This review addresses the toxicities associated with paclitaxel treatment and describes existing and future strategies of paclitaxel administration directed at limiting these toxicities.

Phase I study of CT-2103, a polymer-conjugated paclitaxel, and carboplatin in patients with advanced solid tumors

PURPOSE

The primary objective of this study was to determine the maximum tolerated dose (MTD) of CT-2103 (poly L-glutamic acid-paclitaxel) in combination with carboplatin in patients with histologically proven solid tumors that were either refractory to conventional treatment or for which no conventional therapy was available.

PATIENTS AND METHODS

Twenty-two adult patients with advanced solid tumors were treated in this dose escalation study. Patients were treated every 21 days with CT-2103 at 175, 210, 225, or 250 mg/m2 (doses expressed as units of conjugated-paclitaxel) via 10-20 minute intravenous (IV) infusion, followed one hour later with carboplatin administered at AUC 5 or 6 via 30 minute IV infusion. No prophylaxis for hypersensitivity was administered with initial treatment. Doses were administered every 21 days until progressive disease or dose-limiting toxicity (DLT) was observed. Toxicity was evaluated using NCI Common Toxicity Criteria for Adverse Events v2.0 (CTCAE v2.0); response to treatment was evaluated using Response Criteria in Solid Tumors (RECIST).

RESULTS

The MTD was determined to be 225 mg/m2. DLTs observed at 250 mg/m2 were neutropenia and thrombocytopenia. No hypersensitivity reactions were observed. Three patients achieved partial responses (PR). Fifteen patients received at least 3 cycles of treatment without observation of progressive disease. Median survival time was 5.9 months. Patients that demonstrated partial responses were all ovarian cancer patients that had previously failed paclitaxel therapy. The only Grade 4, nonhematologic treatment-related toxicity was febrile neutropenia. Grade 4 neutropenia (9 patients) was observed across all dose groups. Twelve patients developed thrombocytopenia (Grade 3/4) while receiving combination therapy. All had resolution of thrombocytopenia with discontinuation of carboplatin, suggesting that carboplatin, and not CT-2103, contributed mainly to platelet toxicity.

CONCLUSION

CT-2103 administered at 225 mg/m2 every 21 days in combination with carboplatin administered at AUC 6 has a manageable safety profile in patients with solid tumors; further clinical investigation is recommended, especially in patients with ovarian or non-small cell lung cancer.

Novel formulations of taxanes: a review. Old wine in a new bottle?

Over the past two decades, the taxanes have played a significant role in the treatment of various malignancies. However, the poor solubility of these compounds necessitates the inclusion of surfactant vehicles in their commercial formulations. Cremophor EL and polysorbate 80 have long comprised the standard solvent system for paclitaxel and docetaxel, respectively. A number of pharmacologic and biologic effects related to both of these drug formulations have been described, including clinically relevant acute hypersensitivity reactions and peripheral neuropathy. In addition, these solvents affect the disposition of intravenously administered solubilized drugs and leach plasticizers from polyvinylchloride infusion sets. A number of strategies to develop formulations of surfactant-free taxanes have been developed. They include albumin nanoparticles, polyglutamates, taxane analogs and prodrugs, emulsions, and lipsomes. An overview of these novel formulations of taxanes, their mechanisms of action, pharmacokinetics, dose and administration, adverse effects, and clinical efficacy will be discussed.

CT-2103: emerging utility and therapy for solid tumours

CT-2103 (XYOTAX, Cell Therapeutics, Inc.) is a conjugate of paclitaxel to a polyglutamate polymer. Its macromolecular nature exploits enhanced permeability and retention in tumour tissues. This compound is stable and inactive in aqueous solution and undergoes predominantly intracellular metabolism at the site where active paclitaxel is released. Because it does not require a Cremophor EL vehicle, it can be administered by short infusion into peripheral veins. In preclinical models, compared with the same dose of unconjugated paclitaxel in Cremophor EL-ethanol, CT-2103 yields >or= 12-fold increase in area under the curve in both plasma and tumour tissue. This alteration in drug pharmacokinetics and biodistribution is attributable to the ability of macromolecules to concentrate in areas of vascular leakiness, such as tumour tissue. CT-2103 is taken up by both tumour cells and normal phagocytic cells and is transported to lysosomes, where it is released by specific proteases through enzymatic action. In syngeneic and xenogeneic tumour models, at the maximally tolerated dose, CT-2103 appears to be more active than the standard doses of paclitaxel. It has also demonstrated activity in paclitaxel-resistant tumour models. Its potential enhancement of efficacy and decrease in drug-related toxicities make this agent an attractive option for therapeutic investigation. In Phase I trials it has been relatively well-tolerated, with acceptable toxicity at doses <or= 225 mg/m(2) every 3 weeks. In combination with carboplatin the maximum tolerated dose is 235 mg/m(2) and the recommended Phase II dose 210 mg/m(2). Activity has been demonstrated in both non-small cell lung carcinoma (NSCLC) and in ovarian cancer, Phase III studies are currently testing this agent versus standard paclitaxel as maintenance therapy for first-line treatment-naive ovarian cancer. In addition, CT-2103 at a dose of 210 mg/m(2) (performance status [PS] 0 - 1) or 175 mg/m(2) (PS 2) is being compared with docetaxel (75 mg/m(2)) for the second-line treatment of NSCLC. In front-line PS 2 NSCLC patients, this agent in combination with carboplatin is undergoing comparison with paclitaxel/carboplatin; in a separate effort, single-agent CT-2103 is being compared with either gemcitabine or vinorelbine. These studies will determine whether the preclinical and early clinical promise of this agent can be realised in the clinical treatment of solid tumours.

Poly(L-glutamic acid)-paclitaxel conjugate is a potent enhancer of tumor radiocurability

PURPOSE

Conjugating drugs with polymeric carriers is one way to improve selective delivery to tumors. Poly (L-glutamic acid)-paclitaxel (PG-TXL) is one such conjugate. Compared with paclitaxel, its uptake, tumor retention, and antitumor efficacy are increased. Initial studies showed that PG-TXL given 24 h before or after radiotherapy enhanced tumor growth delay significantly more than paclitaxel. To determine if PG-TXL-induced enhancement is obtained in a more clinically relevant setting, we investigated PG-TXL effects on tumor cure.

METHODS AND MATERIALS

Mice bearing 7-mm-diameter ovarian carcinomas were treated with PG-TXL at an equivalent paclitaxel dose of 80 mg/kg, single dose or 5 daily fractions of radiation or both PG-TXL and radiation. Treatment endpoint was TCD(50) (radiation dose yielding tumor control in 50% of mice). Acute radioresponse of jejunum, skin, and hair was determined for all treatments.

RESULTS

PG-TXL dramatically improved tumor radioresponse, reducing TCD(50) of single-dose irradiation from 53.9 (52.2-55.5) Gy to 7.5 (4.5-10.7) Gy, an enhancement factor (EF) of 7.2. The drug improved the efficacy of fractionated irradiation even more, reducing the TCD(50) of 66.6 (62.8-90.4) Gy total fractionated dose to only 7.9 (4.3-11.5) Gy, for an EF of 8.4. PG-TXL did not affect normal tissue radioresponse resulting from either single or fractionated irradiation.

CONCLUSION

PG-TXL dramatically potentiated tumor radiocurability after single-dose or fractionated irradiation without affecting acute normal tissue injury. To our knowledge, PG-TXL increased the therapeutic ratio of radiotherapy more than that previously reported for other taxanes, thus, PG-TXL has a high potential to improve clinical radiotherapy.

Chemoradiotherapy: emerging treatment improvement strategies

BACKGROUND

The use of chemotherapeutic drugs in combination with radiotherapy has become a common strategy for the treatment of advanced cancer. Solid evidence exists showing that chemotherapy administered during the course of radiotherapy (concurrent chemoradiotherapy) increases both local tumor control and patient survival in a number of cancer sites, including head and neck cancer. These therapy improvements, however, have been achieved at the expense of considerable toxicity, which underscores the need for further improvements.

METHODS

The current status of chemoradiotherapy clinical trials for head and neck cancer and research on the emerging treatment improvements were reviewed. A review of potential treatment improvement strategies focused on preclinical investigations on newer chemotherapeutic agents, notably taxanes and nucleoside analogues, as well as on molecular targets such as epidermal growth factor receptor (EGFR) or cyclooxygenase-2 (COX-2) enzyme.

RESULTS

Concurrent, but not induction (drugs given before radiotherapy), chemoradiotherapy improves locoregional tumor control and survival benefit in head and neck carcinoma relative to radiotherapy alone. In comparison, both concurrent and induction chemoradiotherapy showed therapeutic advantage over radiotherapy alone in the treatment of lung cancer. These therapeutic improvements were achieved with standard chemotherapeutic drugs, most commonly cisplatin-based chemotherapy. Biologically, chemotherapy interacts with radiation through a number of mechanisms, including inhibition of cellular repair, cell cycle effects, and inhibition of tumor cell regeneration. Potential avenues emerged to further improve chemoradiotherapy. One of these involves the newer chemotherapeutic agents, taxanes and nucleoside analogues, which in preclinical studies exhibited strong tumor radiosensitization and therapeutic gain. The clinical benefit of these agents is currently under testing. Another approach for improvement of chemoradiotherapy consists of inhibiting molecules selectively or preferentially expressed on tumor cells, such as EGFR and COX-2, both shown to render cellular resistance to drugs or radiation. Agents that selectively inhibit these molecules are becoming available at a rapid rate, and many of them have been shown in preclinical testing to be highly effective in improving tumor radioresponse or chemoresponse without affecting normal tissues.

CONCLUSIONS

Concurrent chemoradiotherapy, using standard chemotherapeutic agents, has emerged as an effective treatment for advanced cancer, but unfortunately at the expense of considerable increase in normal tissue toxicity. There are a number of potential emerging treatment strategies to further improve chemoradiotherapy. One consists of using newer chemotherapeutic drugs, which in preclinical studies are potent enhancers of tumor radioresponse. Another approach consists of targeting EGFR or COX-2 with selective inhibitors of these molecules.

Poly(L-glutamic acid)--anticancer drug conjugates

Chemotherapy has had limited success in the treatment of cancer over the years, due, in part, to the untoward toxicity of the therapeutic agent to normal cells. The design of tailor-made polymer conjugates provides a synthetic approach that can overcome some of the problems. Several synthetic polymer-based anticancer drug conjugates have entered clinical studies. This report reviews the chemistry, physicochemical properties, and therapeutic applications in cancer therapy of polymeric chemotherapeutic agents based on poly(L-glutamic acid). Targeted delivery of anticancer agents using poly(L-glutamic acid) as the drug carrier is also discussed with emphasis on the design of innovative polymeric constructs.

Potentiation of radioresponse by polymer-drug conjugates

Although combined chemotherapy and radiotherapy has produced significantly improved response and survival rates among cancer patients, there is still a compelling need to establish the most effective way to deliver these agents. We hypothesize that the radiosensitizing effect of a chemotherapeutic agent can be further enhanced if the drug is delivered at an optimal concentration and is maintained in the tumor for a prolonged period. Using a water-soluble poly(L-glutamic acid)-conjugated paclitaxel (PG-TXL) as a model compound, we investigated whether paclitaxel delivered by means of polymeric carrier could increase the tumor's response to radiation. Mice bearing 8-mm syngeneic ovarian carcinoma OCa-1 tumors implanted intramuscularly were treated with i.v. injected PG-TXL alone or in combination with single doses of local radiation. The enhancement factors at 24 h interval, as measured by incremental tumor growth delay compared with radiation alone, ranged from 2.48 to 4.28. The values varied as a function of radiation dose. The enhancement of radioresponse is also a function of time interval between injection of PG-TXL and tumor irradiation. The enhancement factor increased with decreasing interval, suggesting that radiation may in turn mediate the sensitivity of tumor toward PG-TXL. Thus, the mechanism of PG-TXL's radiopotentiation activity is probably multifactorial. Remarkably, while combined radiation and TXL produced additive or even sub-additive interaction when radiation preceded TXL injection, combined radiation and PG-TXL produced synergistic interaction in a mammary MCa-4 tumor model. Radiation significantly increased tumor uptake of PG-TXL, suggesting a potential role of radiation-modulated antitumor activity of polymeric drugs. Our data support a treatment strategy combining radiation and polymeric chemotherapy that may have important clinical implications in terms of scheduling and optimization of the therapeutic ratio.