Nanoparticles are currently being investigated in a number of human clinical trials. As information on how nanoparticles function in humans is difficult to obtain, animal studies that can be correlative to human behavior are needed to provide guidance for human clinical trials. Here, we report correlative studies on animals and humans for CRLX101, a 20-to 30-nm-diameter, multifunctional, polymeric nanoparticle containing camptothecin (CPT). CRLX101 is currently in phase 2 clinical trials, and human data from several of the clinical investigations are compared with results from multispecies animal studies. The pharmacokinetics of polymer-conjugated CPT (indicative of the CRLX101 nanoparticles) in mice, rats, dogs, and humans reveal that the area under the curve scales linearly with milligrams of CPT per square meter for all species. Plasma concentrations of unconjugated CPT released from CRLX101 in animals and humans are consistent with each other after accounting for differences in serum albumin binding of CPT. Urinary excretion of polymer-conjugated CPT occurs primarily within the initial 24 h after dosing in animals and humans. The urinary excretion dynamics of polymer-conjugated and unconjugated CPT appear similar between animals and humans. CRLX101 accumulates into solid tumors and releases CPT over a period of several days to give inhibition of its target in animal xenograft models of cancer and in the tumors of humans. Taken in total, the evidence provided from animal models on the CRLX101 mechanism of action suggests that the behavior of CRLX101 in animals is translatable to humans.nanomedicine | clinical translation | interspecies scaling | pharmacodynamics | Nanoparticles
Small interfering RNA (siRNA) therapeutics have potential advantages over traditional small molecule drugs such as high specificity and the ability to inhibit otherwise "undruggable" targets. However, siRNAs have short plasma half-lives in vivo, can induce a cytokine response, and show poor cellular uptake. Formulating siRNA into nanoparticles offers two advantages: enhanced siRNA stability against nuclease degradation beyond what chemical modification alone can provide; and improved site-specific delivery that takes advantage of the enhanced permeability and retention (EPR) effect. Existing delivery systems generally suffer from poor delivery to tumors. Here we describe the formation and biological activity of polymeric nanopharmaceuticals (PNPs) based on biocompatible and biodegradable poly(lactic-co-glycolic acid) (PLGA) conjugated to siRNA via an intracellular cleavable disulfide linker (PLGA-siRNA). Additionally, these PNPs contain (1) PLGA conjugated to polyethylene glycol (PEG) for enhanced pharmacokinetics of the nanocarrier; (2) a cation for complexation of siRNA and charge compensation to avoid high negative zeta potential; and (3) neutral poly(vinyl alcohol) (PVA) to stabilize the PNPs and support the PEG shell to prevent particle aggregation and protein adsorption. The biological data demonstrate that these PNPs achieve prolonged circulation, tumor accumulation that is uniform throughout the tumor, and prolonged tumor-specific knockdown. PNPs employed in this study had no effect on body weight, blood cell count, serum chemistry, or cytokine response at doses >10 times the effective dose. PNPs, therefore, constitute a promising solution for achieving durable siRNA delivery and gene silencing in tumors.
Novel nanoparticle–drug conjugates (NDCs) containing diverse, clinically relevant anticancer drug payloads (docetaxel, cabazitaxel, and gemcitabine) were successfully generated and tested in drug discovery studies. The NDCs utilized structurally varied linkers that attached the drug payloads to a β-cyclodextrin–PEG copolymer to form self-assembled nanoparticles. In vitro release studies revealed a diversity of release rates driven by linker structure–activity relationships (SARs). Improved in vivo pharmacokinetics (PK) for the cabazitaxel (CBTX) NDCs with glycinate-containing (1c) and hexanoate-containing linkers (2c) were demonstrated, along with high and sustained tumor levels (>168 h of released drug in tumor tissues). This led to potent efficacy and survival in both taxane- and docetaxel-resistant in vivo anticancer mouse efficacy models. Overall, the CBTX-hexanoate NDC 2c (CRLX522), demonstrated optimal and improved in vivo PK (plasma and tumor) and efficacy profile versus those of the parent drug, and the results support the potential therapeutic use of CRLX522 as a new anticancer agent.
Cerulean Pharma Inc.'s Dynamic Tumor Targeting™ Platform creates nanoparticle-drug conjugates (NDCs) designed to significantly mitigate a payload's limitations by providing sustained drug delivery to the tumor and superior therapeutic index through controlled release kinetics. By conjugating drug payloads to our novel β-cyclodextrin-PEG copolymer through linker strategies that allow modulation of release and pharmacokinetics (PK), we provide advantages over entrapped nanoparticle strategies, e.g., polymeric nanoparticles and liposomes. Cerulean has two NDCs in the clinic, CRLX101 and CRLX301, evidencing the translatability of our technology. CRLX101 has been dosed in over 350 patients and CRLX301 is in an ongoing Phase 1/2a trial. Our Dynamic Tumor Targeting Platform is applicable to a diverse range of drug payload possibilities, including small molecules with a host of physiochemical properties, i.e., hydrophobic and hydrophilic payloads, and functional groups with chemical handles for conjugation. To illustrate the capabilities of our platform we will present the biological impact of a series of cabazitaxel-containing NDCs with linkers encompassing a diversity of in vitro release rates. In vivo PK studies showed high and sustained levels of released drug in tumor tissues (>168 hrs), and in vivo mouse tumor model studies demonstrated vastly improved efficacy, i.e., tumor regression and significant tumor growth delay, and survival over separately dosed cabazitaxel including efficacy in a taxane-resistant tumor model. Cerulean continues to expand its platform through the development of new and emerging capabilities to treat patients living with cancer. In this regard, we also will address the future evolution of NDCs, including the conjugation of multiple payloads to a single NDC and the development of antibody-conjugated NDCs. This abstract is also being presented as Poster B43. Citation Format: Chester Metcalf, III, Derek van der Poll, Liang Zhao, Tiffany Halo, Doug Lazarus, Adam Stockmann, Christian Peters, Donna Brown, Roy Case, Ellen Rohde, Lata Jayaraman, Hongwei Wang, Tiffany Crowell, Adrian Senderowicz, Scott Eliasof. Significant improvements in therapeutic index for conjugated payloads using a nanoparticle-drug conjugate (NDC) platform to provide sustained drug release and potentially improved anticancer effects. [abstract]. In: Proceedings of the AACR Special Conference on Engineering and Physical Sciences in Oncology; 2016 Jun 25-28; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2017;77(2 Suppl):Abstract nr PR10.
CRLX101, an investigational nanoparticle-drug conjugate (NDC) containing the payload camptothecin, is currently being clinically evaluated in multiple treatment-refractory solid tumors. In preclinical models, CRLX101 is believed to release camptothecin in the tumor in a slow and prolonged manner due to its long circulation half-life. CRLX101 has been shown preclinically to be a dual inhibitor of topoisomerase 1 and hypoxia-inducible factor 1α. It has demonstrated striking anti-tumor activity in several different tumor models. Camptothecin itself was identified as an active anti-tumor agent preclinically but was not developed clinically due to its poor tolerability in patients. The development of CRLX101, which has not shown significant toxicity in over 300 patients to date, offers a unique opportunity to improve cancer treatment in a meaningful way. We hypothesized that CRLX101 utilizes the enhanced permeability and retention (EPR) effect to accumulate selectively in tumors. In this study, we sought to mechanistically dissect the process of CRLX101 entry and accumulation into tumor cells using multiple methods, both in vitro and in xenograft tumors in vivo. Using confocal microscopy, we detected camptothecin fluorescence in CRLX101-treated tumor cells in culture as well as in tumor tissue from mice treated with CRLX101. We can co-localize this camptothecin with intact nanoparticles using an anti-PEG antibody that specifically detects the PEG loops in the NDCs. More recently, we have shown that camptothecin and anti-PEG co-localize specifically in tumors of patients treated with CRLX101 but not in adjoining normal tissue. We can also demonstrate that macropinocytosis and activation of actin polymerization play a role in the process by which tumor cells take up CRLX101. Using an anti-CD31 antibody, we can visualize the distance traversed by CRLX101 from the tumor vasculature over time. We have developed novel analytical methods to precisely quantify both released and CRLX101-conjugated camptothecin over time in CRLX101 treated tumor cells in vitro, as well as in tumor tissue from mice treated with CRLX101 in vivo. Using cell viability assays, we can correlate the kinetics of camptothecin released inside tumor cells to the degree of tumor cell kill. We believe that these data are an important step forward in understanding the precise mechanism(s) underlying selective delivery of CRLX101 into tumor tissue. Citation Format: Christian G. Peters, Douglas Lazarus, Donna Brown, Ningning Zhang, Adam P. Stockmann, Roy Case, Ellen Rohde, Scott Eliasof, Lata Jayaraman. Tumor selective localization of CRLX101, an investigational nanoparticle-drug conjugate of camptothecin. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 1345.
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