Polymer conjugation is an efficient approach to improve the delivery of drugs and biological agents, both by protecting the body from the drug (by improving biodistribution and reducing toxicity) and ...by protecting the drug from the body (by preventing degradation and enhancing cellular uptake). This review discusses the journey that polymer therapeutics make through the body, following the ADME (absorption, distribution, metabolism, excretion) concept. The biological factors and delivery system parameters that influence each stage of the process will be described, with examples illustrating the different solutions to the challenges of drug delivery systems in vivo.
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Polymer therapeutics have shown promise as tumor-targeted drug delivery systems in mice. The multivalency of polymers allows the attachment of different functional agents to a polymeric backbone, ...including chemotherapeutic and antiangiogenic drugs, as well as targeting moieties, such as the bone-targeting agent alendronate (ALN). We previously reported the conjugation of ALN and the chemotherapeutic drug paclitaxel (PTX) with N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer. The in vitro physicochemical properties, cancer cytotoxicity and antiangiogenic activity of HPMA copolymer–PTX–ALN conjugate were extensively characterized. The reported results warranted in vivo evaluations of the conjugate. In this manuscript, we evaluated the in vivo anticancer and antiangiogenic activity of HPMA copolymer–PTX–ALN conjugate. The conjugate exhibited an antiangiogenic effect by decreasing microvessel density (MVD), and inducing apoptotic circulating endothelial cells (CEC) following treatment of the mice. Using intravital imaging system and mCherry-labeled breast cancer cell lines, we were able to monitor noninvasively the progression of orthotopic metastatic tumors injected into the tibia of the mice. HPMA copolymer–PTX–ALN conjugate showed the greatest antitumor efficacy on mCherry-labeled 4T1 mammary adenocarcinoma inoculated into the tibia, as compared with PTX alone or in combination with ALN. Treatment with the bone-targeted polymeric conjugate demonstrated improved efficacy, was better tolerated, and was more easily administered intravenously than the clinically used PTX formulated in Cremophor/ethanol.
BackgroundCAR T cell activity in solid tumors is limited by off-tumor toxicity, antigen heterogeneity, poor persistence, and functional suppression resulting from the tumor microenvironment (TME). To ...address these challenges, we have developed AB-1015, an autologous, integrated circuit T (ICT) cell product for the potential treatment of ovarian cancer. The AB-1015 DNA cassette includes two functional modules: an ’AND’ logic gate targeting ALPG/P and MSLN designed to limit off-tumor toxicity through dual tumor antigen recognition, and a dual shRNA-miR targeting FAS and PTPN2 to resist TME suppression and to improve ICT cell function. The AB-1015 DNA cassette is inserted into the T cell genome at a defined genomic site, GS94, via CRISPR integration of transgenes by electroporation (CITE).MethodsThe dual-antigen specificity of AB-1015 was evaluated in vivo using a dual flank tumor xenograft model where one tumor expressed both ALPG and MSLN, and the contralateral tumor expressed MSLN alone. To model priming antigen heterogeneity that AB-1015 may encounter in the tumor, we utilized an admixed co-culture system where varying proportions of ALPG+MSLN+ target cells were spiked into cultures that were otherwise MSLN+. In addition, AB-1015 anti-tumor activity and the capability to overcome TME were also assessed in vivo using an intraperitoneal OVCAR3 ovarian xenograft model and a subcutaneous MSTO-FASL xenograft model.ResultsAB-1015 demonstrated specific activity against ALPG+MSLN+ tumors but had no effect against MSLN+ tumors in the in vivo dual flank specificity model. In the in vitro heterogeneity assay, AB-1015 was able to eliminate admixed co-cultures where as few as 5% of the target cells expressed ALPG+MSLN+. In the intraperitoneal OVCAR3 ovarian xenograft model, AB-1015 showed potent anti-tumor activity as demonstrated by decrease in bioluminescent signal from the tumors treated with AB-1015. Furthermore, in the subcutaneous MSTO-FASL xenograft model, AB-1015 could resist FASL suppression via shRNA knockdown of FAS. As a result, AB-1015 is capable of completely clearing these otherwise difficult-to-treat tumors in this model.ConclusionsAB-1015 is specific for ALPG/P+MSLN+, demonstrates superior potency compared with logic gated T cells alone, and is resistant to ovarian TME suppression in preclinical studies. Based on these promising preclinical data, AB-1015 is being studied in a phase I clinical trial (NCT05617755).
Non-small cell lung cancer (NSCLC) metastatic to the brain leptomeninges is rapidly fatal, cannot be biopsied, and cancer cells in the cerebrospinal fluid (CSF) are few; therefore, available tissue ...samples to develop effective treatments are severely limited. This study aimed to converge single-cell RNA-seq and cell-free RNA (cfRNA) analyses to both diagnose NSCLC leptomeningeal metastases (LM), and to use gene expression profiles to understand progression mechanisms of NSCLC in the brain leptomeninges. NSCLC patients with suspected LM underwent withdrawal of CSF via lumbar puncture. Four cytology-positive CSF samples underwent single-cell capture (n = 197 cells) by microfluidic chip. Using robust principal component analyses, NSCLC LM cell gene expression was compared to immune cells. Massively parallel qPCR (9216 simultaneous reactions) on human CSF cfRNA samples compared the relative gene expression of patients with NSCLC LM (n = 14) to non-tumor controls (n = 7). The NSCLC-associated gene, CEACAM6, underwent in vitro validation in NSCLC cell lines for involvement in pathologic behaviors characteristic of LM. NSCLC LM gene expression revealed by single-cell RNA-seq was also reflected in CSF cfRNA of cytology-positive patients. Tumor-associated cfRNA (e.g., CEACAM6, MUC1) was present in NSCLC LM patients' CSF, but not in controls (CEACAM6 detection sensitivity 88.24% and specificity 100%). Cell migration in NSCLC cell lines was directly proportional to CEACAM6 expression, suggesting a role in disease progression. NSCLC-associated cfRNA is detectable in the CSF of patients with LM, and corresponds to the gene expression profile of NSCLC LM cells. CEACAM6 contributes significantly to NSCLC migration, a hallmark of LM pathophysiology.
BackgroundIn solid tumors, CAR T cell efficacy is limited by off-tumor toxicity and suppression by the tumor microenvironment (TME). AB-X is an integrated circuit T cell (ICT cell) intended for the ...treatment of ovarian cancer. AB-X includes a transgene cassette with two functional modules: 1) an ”AND” logic gate designed to limit off-tumor toxicity through dual tumor antigen recognition; 2) a dual shRNA-miR to resist TME suppression and improve ICT cell function. The AB-X logic gate consists of a priming receptor that induces expression of an anti-mesothelin (MSLN) CAR upon engagement of a ALPG/P (alkaline phosphatase germ-line/placental). The dual shRNA-miR mediates downregulation of FAS and PTPN2. The AB-X DNA cassette is inserted into the T cell genome at a defined novel genomic site via CRISPR-based gene editing.MethodsDual-antigen specificity of the logic gate was assessed in mice harboring MSLN+ and ALPG/P+MSLN+ K562 tumors established on contralateral flanks. Potency was measured in a subcutaneous MSTO xenograft model. Logic-gated ICT cells were compared with MSLN CAR T cells in both models. In vitro, expansion of ICT cells with the FAS/PTPN2 shRNA-miR was evaluated in a 14 day repetitive stimulation assay (RSA). In vivo, expansion and potency were measured in the MSTO xenograft model. An in vitro FAS cross-linking assay was conducted to assess the impact of FAS knockdown on FAS-mediated apoptosis.ResultsLogic-gated ICT cells demonstrated specific activity against ALPG/P+MSLN+ tumors, but had no effect against MSLN+ tumors in the K562 in vivo specificity model. In addition, logic-gated ICT cells demonstrated greater in vivo potency than MSLN CAR T cells in the MSTO xenograft model. In our RSA, ICT cells containing the FAS/PTPN2 shRNA-miR had 8-fold greater expansion than the MSLN CAR T cells. Enhanced expansion was confirmed in vivo with ICT cells demonstrating >10-fold expansion in tumors and peripheral blood, enabling comparable growth inhibition in MSTO xenografts at less than one quarter the dose of the MSLN CAR T cells. Importantly, PTPN2 knockdown resulted in balanced expansion of all T cell subsets, including CD45RA+, CCR7+ memory cells. Lastly, ICT cells containing the FAS/PTPN2 shRNA-miR were resistant to FAS-mediated apoptosis.ConclusionsAB-X ICT cells specifically recognize ALPG/P+MSLN+ tumors, demonstrate superior potency, expansion, and persistence compared with MSLN CAR T cells, and are resistant to ovarian TME suppression. AB-X will be evaluated in clinical trials for treatment of platinum resistant/refractory ovarian cancer.AcknowledgementsWe would like to acknowledge all of our colleagues at Arsenal Biosciences, without whom this work would not have been possible.
RNA interference is one of the most promising fields in modern medicine to treat several diseases, ranging from cancer to cardiac diseases, passing through viral infections and metabolic pathologies. ...Since the discovery of the potential therapeutic properties of non-self oligonucleotides, it was clear that it is important to develop delivery systems that are able to increase plasma stability and bestow membrane-crossing abilities to the oligonucleotides in order to reach their cytoplasmic targets. Polymer therapeutics, among other systems, are widely investigated as delivery systems for therapeutic agents, such as oligonucleotides. Physico-chemical characterization of the supramolecular polyplexes obtained upon charge interaction or covalent conjugation between the polymeric carrier and the oligonucleotides is critical. Appropriate characterization is fundamental in order to predict and understand the in vivo silencing efficacy and to avoid undesired side effects and toxicity profile. Shedding light on the physico-chemical and in vitro requirements of a polyplex leads to an efficient in vivo delivery system for RNAi therapeutics. In this review, we will present the most common techniques for characterization of obtained polymer/oligonucleotide polyplexes and an up-to-date state of the art in vivo preclinical and clinical studies. This is the first review to deal with the difficulties in appropriate characterization of small interfering RNA (siRNA) or microRNA (miRNA) polyplexes and conjugates which limit the clinical translation of this promising technology.
Small interfering RNA (siRNA) can silence the expression of a targeted gene in a process known as RNA interference (RNAi). As a consequence, RNAi has immense potential as a novel therapeutic approach ...in cancer targeted therapy. However, successful application of siRNA for therapeutic purposes is challenging due to its rapid renal clearance, degradation by RNases in the bloodstream, poor cellular penetration, immunogenicity and aggregation in the blood. In addition, the few oligonucleotide-based nanomedicines that reached clinical trials either go to the liver following systemic administration or are applied topically. Treatment of solid tumors requires selective distribution of siRNA to the target tissue, hence there is an unmet medical need for an efficacious and safe nano-sized delivery system for their clinical use. To overcome these hurdles, we have designed, synthesized and physico-chemically characterized a novel nanocarrier based on aminated poly(α)glutamate (PGAamine). This cathepsin B-biodegradable polymer interacts electrostatically with the siRNA to form a nano-sized polyplex stable in plasma. Treatment with PGAamine-Rac1 siRNA polyplex (siRac1-polyplex) caused specific gene silencing by 80% in HeLa and SKOV-3 human ovarian adenocarcinoma cells as opposed to PGAamine-control non-targeting siRNA polyplex (siCtrl-polyplex) leading to inhibition of cell migration and wound healing abilities. A stepwise dose escalation was performed in order to determine the in vivo maximum tolerated dose (MTD). This was followed by intraperitoneal administration of siRac1-polyplex to mCherry-labeled ovarian adenocarcinoma-bearing mice leading to preferred tumor accumulation of siRac1 (8-fold) which resulted in 38% Rac1 knockdown. Furthermore, the polyplex was administered intravenously to lung carcinoma-bearing mice in which it caused 33% Rac1 knockdown. These promising results led to efficacy studies administering systemic treatment with an anticancer siRNA, siPlk1-polyplex, which inhibited tumor growth by 73% and 87% compared with siCtrl-polyplex or saline-treated mice, respectively, leading to prolonged overall survival. These findings represent the first time that a polyaminated poly(α)glutamate polymer is used for an efficacious and safe tumor delivery of RNAi following systemic administration.
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Abstract Paclitaxel (PTX) and alendronate (ALN) are effective drugs used for the treatment of breast cancer bone metastases. Growing evidence suggests that low-dose taxanes and bisphosphonates ...possess anti-angiogenic properties. However, PTX is water-insoluble and toxic, even if administered at anti-angiogenic dosing schedule. Polymer conjugation of PTX will increase water-solubility and improve its pharmacokinetic profile directing it to the tumor site. We further propose to combine it with ALN for active bone targeting. We conjugated ALN and PTX with poly(ethylene glycol) (PEG) forming self-assembled micelles where PTX molecules are located at the inner core and the water-soluble ALN molecules at the outer shell. PTX–PEG–ALN micelles exhibited similar in vitro cytotoxic and anti-angiogenic activity as the free drugs. Biodistribution analysis demonstrated preferential tumor accumulation of FITC-labeled PTX–PEG–ALN micelles. Pharmacokinetic studies revealed longer t1/2 of the conjugate than free PTX. PTX–PEG–ALN micelles achieved improved efficacy and safety profiles over free PTX in syngeneic and xenogeneic mouse models of mCherry-infected mammary adenocarcinoma in the tibia, as monitored intravitally non-invasively by a fluorescence imaging system. The described data warrants the potential use of PTX–PEG–ALN as bone-targeted anticancer and anti-angiogenic therapy for breast cancer bone metastases.