Xinpeng Ma

A nanoparticle-based strategy for the imaging of a broad range of tumours by nonlinear amplification of microenvironment signals

Stimuli-responsive nanomaterials are increasingly important in a variety of applications such as biosensing, molecular imaging, drug delivery and tissue engineering. For cancer detection, a paramount challenge still exists in search of methods that can illuminate tumors universally regardless of their genotypes and phenotypes. Here we capitalized on the acidic, angiogenic tumor microenvironment to achieve broad detection of tumor tissues in a wide variety of mouse cancer models. This was accomplished using ultra-pH sensitive fluorescent nanoprobes that have tunable, exponential fluorescence activation upon encountering subtle, physiologically relevant pH transitions. These nanoprobes were silent in the circulation, then dramatically activated (>300 fold) in response to neovasculature or to the low extracellular pH in tumors. Thus, we have established non-toxic, fluorescent nanoreporters that can non-linearly amplify tumor microenvironmental signals, permitting identification of tumor tissue independently of histological type or driver mutation, and detection of acute treatment responses much more rapidly than conventional imaging approaches.

Ultra-pH-sensitive nanoprobe library with broad pH tunability and fluorescence emissions.

pH is an important physiological parameter that plays a critical role in cellular and tissue homeostasis. Conventional small molecular pH sensors (e.g., fluorescein, Lysosensor) are limited by broad pH response and restricted fluorescent emissions. Previously, we reported the development of ultra-pH-sensitive (UPS) nanoprobes with sharp pH response using fluorophores with small Stokes shifts (<40 nm). In this study, we expand the UPS design to a library of nanoprobes with operator-predetermined pH transitions and wide fluorescent emissions (400–820 nm). A copolymer strategy was employed to fine tune the hydrophobicity of the ionizable hydrophobic block, which led to a desired transition pH based on standard curves. Interestingly, matching the hydrophobicity of the monomers was critical to achieve a sharp pH transition. To overcome the fluorophore limitations, we introduced copolymers conjugated with fluorescence quenchers (FQs). In the micelle state, the FQs effectively suppressed the emission of fluorophores regardless of their Stokes shifts and further increased the fluorescence activation ratios. As a proof of concept, we generated a library of 10 nanoprobes each encoded with a unique fluorophore. The nanoprobes cover the entire physiologic range of pH (4–7.4) with 0.3 pH increments. Each nanoprobe maintained a sharp pH transition (on/off < 0.25 pH) and high fluorescence activation ratio (>50-fold between on and off states). The UPS library provides a useful toolkit to study pH regulation in many pathophysiological indications (e.g., cancer, lysosome catabolism) as well as establishing tumor-activatable systems for cancer imaging and drug delivery.

Multi-chromatic pH-activatable 19F-MRI nanoprobes with binary ON/OFF pH transitions and chemical-shift barcodes

Magnetic resonance imaging (MRI) is a powerful noninvasive imaging technique that has greatly impacted basic biological research as well clinical diagnosis of cancer and other diseases.[1] Conventional MR contrast agents are T1 (e.g. Gd-DTPA) or T2-based (e.g. iron oxide), which cause significant longitudinal or transverse relaxation of protons, respectively.[2] Despite their success in many biological applications, one potential limitation is the lack of multi-chromatic features that allows for simultaneous detection of multiple signals. Recently, 19F has received significant attention in MR imaging and spectroscopy studies.[3] Compared to 1H-MRI, 19F-MRI has little biological background due to the low levels of endogenous fluorine in the body. Moreover, 19F has 100% natural abundance and its gyromagnetic ratio (40.06 MHz/T) is second only to 1H, which makes it more sensitive for detection over other nuclei.[3f]

Esterase-activatable β-lapachone prodrug micelles for NQO1-targeted lung cancer therapy

UNLABELLED Lung cancer is one of the most lethal forms of cancer and current chemotherapeutic strategies lack broad specificity and efficacy. Recently, β-lapachone (β-lap) was shown to be highly efficacious in killing non-small cell lung cancer (NSCLC) cells regardless of their p53, cell cycle and caspase status. Pre-clinical and clinical use of β-lap (clinical form, ARQ501 or 761) is hampered by poor pharmacokinetics and toxicity due to hemolytic anemia. Here, we report the development and preclinical evaluation of β-lap prodrug nanotherapeutics consisting of diester derivatives of β-lap encapsulated in biocompatible and biodegradable poly(ethylene glycol)-b-poly(D,L-lactic acid) (PEG-b-PLA) micelles. Compared to the parent drug, diester derivatives of β-lap showed higher drug loading densities inside PEG-b-PLA micelles. After esterase treatment, micelle-delivered β-lap-dC3 and -dC6 prodrugs were converted to β-lap. Cytotoxicity assays using A549 and H596 lung cancer cells showed that both micelle formulations maintained NAD(P)H quinone oxidoreductase 1 (NQO1)-dependent cytotoxicity. However, antitumor efficacy study of β-lap-dC3 micelles against orthotopic A549 NSCLC xenograft-bearing mice showed significantly greater long-term survival over β-lap-dC6 micelles or β-lap-HPβCD complexes. Improved therapeutic efficacy of β-lap-dC3 micelles correlated with higher area under the concentration-time curves of β-lap in tumors, and enhanced pharmacodynamic endpoints (e.g., PARP1 hyperactivation, γH2AX, and ATP depletion). β-Lap-dC3 prodrug micelles provide a promising strategy for NQO1-targeted therapy of lung cancer with improved safety and antitumor efficacy.

A transistor-like pH nanoprobe for tumour detection and image-guided surgery

Because of profound genetic and histological differences in cancerous tissue, it is challenging to detect a broad range of malignant tumours at high resolution. Here, we report the design and performance of a fluorescent nanoprobe with transistor-like responses (transition pH = 6.9) for the detection of the deregulated pH that drives many of the invasive properties of cancer. The nanoprobe amplifies fluorescence signal in the tumour over that in the surrounding normal tissues, resulting in a discretized, binary output signal with spatial resolution smaller than 1 mm. The nanoprobe allowed us to image a broad range of tumours in mouse models using a variety of clinical cameras, and to perform real-time tumour-acidosis-guided detection and surgery of occult nodules (< 1 mm3) in mice bearing head-and-neck or breast tumours, significantly lengthening mice survivability. We also show that the pH nanoprobe can be used as a reporter in a fast, quantitative assay to screen for tumour-acidosis inhibitors. The binary delineation of pH achieved by the nanoprobe promises to improve the accuracy of cancer detection, surveillance and therapy.

Chaotropic-anion-induced supramolecular self-assembly of ionic polymeric micelles.

Traditional micelle self-assembly is driven by the association of hydrophobic segments of amphiphilic molecules forming distinctive core-shell nanostructures in water. Here we report a surprising chaotropic-anion-induced micellization of cationic ammonium-containing block copolymers. The resulting micelle nanoparticle consists of a large number of ion pairs (≈60,000) in each hydrophobic core. Unlike chaotropic anions (e.g. ClO4(-)), kosmotropic anions (e.g. SO4(2-)) were not able to induce micelle formation. A positive cooperativity was observed during micellization, for which only a three-fold increase in ClO4(-) concentration was necessary for micelle formation, similar to our previously reported ultra-pH-responsive behavior. This unique ion-pair-containing micelle provides a useful model system to study the complex interplay of noncovalent interactions (e.g. electrostatic, van der Waals, and hydrophobic forces) during micelle self-assembly.

Prodrug strategy to achieve lyophilizable, high drug loading micelle formulations through diester derivatives of β-Lapachone.

β-Lap prodrug micelle strategy improves the formulation properties of β-lap therapeutics. The resulting micelles yield apparent high β-lap solubility (>7 mg mL(-1) ), physical stability, and ability to reconstitute after lyophilization. In the presence of esterase, β-lap prodrugs are efficiently converted into parent drug (i.e., β-lap), resulting in NQO1-dependent lethality of NSCLC cells.

Nanotechnology-enabled delivery of NQO1 bioactivatable drugs

Abstract Current cancer chemotherapy lacks specificity and is limited by undesirable toxic side-effects, as well as a high rate of recurrence. Nanotechnology has the potential to offer paradigm-shifting solutions to improve the outcome of cancer diagnosis and therapy. β-Lapachone (β-lap) is a novel anticancer agent whose mechanism of action is highly dependent on NAD(P)H:quinone oxidoreductase 1 (NQO1), a phase II detoxifying enzyme overexpressed in solid tumors from a variety of cancer types. However, the poor water solubility of β-lap limits its clinical potential. A series of drug formulations were developed for systemic administration in preclinical evaluations. Encapsulation of β-lap into polymeric micelles showed less side-effects and higher maximum tolerated dose (MTD), prolonged blood circulation time and preferential accumulation in tumors with greatly improved safety and antitumor efficacy. The prodrug strategy of β-lap further decreases the crystallization of β-lap by introducing esterase degradable side chains to the rigid fused ring structure. β-Lap prodrugs considerably increased the stability, drug-loading content and delivery efficiency of nanoparticles. The optimized formulation of β-lap-dC3 prodrug micelles showed excellent antitumor efficacy in treating orthotopic non-small cell lung tumors that overexpress NQO1, with target validation using pharmacodynamic endpoints.

Digitization of Endocytic pH by Hybrid Ultra‐pH‐Sensitive Nanoprobes at Single‐Organelle Resolution

A multispectral hybrid nanotransistor consisting of modular fluorescent block copolymers with discrete and sharp pH transitions in one nanoparticluate system is presented. This nanotransistor probe allows digitized reporting of dynamic maturation at single-organelle resolution over time. This nanotechnology platform offers a powerful tool in fundamental studies of organelle biology, cell signaling in diseases characterized by pH dysregulation in the endosomes or lysosomes.

Chapter 2:Targeted Nanomedicines: Challenges and Opportunities

Cancer is one of the leading public health risks in the world. In the United States alone, one in four deaths is caused by this disease. A total of over 1.6 million new cancer cases and 0.58 million deaths are expected in 2012.1 Current cancer treatments include surgical resection, radiation therapy...