Noufal Kandoth

An engineered nanoplatform for bimodal anticancer phototherapy with dual-color fluorescence detection of sensitizers

A multifunctional nanoplatform with four-in-one photoresponsive functionalities has been achieved through the co-encapsulation of two chromo-fluorogenic components within biocompatible polymeric nanoparticles. This engineered nanoconstruct efficiently delivers different photosensitizers in melanoma cells, which can be detected through their dual-color fluorescence, and induces amplified cell mortality due to the simultaneous photogeneration of singlet oxygen and nitric oxide.

A Cyclodextrin‐Based Nanoassembly with Bimodal Photodynamic Action

We have developed a supramolecular nanoassembly capable of inducing remarkable levels of cancer cell mortality through a bimodal action based on the simultaneous photogeneration of nitric oxide (NO) and singlet oxygen ((1)O(2)). This was achieved through the appropriate incorporation of an anionic porphyrin (as (1)O(2) photosensitizer) and of a tailored NO photodonor in different compartments of biocompatible nanoparticles based on cationic amphiphilic cyclodextrins. The combination of steady-state and time-resolved spectroscopic techniques showed the absence of significant intra- and interchromophoric interaction between the two photoactive centers embedded in the nanoparticles, with consequent preservation of their photodynamic properties. Photodelivery of NO and (1)O(2) from the nanoassembly on visible light excitation was unambiguously demonstrated by direct and real-time monitoring of these transient species through amperometric and time-resolved infrared luminescence measurements, respectively. The typical red fluorescence of the porphyrin units was essentially unaffected in the bichromophoric nanoassembly, allowing its localization in living cells. The convergence of the dual therapeutic action and the imaging capacities in one single structure makes this supramolecular architecture an appealing, multifunctional candidate for applications in biomedical research.

Photoinduced Fluorescence Activation and Nitric Oxide Release with Biocompatible Polymer Nanoparticles

A viable strategy to encapsulate a fluorophore/photochrome dyad and a nitric oxide photodonor within supramolecular assemblies of a cyclodextrin-based polymer in water was developed. The two photoresponsive guests do not interact with each other within their supramolecular container and can be operated in parallel under optical control. Specifically, the dyad permits the reversible switching of fluorescence on a microsecond timescale for hundreds of cycles, and the photodonor enables the irreversible release of nitric oxide. Furthermore, these supramolecular assemblies cross the membrane of human melanoma cancer cells and transport their cargo in the cytosol. The fluorescence of one component allows the visualization of the labeled cells, and its switchable character could, in principle, be used to acquire super-resolution images, while the release of nitric oxide from the other induces significant cell mortality. Thus, our design logic for the construction of biocompatible nanoparticles with dual functionality might evolve into the realization of valuable photoresponsive probes for imaging and therapeutic applications.

Two-photon fluorescence imaging and bimodal phototherapy of epidermal cancer cells with biocompatible self-assembled polymer nanoparticles.

We have developed herein an engineered polymer-based nanoplatform showing the convergence of two-photon fluorescence imaging and bimodal phototherapeutic activity in a single nanostructure. It was achieved through the appropriate choice of three different components: a β-cyclodextrin-based polymer acting as a suitable carrier, a zinc phthalocyanine emitting red fluorescence simultaneously as being a singlet oxygen ((1)O2) photosensitizer, and a tailored nitroaniline derivative, functioning as a nitric oxide (NO) photodonor. The self-assembly of these components results in photoactivable nanoparticles, approximately 35 nm in diameter, coencapsulating a multifunctional cargo, which can be delivered to carcinoma cells. The combination of steady-state and time-resolved spectroscopic and photochemical techniques shows that the two photoresponsive guests do not interfere with each other while being enclosed in their supramolecular container and can thus be operated in parallel under control of light stimuli. Specifically, two-photon fluorescence microscopy allows mapping of the nanoassembly, here applied to epidermal cancer cells. By detecting the red emission from the phthalocyanine fluorophore it was also possible to investigate the tissue distribution after topical delivery onto human skin ex vivo. Irradiation of the nanoassembly with visible light triggers the simultaneous delivery of cytotoxic (1)O2 and NO, resulting in an amplified cell photomortality due to a combinatory effect of the two cytotoxic agents. The potential of dual therapeutic photodynamic action and two-photon fluorescence imaging capability in a single nanostructure make this system an appealing candidate for further studies in biomedical research.

A polymer-based nanodevice for the photoregulated release of NO with two-photon fluorescence reporting in skin carcinoma cells

We have developed a multifunctional biocompatible nanoconstruct based on polymeric nanoparticles encapsulating a molecular conjugate, able to photorelease nitric oxide (NO) with a fluorescent reporting function. We demonstrate that two-photon excitation (TPE) using biofriendly NIR 700 nm laser light can be applied for monitoring as well as triggering the release of NO, wherein the uncaging of a strongly fluorescent co-product acts in turn as a TPE fluorescent reporter for the simultaneous NO release from the nanoassembly. This supramolecular nanodevice internalizes in skin carcinoma cells, induces significant cell death upon light excitation and preserves its TPE properties, allowing the nearly instantaneous quantification of the NO photoreleased in cancer cells by two-photon NIR fluorescence microscopy.

A host-guest supramolecular complex with photoregulated delivery of nitric oxide and fluorescence imaging capacity in cancer cells.

Herein we report the design, preparation, and properties of a supramolecular system based on a tailored nitric oxide (NO) photodonor and a rhodamine-labeled β-cyclodextrin conjugate. The combination of spectroscopic and photochemical experiments shows the absence of significant interchromophoric interactions between the host and the guest in the excited states. As a result, the complex is able to release NO under the exclusive control of visible light, as unambiguously demonstrated by direct detection of this transient species through an amperometric technique, and exhibits the typical red fluorescence of the rhodamine appendage. The supramolecular complex effectively internalizes in HeLa cancer cells as proven by fluorescence microscopy, shows a satisfactory biocompatibility in the dark, and induces about 50% of cell mortality upon irradiation with visible light. The convergence of all these properties in one single complex makes the present host-guest ensemble an appealing candidate for further delevopment of photoactivatable nanoscaled systems addressed to photostimulated NO-based therapy.

Cyclodextrin-based nanoconstructs for photoactivated therapies

The achievement of nanovehicles able to release therapeutic agents in a controlled fashion is a major challenge in the burgeoning field of nanomedicine. Light represents the most elegant and non-invasive trigger to deliver bio-active compounds on demand since it allows the accurate control of three key factors determining the positive therapeutic outcome such as site, timing and dosage. Monomeric and aggregate forms of both natural and modified cyclodextrins (CDs) offer useful biocompatible scaffolds to bind suitable phototherapeutic agents preserving, in most cases, their photochemical properties. In this contribution we shall illustrate some representative examples of photoresponsive CD-based nanoassemblies achieved in others and our laboratories in recent years, underlying the logical design and highlighting the potential applications in some major areas, such as photodynamic, photothermal and nitric oxide-stimulated therapy.

Gold nanoparticles decorated with a photoactivable nitric oxide donor/cyclodextrin host/guest complex

Hybrid gold nanoclusters exhibiting photoregulated release of nitric oxide are obtained by appropriate self-assembling of a suitable host, a photoactivable guest and Au nanoparticles. The excitation of the core, the shell or both components of the nanoclusters with visible light, together with their dark stability and water solubility, make these nanoarchitectures intriguing candidates to be tested in biomedical research studies.

Layer-by-layer assembled gold nanoparticles with a tunable payload of a nitric oxide photocage

We report herein the design, preparation and characterisation of a new, water soluble, nanoplatform for the light-triggered release of nitric oxide (NO). This nanoconstruct has been achieved by exploiting a layer-by-layer approach to assembly a polyelectrolyte modified with a NO photochemical precursor, around citrate stabilized gold colloidal template. Combined spectroscopic and transmission electron microscopy analysis show that the layered hybrid nanoparticles remain stable under physiological conditions without any significant clustering along the different coating processes. The photochemical properties of the NO photocage are well preserved upon its covalent grafting in the polymeric skeleton, before and after the of the metal colloids. The direct and in real time monitoring of NO using an ultrasensitive electrode unambiguously shows the light-stimulated NO release from modified gold nanoparticles and demonstrates that the approach used permits the accurate regulation of the NO reservoir on the nanoparticles surface.

Nitric oxide photoreleasing nanoconstructs with multiple photofunctionalities

Nitric oxide (NO) has become one of the most studied molecules in the fascinating realm of the biomedical sciences over the last two decades, owing to its multifaceted role in a variety of physiological and pathophysiological processes. This has made the development of new strategies and methods for generating NO in a controlled fashion a hot topic in the burgeoning field of nanomedicine, with the exciting prospect to tackle important diseases. This paper illustrates very recent advances in the fabrication of multifunctional nanoconstructs which combine the photoregulated release of NO with additional fluorescence imaging and phototherapeutic modalities. Representative examples, including metal and supramolecular complexes, molecular conjugates, nanoparticles and thin films, will be described, highlighting the rationale design and their potential relevance in biomedical research.