Reporter nanoparticle that monitors its anticancer efficacy in real time

Kulkarni, Ashish; Rao, P. Raja Ramana; Natarajan, Siva Kumar; Goldman, Aaron; Sabbisetti, Venkata; Khater, Yashika; Korimerla, Navya; Chandrasekar, Vineethkrishna; Mashelkar, R. A.; Sengupta, Shiladitya

doi:10.1073/pnas.1603455113

Cited by 68 publications

(64 citation statements)

References 80 publications

(87 reference statements)

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“…In vivo studies have tested a range of particle sizes, mostly less than 300 nm, and particles with both positive and negative zeta potentials for various applications. Material composition and surface modifications have been shown to contribute significantly in selective targeting, efficient delivery and active stimulation of immune system targets [35, 41, 43-66]. Thus, these investigations, including a wide array of nanoparticles for cancer immunotherapy, substantiate the employment of nanocarriers for efficacious cancer immunotherapies.…”

Section: Alternate Targeting Strategiesmentioning

confidence: 99%

“…For non-specific immunotherapy, the enhanced delivery of certain adjuvants, such as cytokines, can be achieved with the help of nanoparticles to boost the immune response in conjunction with other cancer immunotherapies. Nanoparticles also benefit from theranostic applications including delivery of imaging agents along with the therapeutic moieties to diagnose and track the treatment [41, 42]. …”

Section: Introductionmentioning

confidence: 99%

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Nanoparticle Design Strategies for Effective Cancer Immunotherapy

et al. 2017

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Cancer immunotherapy is a rapidly evolving and paradigm shifting treatment modality that adds a strong tool to the collective cancer treatment arsenal. It can be effective even for late stage diagnoses and has already received clinical approval. Tumors are known to not only avoid immune surveillance but also exploit the immune system to continue local tumor growth and metastasis. Because of this, most immunotherapies, particularly those directed against solid cancers, have thus far only benefited a small minority of patients. Early clinical substantiation lends weight to the claim that cancer immunotherapies, which are adaptive and enduring treatment methods, generate much more sustained and robust anticancer effects when they are effectively formulated in nanoparticles or scaffolds than when they are administered as free drugs. Engineering cancer immunotherapies using nanomaterials is, therefore, a very promising area worthy of further consideration and investigation. This review focuses on the recent advances in cancer immunoengineering using nanoparticles for enhancing the therapeutic efficacy of a diverse range of immunotherapies. The delivery of immunostimulatory agents to antitumor immune cells, such as dendritic or antigen presenting cells, may be a far more efficient tactic to eradicate tumors than delivery of conventional chemotherapeutic and cytotoxic drugs to cancer cells. In addition to its immense therapeutic potential, immunoengineering using nanoparticles also provides a valuable tool for unearthing and understanding the basics of tumor biology. Recent research using nanoparticles for cancer immunotherapy has demonstrated the advantage of physicochemical manipulation in improving the delivery of immunostimulatory agents. In vivo studies have tested a range of particle sizes, mostly less than 300 nm, and particles with both positive and negative zeta potentials for various applications. Material composition and surface modifications have been shown to contribute significantly in selective targeting, efficient delivery and active stimulation of immune system targets. Thus, these investigations, including a wide array of nanoparticles for cancer immunotherapy, substantiate the employment of nanocarriers for efficacious cancer immunotherapies.

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Section: Alternate Targeting Strategiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nanoparticle Design Strategies for Effective Cancer Immunotherapy

et al. 2017

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“…Uncovering the biological and physical mechanisms that impact the ability of specific cells to associate with, and subsequently internalize, nanoparticles is necessary for informed nanoparticle design (1,2,7). The ability to reliably deliver nanoparticles to a target cell population such that the nanoparticles are rapidly internalized has the potential to transform disease treatment and diagnosis (34)(35)(36). However, the journey between nanoparticle creation and cellular internalisation is convoluted, and involves a multitude of intertwined biological, physical and chemical processes (1-4, 7).…”

Section: Discussionmentioning

confidence: 99%

Isolating the sources of heterogeneity in nanoparticle-cell interactions

Johnston

Faria

Crampin

2019

Preprint

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Nanoparticles have the potential to enhance therapeutic success and reduce toxicitybased treatment side effects via the targeted delivery of drugs to cells. This delivery relies on complex interactions between numerous biological, chemical and physical processes. The intertwined nature of these processes has thus far hindered attempts to understand their individual impact. Variation in experimental data, such as the number of nanoparticles inside each cell, further inhibits understanding. Here we present a mathematical framework that is capable of examining the impact of individual processes during nanoparticle delivery. We demonstrate that variation in experimental nanoparticle uptake data can be explained by three factors: random nanoparticle motion; variation in nanoparticle-cell interactions; and variation in the maximum nanoparticle uptake per cell. Without all three factors, the experimental data cannot be explained. This work provides insight into biological mechanisms that cause heterogeneous responses to treatment, and enables precise identification of treatment-resistant cell subpopulations.

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“…[ 22 ] Moreover, direct anatomical measurements involved in evaluating the RECIST criteria such as computed tomography (CT), magnetic resonance imaging (MRI), and fluorodeoxyglucose–positron emission tomography (FDG–PET) lack sensitivity and specificity to detect early response measurements. [ 23 ] Even though blood plasma concentrations of cytokines have been used to monitor disease progression, lack of standardization and reproducibility makes it a less robust tool when it comes to clinical settings, hence clinical usage of cytokine expression remains uncertain. [ 24 ] Histological analysis of disease progression provides concrete validation for immunological efficacy, but this is often limited to in situ carcinomas that are easily accessible.…”

Section: Figurementioning

confidence: 99%

A Nitric Oxide (NO) Nanoreporter for Noninvasive Real‐Time Imaging of Macrophage Immunotherapy

et al. 2020

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Macrophage‐centered therapeutic approaches that rely on immune modulation of tumor associated macrophages (TAMs) from a pro‐tumorigenic phenotype (M2) to an anti‐tumorigenic phenotype (M1) have facilitated a paradigm shift in macrophage immunotherapy. However, limited clinical success has been achieved due to the low response rates observed in different types of cancers. The ability to measure immune response in real time is critical in order to differentiate responders from non‐responders; however, there are currently no platforms to monitor real‐time macrophage immunotherapy response. Hence, there is an immediate need to develop imaging techniques that can longitudinally monitor macrophage immunotherapy response. Nitric oxide (NO) produced as a result of activation of macrophages to an anti‐tumorigenic state is considered as a hallmark of M1 and can be a direct indication of response. In this study, a NO nanoreporter (NO‐NR) is reported that enables real‐time monitoring of macrophage immunotherapy drugs in vitro and in vivo. Furthermore, it is observed that sustained inhibition of colony stimulating factor 1 receptor (CSF1R) using a CSF1R inhibitor–NO‐NR system leads to enhanced efficacy and better imaging signal. In conclusion, a first‐of‐its‐kind NO nanoreporter tool is reported that can be used as an activatable imaging agent to monitor macrophage immunotherapy response in real time.

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Reporter nanoparticle that monitors its anticancer efficacy in real time

Cited by 68 publications

References 80 publications

Nanoparticle Design Strategies for Effective Cancer Immunotherapy

Nanoparticle Design Strategies for Effective Cancer Immunotherapy

Isolating the sources of heterogeneity in nanoparticle-cell interactions

A Nitric Oxide (NO) Nanoreporter for Noninvasive Real‐Time Imaging of Macrophage Immunotherapy

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