Smart cancer nanomedicine

Meel, Roy van der; Sulheim, Einar; Shi, Yang; Kießling, Fabian; Mulder, Willem J. M.; Lammers, Twan

doi:10.1038/s41565-019-0567-y

Cited by 887 publications

(602 citation statements)

References 102 publications

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“…The gradual implementation of universally standardized practices could promote more accurate reporting of materials and methodologies, and could change the paradigm for many nanotechnology products that already exist [41,42]. On top of this, improving the clinical impact of nanomedicines demands "smart thinking and rational and realistic reasoning," as stated by van der Meel et al in a recently published perspective article in Nature Nanotechnology [43]. In this sense, and particularly in the case of cancer therapy, patient stratification, rational drug selection, the use of combination therapies, and the targeting of the adaptive immune system are key for addressing scientific and medical questions that will potentiate the exploitation and, most importantly, the translation of nanomedicines into the clinic.…”

mentioning

confidence: 99%

The solid progress of nanomedicine

Martins

Neves

Fuente

et al. 2020

Drug Deliv. and Transl. Res.

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confidence: 99%

The solid progress of nanomedicine

Martins

Neves

Fuente

et al. 2020

Drug Deliv. and Transl. Res.

102

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“…Many new drug products that now appear on the market come with their own biomarker, and typically, these biomarkers are identified and evaluated early on in the developmental process. In this regard, one could even argue that biomarkers should already be identified before clinical development is commenced, and there is no reason why this-as for molecularly targeted therapeutic and monoclonal antibodies-should not also hold true for nanomedicinal drugs [6][7][8].…”

Section: Clinical Development Feasibilitymentioning

confidence: 99%

“…The observation that nanomedicines seem to be more prone to lack of predictability of patient benefit as compared with conventional drugs and molecularly targeted therapeutics may be due to the critical dependence of nanomedicine efficacy on pharmacokinetics, tissue distribution, target site accumulation and penetration, and drug release at the target site (and ideally in the target cell), which are all specific in vivo nanoparticulate performance aspects and which are very different in animal models versus in human patients. Lessons learnt in anticancer nanomedicine development have taught us the importance of tumor vascularization, stroma, and especially macrophage population in nanoparticle target localization and drug release, and these tissue morphology aspects typically vary dramatically inside a tumor, across tumors in a patient and even more so among (different cancerous lesions in) different patients [7][8][9]. This becomes all the more poignant when we realize that thus far, the (cancer) nanomedicine field has seen relatively little progress in the development of biomarkers and companion diagnostics.…”

Section: Translating Preclinical Efficacy To Clinical Outcomementioning

confidence: 99%

Challenges in nanomedicine clinical translation

Metselaar

Lammers

2020

Drug Deliv. and Transl. Res.

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New nanomedicine formulations and novel applications of nanomedicinal drugs are reported on an almost daily basis. While academic progress and societal promise continue to shoot for the stars, industrial acceptance and clinical translation are being looked at increasingly critically. We here discuss five key challenges that need to be considered when aiming to promote the clinical translation of nanomedicines. We take the perspective of the end-stage users and consequently address the developmental path in a top-down manner. We start off by addressing central and more general issues related to practical and clinical feasibility, followed by more specific preclinical, clinical, and pharmaceutical aspects that nanomedicinal product development entails. We believe that being more aware of the end user's perspective already early on in the nanomedicine development path will help to better oversee the efforts and investments needed, and to take optimally informed decisions with regard to market opportunities, target disease indication, clinical trial design, therapeutic endpoints, preclinical models, and formulation specifications. Critical reflections on and careful route planning in nanomedicine translation will help to promote the success of nanomedicinal drugs.

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“…[111] In addition, a fundamental problem in successfully delivering nanocarriers to specific tumor sites in human patients is a lack of understanding of the EPR effect, which is observed in preclinical mouse models. [10,[112][113][114][115] In animal models of cancer, the EPR effect is thought to result from the tumor's induction of immature blood vessel formation, which causes nanoparticles to be accumulated in regions where the tumor is highly vascularized with immature vessels and where the vessels are more permeable. [11,116] However, in clinical trials with patients, numerous nanocarriers fail because of very low (less than 1%) accumulation in tumors.…”

Section: Low Efficacy Of Nanomedicinementioning

confidence: 99%

“…Personalized nanomedicine is likely the future of nanomedicine, because this approach will take into account the heterogeneous characteristics of patients and, for cancer patients, the heterogeneity of cancer cells within a patient. [8][9][10] In the following two sections, we review how systems biology can contribute to realizing personalized nanomedicine by promoting EPR and aiding in target selection, and identifying treatment paradigms.…”

Section: Low Efficacy Of Nanomedicinementioning

confidence: 99%

Realizing Cancer Precision Medicine by Integrating Systems Biology and Nanomaterial Engineering

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Many clinical trials for cancer precision medicine have yielded unsatisfactory results due to challenges such as drug resistance and low efficacy. Drug resistance is often caused by the complex compensatory regulation within the biomolecular network in a cancer cell. Recently, systems biological studies have modeled and simulated such complex networks to unravel the hidden mechanisms of drug resistance and identify promising new drug targets or combinatorial or sequential treatments for overcoming resistance to anticancer drugs. However, many of the identified targets or treatments present major difficulties for drug development and clinical application. Nanocarriers represent a path forward for developing therapies with these “undruggable” targets or those that require precise combinatorial or sequential application, for which conventional drug delivery mechanisms are unsuitable. Conversely, a challenge in nanomedicine has been low efficacy due to heterogeneity of cancers in patients. This problem can also be resolved through systems biological approaches by identifying personalized targets for individual patients or promoting the drug responses. Therefore, integration of systems biology and nanomaterial engineering will enable the clinical application of cancer precision medicine to overcome both drug resistance of conventional treatments and low efficacy of nanomedicine due to patient heterogeneity.

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Smart cancer nanomedicine

Cited by 887 publications

References 102 publications

The solid progress of nanomedicine

The solid progress of nanomedicine

Challenges in nanomedicine clinical translation

Realizing Cancer Precision Medicine by Integrating Systems Biology and Nanomaterial Engineering

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