Surface Charge of Supramolecular Nanosystems for In Vivo Biodistribution: A MicroSPECT/CT Imaging Study

Ding, Ling; Lyu, Zhenbin; Louis, Béatrice; Tintaru, Aura; Laurini, Erik; Zhang, Mengjie; Shao, Wanxuan; Jiang, Yifan; Bouhlel, Ahlem; Balasse, Laure; Garrigue, Philippe; Mas, Eric; Giorgio, S.; Iovanna, Juan; Huang, Yuanyu; Pricl, Sabrina; Guillet, Benjamin; Peng, Ling

doi:10.1002/smll.202003290

Cited by 14 publications

(26 citation statements)

References 24 publications

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“…Figure 11 illustrates amphiphilic dendrimers 11-12, which we conceived and developed to construct supramolecular dendrimer nanoprobes for SPECT and PET imaging. 2,18,19 The first ever supramolecular dendrimer nanoprobe for SPECT imaging was formed from 11. 18 This dendrimer is composed of a Figure 11B, left panel), which accumulated effectively within the tumor via the EPR effect for SPECT imaging (Figure 11C, left panel).…”

Section: Bioimagingmentioning

confidence: 99%

“…By employing different small and simple amphiphilic building units, we have successfully constructed various supramolecular dendrimers for the delivery of drugs, nucleic acid therapeutics, and bioimaging agents. [1][2][3][4][5][18][19][20][21][22][23][24][25][26][27] It is worth mentioning that amphiphilic dendrimers can also readily self-assemble into vesicle structures known as "dendrimersomes". 28,29 The dendrimersome concept-which differs from the supramolecular dendrimer concept described in the present work-was inaugurated by Percec et al, 28 and has been investigated extensively as a means of mimicking membranes in biological applications.…”

Section: Introductionmentioning

confidence: 99%

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Self-Assembling Supramolecular Dendrimers for Biomedical Applications: Lessons Learned from Poly(amidoamine) Dendrimers

et al. 2020

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Conspectus Dendrimers, notable for their well-defined radial structures with numerous terminal functionalities, hold great promise for biomedical applications such as drug delivery, diagnostics, and therapeutics. However, their translation into clinical use has been greatly impeded by their challenging stepwise synthesis and difficult purification. To circumvent these obstacles, we have pioneered a self-assembly approach to constructing noncovalent supramolecular dendrimers using small amphiphilic dendrimer building units which can be easily synthesized and purified. By virtue of their amphipathic nature, the small amphiphilic dendrimers are able to self-assemble and generate large supramolecular dendrimers via noncovalent weak interactions such as van der Waals forces, H bonds, and electrostatic interactions. The so-created noncovalent dendrimers can mimic covalent dendrimers not only in terms of the radial structural feature emanating from a central core but also in their capacity to deliver drugs and imaging agents for biomedical applications. The noncovalent supramolecular dendrimers can be easily synthesized and modulated with regard to size, shape, and properties by varying the nature of the hydrophobic and hydrophilic entities as well as the dendrimer generation and terminal functionalities, ensuring their adaptability to specific applications. In particular, the dendritic structure of the amphiphilic building units permits the creation of large void spaces within the formed supramolecular dendrimers for the physical encapsulation of drugs, while the large number of surface functionalities can be exploited for both physical and chemical conjugation of pharmaceutic agents for drug delivery. Poly(amidoamine) (PAMAM) dendrimers are the most intensively studied for biomedical applications by virtue of their excellent biocompatibility imparted by their peptide-mimicking amide backbones and numerous interior and terminal amine functionalities. We present a short overview of our self-assembly strategy for constructing supramolecular PAMAM dendrimers for biomedical applications. Specifically, we start with the introduction of dendrimers and their synthesis, focusing on the innovative self-assembly synthesis of supramolecular dendrimers. We then detail the representative examples of the noncovalent supramolecular PAMAM dendrimers established in our group for the delivery of anticancer drugs, nucleic acid therapeutics, and imaging agents, either within the dendrimer interior or at the dendrimer terminals on the surface. Some of the supramolecular dendrimer nanosystems exhibit outstanding performance, excelling the corresponding clinical anticancer therapeutics and imaging agents. This self-assembly approach to creating supramolecular dendrimers is completely novel in concept yet easy to implement in practice, offering a fresh perspective for exploiting the advantageous features of dendrimers in biomedical applications.

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Section: Bioimagingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Self-Assembling Supramolecular Dendrimers for Biomedical Applications: Lessons Learned from Poly(amidoamine) Dendrimers

et al. 2020

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“…The ovarian carcinoma, especially, having the highest mortality rate in gynecological cancers, is difficult to theranostics drawing support from nanoplatforms due to its dense extracellular matrix [ 7 , 8 ]. In recent years, some novel nanocarriers have been designed by optimizing their physicochemical properties, such as size, softness, shape, surface charge and modification, to achieve highly efficient delivery, to improve theranostic efficacy and reduce systemic toxicity [ [9] , [10] , [11] , [12] , [13] ].…”

Section: Introductionmentioning

confidence: 99%

Dendrimer-decorated nanogels: Efficient nanocarriers for biodistribution in vivo and chemotherapy of ovarian carcinoma

Ouyang

et al. 2021

Bioactive Materials

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Nanomedicine has revolutionized disease theranostics by the accurate diagnosis and efficient therapy. Here, the PAMAM dendrimer decorated PVCL-GMA nanogels (NGs) were developed for favorable biodistribution in vivo and enhanced antitumor efficacy of ovarian carcinoma. By an ingenious design, the NGs with a unique structure that GMA-rich domains were localized on the surface were synthesized via precipitation polymerization. After G2 dendrimer decoration, the overall charge is changed from neutral to positive, and the NGs-G2 display the whole charge nature of positively charged corona and neutral core. Importantly, the unique architecture and charge conversion of NGs-G2 have a profound impact on the biodistribution and drug delivery in vivo . As a consequence of this alteration, the NGs-G2 as nanocarriers emerge the highly sought biodistribution of reduced liver accumulation, enhanced tumor uptake, and promoted drug release, resulting in the significantly augmented antitumor efficacy with low side effects. Remarkably, this finding is contrary to some reported work that the nanocarriers with positive charge have preferential liver uptake. Moreover, the NGs-G2 also displayed thermal/pH dual-responsive behaviors, excellent biocompatibility, improved cellular uptake, and stimuli-responsive drug release. Encouragingly, this work demonstrates a novel insight into the strategy for optimizing design, improving biodistribution and enhancing theranostic efficacy of nanocarriers.

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“…Surface charge can substantially influence the efficiency and the in vivo fate of NPs [ 266 , 267 ]. The surface densities and charges (negative, neutral, or positive) are different for each NP.…”

Section: Physicochemical Properties Of Nps Affecting Toxicitymentioning

confidence: 99%

Safety Evaluation of Nanotechnology Products

et al. 2021

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Nanomaterials are now being used in a wide variety of biomedical applications. Medical and health-related issues, however, have raised major concerns, in view of the potential risks of these materials against tissue, cells, and/or organs and these are still poorly understood. These particles are able to interact with the body in countless ways, and they can cause unexpected and hazardous toxicities, especially at cellular levels. Therefore, undertaking in vitro and in vivo experiments is vital to establish their toxicity with natural tissues. In this review, we discuss the underlying mechanisms of nanotoxicity and provide an overview on in vitro characterizations and cytotoxicity assays, as well as in vivo studies that emphasize blood circulation and the in vivo fate of nanomaterials. Our focus is on understanding the role that the physicochemical properties of nanomaterials play in determining their toxicity.

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Surface Charge of Supramolecular Nanosystems for In Vivo Biodistribution: A MicroSPECT/CT Imaging Study

Cited by 14 publications

References 24 publications

Self-Assembling Supramolecular Dendrimers for Biomedical Applications: Lessons Learned from Poly(amidoamine) Dendrimers

Self-Assembling Supramolecular Dendrimers for Biomedical Applications: Lessons Learned from Poly(amidoamine) Dendrimers

Dendrimer-decorated nanogels: Efficient nanocarriers for biodistribution in vivo and chemotherapy of ovarian carcinoma

Safety Evaluation of Nanotechnology Products

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