Cisplatin Nanoliposomes for Cancer Therapy:  AFM and Fluorescence Imaging of Cisplatin Encapsulation, Stability, Cellular Uptake, and Toxicity

Ramachandran, Srinivasan; Quist, Arjan P.; Kumar, Satish; Lal, Ratnesh

doi:10.1021/la0607499

Cited by 105 publications

(81 citation statements)

References 24 publications

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“…12 Ramachandran et al also found that the uptake of nanoparticle formations of CDDP by cells was much easier. 13 CDDP is a radiation sensitizer and has been widely used with radiation therapy for cancer treatment.…”

Section: Discussionmentioning

confidence: 99%

In vitro and in vivo study of a nanoliposomal cisplatin as a radiosensitizer

Zhang¹,

Yang²,

Gu³

et al. 2011

IJN

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Objective: To investigate the in vitro and in vivo radiosensitization effect of an institutionally designed nanoliposome encapsulated cisplatin (NLE-CDDP). Materials and methods: NLE-CDDP was developed by our institute. In vitro radiosensitization of NLE-CDDP was evaluated by colony forming assay in A549 cells. In vivo radiosensitization was studied with tumor growth delay (TGD) in Lewis lung carcinoma. The radiosensitization for normal tissue was investigated by jejunal crypt survival. The radiosensitization studies were carried out with a 72 h interval between drug administration and irradiation. The mice were treated with 6 mg/kg of NLE-CDDP or CDDP followed by single doses of 2 Gy, 6 Gy, 16 Gy, and 28 Gy. Sensitization enhancement ratio (SER) was calculated by D 0 s of cell survival curves for A549 cells, doses needed to yield TGD of 20 days in Lewis lung carcinoma, or D 0 s of survival curves in crypt cells in radiation alone and radiation plus drug groups. Results: Our NLE-CDDP could inhibit A549 cells in vitro with half maximal inhibitory concentration of 1.12 μg/mL, and its toxicity was 2.35 times that observed in CDDP. For in vitro studies of A549 cells, SERs of NLE-CDDP and CDDP were 1.40 and 1.14, respectively, when combined with irradiation. For in vivo studies of Lewis lung carcinoma, the strongest radiosensitization was found in the 72 h interval between NLE-CDDP and irradiation. When given 72 h prior to irradiation, NLE-CDDP yielded higher radiosensitization than CDDP (SER of 4.92 vs 3.21) and slightly increased injury in jejunal crypt cells (SER of 1.15 vs 1.19). Therefore, NLE-CDDP resulted in a higher TGF than did CDDP (4.28 vs 2.70) when SERs were compared between experiments in vivo and in jejunal crypt cell studies. Conclusions: Our NLE-CDDP was demonstrated to have radiosensitization with TGF of 4.28 when administrated 72 h prior to irradiation.

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Section: Discussionmentioning

confidence: 99%

In vitro and in vivo study of a nanoliposomal cisplatin as a radiosensitizer

Zhang¹,

Yang²,

Gu³

et al. 2011

IJN

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“…For example, the interaction of particles with some cell types is known to vary with particle size [47,48]. Thus, fine control over liposome size can be exploited to produce optimal drug and gene delivery vectors [2,5]. Liposome geometry is also expected to play a significant role in their application as model biological systems.…”

Section: Morphology Of Liposomesmentioning

confidence: 99%

“…Since their discovery in the 1960s [1], liposome application has spanned a wide range of fields. They have been used as gene and drug delivery vectors in the pharmaceutical industry [2][3][4][5], as contrast agent containers in enhanced medical imaging [6][7][8], and as nano-sized crystallization reactors [9,10]. Similarities in the chemical and physical properties of the lipid bilayers of liposomes and living cells have also led to their use as models in studying cellular membranes [1,11].…”

Section: Introductionmentioning

confidence: 99%

Microfluidic hydrodynamic focusing based synthesis of POPC liposomes for model biological systems

Mijajlovic

Wright

Živković

et al. 2013

Colloids and Surfaces B: Biointerfaces

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Elsevier's AAM Policy: Authors retain the right to use the accepted author manuscript for personal use, internal institutional use and for permitted scholarly posting provided that these are not for purposes of commercial use or systematic distribution.Elsevier believes that individual authors should be able to distribute their AAMs for their personal voluntary needs and interests, e.g. posting to their websites or their institution's repository, e-mailing to colleagues. However, our policies differ regarding the systematic aggregation or distribution of AAMs to ensure the sustainability of the journals to which AAMs are submitted. Therefore, deposit in, or posting to, subjectoriented or centralized repositories (such as PubMed Central), or institutional repositories with systematic posting mandates is permitted only under specific agreements between Elsevier and the repository, agency or institution, and only consistent with the publisher's policies concerning such repositories. AbstractLipid vesicles have received significant attention in areas ranging from pharmaceutical and biomedical engineering to novel materials and nanotechnology. Microfluidic-based synthesis of liposomes offers a number of advantages over the more traditional synthesis methods such as extrusion and sonication. One such microfluidic approach is microfluidic hydrodynamic focusing (MHF), which has been used to synthesize nanoparticles and vesicles of various lipids. We show here that this method can be utilized in synthesis of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) vesicles with controllable size. Since POPC is among the primary constituents of cellular membranes, this work is of direct applicability to modelling of biological systems and development of nanocontainers with higher biologic compatibility for pharmaceutical and medical applications.

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“…4 Therefore, the development of a controlled release drug delivery system for CDDP represents a key challenge in achieving optimum clinical response for this potent chemotherapy agent. 5 In recent years, the continued search for effective cancer treatment has led to the emergence of many nanosized vectors for the delivery of chemotherapeutics, for example, liposomes 6 and polymeric particles, 7,8 which aim to reduce premature interaction with the biological environment and improve cellular targeting. 9,10 Importantly, the physicochemical properties of nanovectors influence their efficacy as drug delivery systems.…”

Section: Introductionmentioning

confidence: 99%

Electrohydrodynamic fabrication of core–shell PLGA nanoparticles with controlled release of cisplatin for enhanced cancer treatment

Reardon¹,

Parhizkar²,

Harker³

et al. 2017

IJN

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Increasing the clinical efficacy of toxic chemotherapy drugs such as cisplatin (CDDP), via targeted drug delivery, is a key area of research in cancer treatment. In this study, CDDP-loaded poly(lactic-co-glycolic acid) (PLGA) polymeric nanoparticles (NPs) were successfully prepared using electrohydrodynamic atomization (EHDA). The configuration was varied to control the distribution of CDDP within the particles, and high encapsulation efficiency (>70%) of the drug was achieved. NPs were produced with either a core–shell (CS) or a matrix (uniform) structure. It was shown that CS NPs had the most sustained release of the 2 formulations, demonstrating a slower linear release post initial “burst” and longer duration. The role of particle architecture on the rate of drug release in vitro was confirmed by fitting the experimental data with various kinetic models. This indicated that the release process was a simple diffusion mechanism. The CS NPs were effectively internalized into the endolysosomal compartments of cancer cells and demonstrated an increased cytotoxic efficacy (concentration of a drug that gives half maximal response [EC 50 ] reaching 6.2 µM) compared to free drug (EC 50 =9 µM) and uniform CDDP-distributed NPs (EC 50 =7.6 µM) in vitro. Thus, these experiments indicate that engineering the structure of PLGA NPs can be exploited to control both the dosage and the release characteristics for improved clinical chemotherapy treatment.

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Cisplatin Nanoliposomes for Cancer Therapy: AFM and Fluorescence Imaging of Cisplatin Encapsulation, Stability, Cellular Uptake, and Toxicity

Cited by 105 publications

References 24 publications

In vitro and in vivo study of a nanoliposomal cisplatin as a radiosensitizer

In vitro and in vivo study of a nanoliposomal cisplatin as a radiosensitizer

Microfluidic hydrodynamic focusing based synthesis of POPC liposomes for model biological systems

Electrohydrodynamic fabrication of core–shell PLGA nanoparticles with controlled release of cisplatin for enhanced cancer treatment

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Cisplatin Nanoliposomes for Cancer Therapy: AFM and Fluorescence Imaging of Cisplatin Encapsulation, Stability, Cellular Uptake, and Toxicity

Cited by 105 publications

References 24 publications

In vitro and in vivo study of a nanoliposomal cisplatin as a radiosensitizer

In vitro and in vivo study of a nanoliposomal cisplatin as a radiosensitizer

Microfluidic hydrodynamic focusing based synthesis of POPC liposomes for model biological systems

Electrohydrodynamic fabrication of core&ndash;shell PLGA nanoparticles with controlled release of cisplatin for enhanced cancer treatment

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Electrohydrodynamic fabrication of core–shell PLGA nanoparticles with controlled release of cisplatin for enhanced cancer treatment