• KSBB Journal
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• 제10권4호
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• pp.428-434
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• 1995

Target-sensitive(TG-S) liposomes, which have the antibodies coupled on the surface of liposome and can release their entrapped contents by the binding of antibodies with the specigic target cells, were prepared and employed to study the release of calcein and the selective delivery of an anticancer agent, doxorubicin(DOX). The monoclonal antibody, Y3, used for the preparation of the TG-S liposome was one against major histocompatibility complex class 1 of mouse(MHCI, H-2Kｂtype) and the target cells were EL-4 and RMA, which have the MHC1, H-2Kbtype on their membrane surfacem. The release of calcein from TG-S liposome occurred when the target cells were contacted with liposomes and it was proportionally increased with the rise of binding capacity of antibody coupled on the surface of liposome to the target cells. The experimental results of drug delivery were similar to the cases of calcein release. The viability of specific target cell, EL-4 with liposomal DOX was not so different from that with the free DOX, while for the non-specific target cell, Yacl(H-2Kf), the cell viability with Iiposomal DOX was much higher than that with free DOX. This shows the fact that the liposomal DOX can be efficiently delivered to the specific target cells, while it was not the case for the non-specific target cells. And the drug delivery was lnhibited when the free antibody of Y3 was added in the contact process between EL-4 and TG-S liposomes, which means the drug delivery occurred mainly by the destabilization of TG-S liposomes. From these results, we could conclude that the selective drug delivery to specific target cell using the TG-S liposome would be feasible.

• 대한의용생체공학회:의공학회지
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• 제43권2호
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• pp.94-101
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• 2022

Recent advancement of micro/nano technology enables the development of diverse micro/nano particle-based delivery systems. Due to the multi-functionality and engineerability, particle-based delivery system are expected to be a promising method for delivery to the target cell. Since the particle-based delivery system should be delivered to the various kinds of target cell, including the cardiovascular system, cancer cell etc., it is frequently decorated with multiple kinds of targeting molecule(s) to induce specific interaction to the target cell. The surface decorated molecules interact with the cell surface expressed molecule(s) to specifically form a firm adhesion. Thus, in this study, the probability of adhesion is estimated to predict the possibility to form a firm adhesion for the multi-ligand decorated particle-based delivery system.

• Applied Science and Convergence Technology
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• 제24권6호
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• pp.284-288
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• 2015

Anionic small molecules are hard to penetrate the cell membranes because of their negative charges. Encapsulation of small molecules into liposome particles can provide target specific delivery of them. In our previous study, siRNA could be efficiently encapsulated into liposome particles using an asymmetric preparation method of liposomes. In this study, the same method was applied for encapsulation of small anionic fluorescent chemicals such as calcein and indocyanine green (ICG). More than 90% fluorescent chemicals were encapsulated in the asymmetric liposome particles (ALPs). No intracellular fluorescent signal was observed in the tumor cells treated with the unmodified calcein/ALPs and ICG/ALPs, whereas the surface modification with a cell-penetrating polyarginine peptide (R8 or R12) allows cellular uptake of the ALPs. The results demonstrate that the ALPs encapsulating small anionic drugs will be useful for target-specific delivery after modification of target-specific ligands.

• Biomolecules & Therapeutics
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• 제21권6호
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• pp.423-434
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• 2013

The adoption of oligonucleotide aptamer is well on the rise, serving an ever increasing demand for versatility in biomedical field. Through the SELEX (Systematic Evolution of Ligands by EXponential enrichment), aptamer that can bind to specific target with high affinity and specificity can be obtained. Aptamers are single-stranded nucleic acid molecules that can fold into complex three-dimensional structures, forming binding pockets and clefts for the specific recognition and tight binding of any given molecular target. Recently, aptamers have attracted much attention because they not only have all of the advantages of antibodies, but also have unique merits such as thermal stability, ease of synthesis, reversibility, and little immunogenicity. The advent of novel technologies is revolutionizing aptamer applications. Aptamers can be easily modified by various chemical reactions to introduce functional groups and/or nucleotide extensions. They can also be conjugated to therapeutic molecules such as drugs, drug containing carriers, toxins, or photosensitizers. Here, we discuss new SELEX strategies and stabilization methods as well as applications in drug delivery and molecular imaging.

• Archives of Pharmacal Research
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• 제29권7호
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• pp.598-604
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• 2006

In many conventional drug delivery systems in vogue, failure to deliver efficient drug delivery at the target site/organs; is evident as a result, less efficacious pharmacological response is elicited. Microspheres can be derived a remedial measure which can improve site-specific drug delivery to a considerable extent. As an application, Lung-targeting Ofloxacin-loaded gelatin microspheres (GLOME) were prepared by water in oil emulsion method. The Central Composite Design (CCD) was used to optimize the process of preparation, the appearance and size distribution were examined by scanning electron microscopy, the aspects such as in vitro release characteristics, stability, drug loading, loading efficiency, pharmacokinetics and tissue distribution in albino mice were studied. The experimental results showed that the microspheres in the range of $0.32-22\;{\mu}m$. The drug loading and loading efficiency were 61.05 and 91.55% respectively. The in vitro release profile of the microspheres matched the korsmeyer’s peppas release pattern, and release at 1h was 42%, while for the original drug, ofloxacin under the same conditions 90.02% released in the first half an hour. After i.v. administration (15 min), the drug concentration of microspheres group in lung in albino mice was $1048\;{\mu}g/g$, while that of controlled group was $6.77\;{\mu}g/g$. GLOME found to release the drug to a maximum extent in the target tissue, lungs.

• 생명과학회지
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• 제31권9호
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• pp.849-855
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• 2021

최근에는 나노기술이 다양한 분야에 도입되고 활용되면서 신약개발이 가속화되고 있다. 나노입자는 약물의 단일 투여로 장기간 동안 혈중 약물 농도를 유지하고, 병리학적 부위에만 선택적으로 방출되는 장점이 있어 비병리 주위에 대한 부작용을 줄일 수 있다. Poly (D,L-lactic-co-glycolic acid) (PLGA)는 가장 광범위하게 개발된 생분해성 고분자 중 하나이다. PLGA는 다양한 응용분야의 약물전달에 널리 사용된다. 또한 FAD에 의해 약물전달 시스템으로 승인되었으며, 유전자 치료제와 같은 제어방출제형에 널리 적용된다. PLGA 나노입자는 수동 및 능동 표적화 방법을 사용하여 특정 세포 유형에 고효율의 전달 시스템으로 개발되었다. 이러한 PLGA 나노입자를 이용한 약물전달체 개발 후 표적 부위에 선택적으로 약물을 전달하고 질병에 따라 장기간 유효 혈중 농도를 최적화한다. 이 리뷰논문에서 우리는 유전자 치료를 위한 PLGA 나노 물질을 기반으로 하는 성상 세포 선택적 나노입자의 개발을 조사하여 세포 특이적으로 치료결과를 향상시키는 방법에 중점을 두고자 한다.

• Archives of Pharmacal Research
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• 제25권1호
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• pp.1-10
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• 2002

Attempts to develop drugs, specific for cancer cells, are dealt here according to the intended cell-target. While many target specific drugs were developed, they reach only moderate successes in clinics for reasons, such as, delivery problem, lack of in vivo efficacy or toxicity. However, recent efforts focusing on the diversity of tyrosine kinases, participating in cell-signal transduction, brought fruit. The first such drug, Givec, approved by the USFDA recently, is used in clinics with great success to threat CML. The drug inhibits tyrosin kinase of bcr-abl, c-abl and v-abl. Work is progressing on other tyrosin kinase inhibitors and on other type of specific cancer cell signal protein inhibitors. These efforts are hoped to yield better cures for cancer in the near future.

• Molecules and Cells
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• 제46권1호
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• pp.41-47
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• 2023

The rapid development of mRNA vaccines has contributed to the management of the current coronavirus disease 2019 (COVID-19) pandemic, suggesting that this technology may be used to manage future outbreaks of infectious diseases. Because the antigens targeted by mRNA vaccines can be easily altered by simply changing the sequence present in the coding region of mRNA structures, it is more appropriate to develop vaccines, especially during rapidly developing outbreaks of infectious diseases. In addition to allowing rapid development, mRNA vaccines have great potential in inducing successful antigen-specific immunity by expressing target antigens in cells and simultaneously triggering immune responses. Indeed, the two COVID-19 mRNA vaccines approved by the U.S. Food and Drug Administration have shown significant efficacy in preventing infections. The ability of mRNAs to produce target proteins that are defective in specific diseases has enabled the development of options to treat intractable diseases. Clinical applications of mRNA vaccines/therapeutics require strategies to safely deliver the RNA molecules into targeted cells. The present review summarizes current knowledge about mRNA vaccines/ therapeutics, their clinical applications, and their delivery strategies.

• 공업화학
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• 제21권6호
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• pp.593-602
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• 2010

천연고분자물질로서 키토산(chitosan)은 생체적합성, 생분해성, 무독성과 같은 생체재료로서의 우수한 물리화학적 특성에도 불구하고 산(acid)으로 용해하여야 한다는 문제점으로 인해 유전질병이나 암과 같은 불치병의 치료를 위한 생리활성 물질의 생체 내 전달물질로서의 응용이 어려운 실정이다. 따라서 키토산의 이러한 문제점을 획기적으로 해결한 높은 반응성과 강한 양전하(+)를 띠고 있는 저분자량 수용성 키토산(low molecular weight water-soluble chitosan, LMWSC)을 이용하여 난용성 약물뿐만 아니라 치료유전자와 같은 생리활성물질을 안전하게 생체 내 표적위치에 운반할 수 있는 전달체를 제조할 수 있고, 인체 내 무해하고 치료효율이 높은 치료시스템을 개발할 수 있을 것으로 사료된다. 또한 질병의 치료를 위해 무엇보다 중요한 인자는 특정 병소조직에만 발현되는 항원이나 수용체를 밝혀내고 이들과 결합할 수 있는 항체나 리간드를 다양한 생체재료에 개질함으로써 질병 치료의 효율을 높이는 것이 가장 중요한 전략이라고 할 수 있다. 약물이나 유전자를 전달할 수 있는 많은 양이온성 합성고분자에 대한 연구가 활발히 이루어지고 있으나 체내 독성이나 효율성 면에서 많은 문제점을 가지고 있다. 따라서 본 총설에서는 인체 내 전달 효율을 높이기 위한 기능성기의 도입과 유전자와의 복합체 형성을 가능하게 하는 유리 아민기를 가진 인체 무해한 저분자량 수용성 키토산을 이용하여 특정 조직을 표적할 수 있는 다양한 기능성기 도입의 특성과 치료 전략에 대해 기술하고자 한다. 이러한 전달체의 개발은 앞으로 인간에게 유발되는 가장 난치병 중의 하나인 암 치료에 있어 밝은 전망이 될 수 있을 것으로 사료된다.

• Nuclear Medicine and Molecular Imaging
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• 제42권5호
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• pp.337-346
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• 2008

Applications of nanotechnology in the medical field have provided the fundamentals of tremendous improvement in precise diagnosis and customized therapy. Recent advances in nanomedicine have led to establish a new concept of theragnosis, which utilizes nanomedicines as a therapeutic and diagnostic tool at the same time. The development of high affinity nanoparticles with large surface area and functional groups multiplies diagnostic and therapeutic capacities. Considering the specific conditions related to the disease of individual patient, customized therapy requires the identification of disease target at the cellular and molecular level for reducing side effects and enhancing therapeutic efficiency. Well-designed nanoparticles can minimize unnecessary exposure of cytotoxic drugs and maximize targeted localization of administrated drugs. This review will focus on major pharmaceutical nanomaterials and nanoparticles as key components of designing and surface engineering for targeted theragnostic drug development.