Kihwan Nam
Overview
Explore the profile of Kihwan Nam including associated specialties, affiliations and a list of published articles.
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Articles
13
Citations
25
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0
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Recent Articles
1.
Chung H, Nam K, Lee S, Woo A, Kim J, Park E, et al.
Medicina (Kaunas)
. 2025 Jan;
60(12.
PMID: 39768870
: Assessing pain deception is challenging due to its subjective nature. The main goal of this study was to evaluate the diagnostic value of pain deception using machine learning (ML)...
2.
Nam K, Lee C, Lee T, Shin M, Kim B, Park J
Diagnostics (Basel)
. 2024 Jul;
14(13).
PMID: 39001334
We aimed to develop an automated detector that determines laryngeal invasion during swallowing. Laryngeal invasion, which causes significant clinical problems, is defined as two or more points on the penetration-aspiration...
3.
Kim K, Rothlisberger P, Kang S, Nam K, Lee S, Hollenstein M, et al.
Molecules
. 2018 Jul;
23(7).
PMID: 30041480
Rolling circle amplification (RCA) is a robust way to generate DNA constructs, which are promising materials for biomedical applications including drug delivery because of their high biocompatibility. To be employed...
4.
Lee H, Lee S, Lee G, Lee W, Nam K, Lee J, et al.
Nanoscale
. 2017 Nov;
10(2):538-547.
PMID: 29167849
Here, we demonstrate a powerful method to discriminate DNA mismatches at single-nucleotide resolution from 0 to 5 mismatches (χ to χ) using Kelvin probe force microscopy (KPFM). Using our previously...
5.
Kim M, Lee J, Nam K, Park I, Son M, Ko H, et al.
Sensors (Basel)
. 2017 Oct;
17(10).
PMID: 28976941
We reported an automated dielectrophoretic (DEP) tweezers-based force spectroscopy system to examine intermolecular weak binding interactions, which consists of three components: (1) interdigitated electrodes and micro-sized polystyrene particles used as...
6.
Park I, Kwak T, Lee G, Son M, Choi J, Choi S, et al.
ACS Nano
. 2016 Mar;
10(4):4011-9.
PMID: 27007455
The direct quantification of weak intermolecular binding interactions is very important for many applications in biology and medicine. Techniques that can be used to investigate such interactions under a controlled...
7.
Kwon T, Park J, Lee G, Nam K, Huh Y, Lee S, et al.
J Phys Chem Lett
. 2015 Aug;
4(7):1126-30.
PMID: 26282031
It has been of high significance to devise a biochemical analytical tool kit enabling the detection of few circulating tumor cells (CTCs) for early diagnosis of cancer. Despite recent effort...
8.
Park I, Lee J, Lee G, Nam K, Lee T, Chang W, et al.
Anal Chem
. 2015 Jul;
87(14):7495.
PMID: 26151359
No abstract available.
9.
Park I, Lee J, Lee G, Nam K, Lee T, Chang W, et al.
Anal Chem
. 2015 Mar;
87(12):5914-20.
PMID: 25811309
Quantitative detection of the biological properties of living cells is essential for a wide range of purposes, from the understanding of cellular characteristics to the development of novel drugs in...
10.
Lee G, Lee H, Nam K, Han J, Yang J, Lee S, et al.
Nanoscale Res Lett
. 2012 Nov;
7(1):608.
PMID: 23113991
We report on how to quantify the binding affinity between a nanoparticle and chemical functional group using various experimental methods such as cantilever assay, PeakForce quantitative nanomechanical property mapping, and...