Jacob M Majikes
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Explore the profile of Jacob M Majikes including associated specialties, affiliations and a list of published articles.
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Articles
12
Citations
41
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Recent Articles
1.
Majikes J, Cho S, Cleveland 4th T, Liddle J, Balijepalli A
Nanoscale
. 2024 Oct;
16(45):20893-20902.
PMID: 39403767
Electronic measurements of engineered nanostructures comprised solely of DNA (DNA origami) enable new signal conditioning modalities for use in biosensing. DNA origami, designed to take on arbitrary shapes and allow...
2.
Majikes J, Liddle J
J Res Natl Inst Stand Technol
. 2024 Oct;
126:126001.
PMID: 39359737
No abstract available.
3.
Piantanida L, Dickinson G, Majikes J, Clay W, Liddle J, Andersen T, et al.
ACS Nano
. 2024 Aug;
18(33):22369-22377.
PMID: 39109416
DNA-based Points Accumulation for Imaging in Nanoscale Topography (DNA-PAINT) is an effective super resolution microscopy technique, and its optimization is key to improve nanoscale detection. The state-of-the-art improvements that are...
4.
Piantanida L, Liddle J, Hughes W, Majikes J
Nanotechnology
. 2024 Feb;
35(27).
PMID: 38373400
DNA Nanotechnology is being applied to multiple research fields. The functionality of DNA nanostructures is significantly enhanced by decorating them with nanoscale moieties including: proteins, metallic nanoparticles, quantum dots, and...
5.
Hui J, Majikes J, Riley K
Anal Chem
. 2023 Dec;
95(51):18783-18792.
PMID: 38088564
DNA origami nanostructures are engineered nanomaterials (ENMs) that possess significant customizability, biocompatibility, and tunable structural and functional properties, making them potentially useful materials in fields, such as medicine, biocomputing, biomedical...
6.
DeJaco R, Majikes J, Liddle J, Kearsley A
Biophys J
. 2023 Mar;
122(7):1364-1375.
PMID: 36871160
We present a method for extracting temperature-dependent thermodynamic and photophysical properties of SYTO-13 dye bound to DNA from fluorescence measurements. Together, mathematical modeling, control experiments, and numerical optimization enable dye...
7.
Majikes J, Liddle J
Nanoscale
. 2022 Oct;
14(42):15586-15595.
PMID: 36268635
Since its inception nearly 40 years ago [Kallenbach, , , 1983, , 829; N. C. Seeman, , 1982, , 237], Nucleic Acid Nanotechnology (NAN) has matured and is beginning to...
8.
Majikes J, Zwolak M, Liddle J
Biophys J
. 2022 May;
121(11):1986-2001.
PMID: 35546781
Biomolecular thermodynamics, particularly for DNA, are frequently determined via van't Hoff analysis of optically measured melt curves. Accurate and precise values of thermodynamic parameters are essential for the modeling of...
9.
Majikes J, Patrone P, Kearsley A, Zwolak M, Liddle J
ACS Nano
. 2021 Feb;
15(2):3284-3294.
PMID: 33565312
Understanding the folding process of DNA origami is a critical stepping stone to the broader implementation of nucleic acid nanofabrication technology but is notably nontrivial. Origami are formed by several...
10.
Patrone P, Kearsley A, Majikes J, Liddle J
Anal Biochem
. 2020 Jun;
607:113773.
PMID: 32526200
Fluorescence-based measurements are a standard tool for characterizing the thermodynamic properties of DNA systems. Nonetheless, experimental melt data obtained from polymerase chain-reaction (PCR) machines (for example) often leads to signals...