Daniel Rojas
Overview
Explore the profile of Daniel Rojas including associated specialties, affiliations and a list of published articles.
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Articles
30
Citations
318
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Recent Articles
1.
Samuel J, Yon C, Frisancho A, Estrada L, Lourdes Valdez Jaen M, Paucar Pari D, et al.
Community Health Equity Res Policy
. 2025 Mar;
:2752535X251323637.
PMID: 40088181
This study examines the work of a collective of community-based Indigenous health rights activists in southern Peru who, at the height of the pandemic, designed, recorded, and disseminated seven Quechua...
2.
Xuan X, Rojas D, Lozano I, Cuartero M, Crespo G
Sensors (Basel)
. 2024 Nov;
24(22).
PMID: 39599020
Sweat rate magnitude is a desired outcome for any wearable sensing patch dedicated to sweat analysis. Indeed, sweat rate values can be used two-fold: self-diagnosis of dehydration and correction/normalization of...
3.
Rojas D, Torricelli D, Cuartero M, Crespo G
Anal Chem
. 2024 Sep;
96(39):15572-15580.
PMID: 39303277
3D printing technology has become attractive in the development of electrochemical sensors as it offers automation in fabrication, customization on-demand, and reproducibility, among other features. Nonetheless, to date, solid contact...
4.
Diaz-Moreno M, Rojas D
Am J Public Health
. 2024 Sep;
114(11):1151-1152.
PMID: 39265127
No abstract available.
5.
Hernandez-Rodriguez J, Trachioti M, Hrbac J, Rojas D, Escarpa A, Prodromidis M
Anal Chem
. 2024 Jun;
96(25):10127-10133.
PMID: 38867513
3D printing technology is a tremendously powerful technology to fabricate electrochemical sensing devices. However, current conductive filaments are not aimed at electrochemical applications and therefore require intense activation protocols to...
6.
Hernandez-Rodriguez J, Rojas D, Escarpa A
Anal Chem
. 2023 Dec;
95(51):18679-18684.
PMID: 38095628
Three-dimensional (3D) printing technology has emerged as a powerful technology for the fabrication of low-cost microfluidics. Nevertheless, the fabrication of microfluidic devices integrating high-performance electrochemical sensors in practical applications is...
7.
Palacios-Corella M, Rojas D, Pumera M
J Colloid Interface Sci
. 2022 Nov;
631(Pt B):125-134.
PMID: 36399805
Autonomous self-propelled micromachines based on semiconductors are at the forefront of environmental pollutants degradation research to palliate the effects of the contamination arising from the constant manufacturing of new products....
8.
Hernandez-Rodriguez J, Lopez M, Rojas D, Escarpa A
Lab Chip
. 2022 Nov;
22(24):4805-4821.
PMID: 36342332
Organ on-a-chip (OoC) is a promising technology that aims to recapitulate human body pathophysiology in a more precise way to advance in drug development and complex disease understanding. However, the...
9.
Rojas D, Hernandez-Rodriguez J, Della Pelle F, Escarpa A, Compagnone D
Mikrochim Acta
. 2022 Aug;
189(9):320.
PMID: 35932400
No abstract available.
10.
Rojas D, Hernandez-Rodriguez J, Della Pelle F, Escarpa A, Compagnone D
Mikrochim Acta
. 2022 Feb;
189(3):102.
PMID: 35152341
The ubiquity and importance of ROS and RNS in cellular signaling, disease development, and death give rise to an outstanding interest in their detection and quantification. Among the analytical techniques...