Ieee Transactions on Biomedical Circuits and Systems
Overview
The IEEE Transactions on Biomedical Circuits and Systems is a prestigious journal that focuses on the design, development, and application of circuits and systems for biomedical applications. It covers a wide range of topics including bioelectronics, medical imaging, wearable devices, and neuroengineering. The journal publishes high-quality research articles, reviews, and letters, making it an essential resource for researchers, engineers, and healthcare professionals in the field of biomedical circuits and systems.
Details
Details
Abbr.
IEEE Trans Biomed Circuits Syst
Publisher
IEEE
Start
2007
End
Continuing
Frequency
Six no. a year, 2009-
p-ISSN
1932-4545
e-ISSN
1940-9990
Country
United States
Language
English
Specialties
Biomedical Engineering
Biotechnology
Biotechnology
Metrics
Metrics
h-index / Ranks: 3442
94
SJR / Ranks: 2044
1462
CiteScore / Ranks: 1397
10.10
JIF / Ranks: 1521
5.1
Recent Articles
1.
Zhang Z, Cao T, Liu S, Jin H, Wang W, Yin X, et al.
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
PP.
PMID: 40031742
The miniaturization and real time imaging capability have always been the desired properties of photoacoustic imaging (PAI) system, which unlocked vast potential for personalized healthcare and diagnostics. While the imaging...
2.
Wang Y, Orlandic L, Machetti S, Ansaloni G, Atienza D
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
19(1):82-92.
PMID: 40031441
Wearable devices for health monitoring are essential for tracking individuals' health status and facilitating early detection of diseases. However, processing biomedical signals online for real-time monitoring is challenging due to...
3.
Scrugli M, Leone G, Busia P, Raffo L, Meloni P
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
19(1):68-81.
PMID: 40031440
The accurate modeling of hand movement based on the analysis of surface electromyographic (sEMG) signals offers exciting opportunities for the development of complex prosthetic devices and human-machine interfaces, moving from...
4.
Liang J, Hu Y
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
19(1):238.
PMID: 40031439
In [1], in section III.E of the article, we calculate the equivalent tunnelling current according to equation (4) by using the value of Cg, eff as 1.679 fF, which is...
5.
Busia P, Scrugli M, Jung V, Benini L, Meloni P
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
19(1):142-152.
PMID: 40031438
Wearable systems for the continuous and real-time monitoring of cardiovascular diseases are becoming widespread and valuable assets in diagnosis and therapy. A promising approach for real-time analysis of the electrocardiographic...
6.
Habibollahi M, Jiang D, Lancashire H, Demosthenous A
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
PP.
PMID: 40031356
A mm-sized, implantable neural interface for bidirectional control of the peripheral nerves with microchannel electrodes is presented in this paper. The application-specific integrated circuit (ASIC) developed in a 0.18 μm...
7.
Willaredt R, Grandauer C, Dorigo D, Wendler D, Kuhl M, Manoli Y
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
PP.
PMID: 40031267
Host connectivity for invasive, high-density neural probes that integrate all the circuits needed for insitu digitization of brain activity in the shank requires a thin and conformal cable. To minimize...
8.
Zhang C, Huang Z, Zhou C, Qie A, Wang X
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
PP.
PMID: 40031210
Many electrocardiogram (ECG) processors have been widely used for cardiac monitoring. However, most of them have relatively low energy efficiency, and lack configurability in classification leads number and inference algorithm...
9.
Omi A, Jiang A, Chatterjee B
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
PP.
PMID: 40031198
In the context of implantable bioelectronics, this work provides new insights into maximizing biomedical wireless power transfer (BWPT) via the systematic development of inductive links. This approach addresses the specific...
10.
Bhattacharyya S, Hasler J
IEEE Trans Biomed Circuits Syst
. 2025 Mar;
PP.
PMID: 40031050
Integrate-and-fire (I&F) neurons used in neuromorphic systems are traditionally optimized for low energy-per-spike and high density, often excluding the complex dynamics of biological neurons. Limited dynamics cause missed opportunities in...