Electroencephalogram (EEG) Based Fuzzy Logic and Spiking Neural Networks (FLSNN) for Advanced Multiple Neurological Disorder Diagnosis
Brain Topography,
Год журнала:
2025,
Номер
38(3)
Опубликована: Фев. 24, 2025
Язык: Английский
Smart Textile Technology for the Monitoring of Mental Health
Sensors,
Год журнала:
2025,
Номер
25(4), С. 1148 - 1148
Опубликована: Фев. 13, 2025
In
recent
years,
smart
devices
have
proven
their
effectiveness
in
monitoring
mental
health
issues
and
played
a
crucial
role
providing
therapy.
The
ability
to
embed
sensors
fabrics
opens
new
horizons
for
healthcare,
addressing
the
growing
demand
innovative
solutions
objective
of
this
review
is
understand
health,
its
impact
on
human
body,
latest
advancements
field
textiles
(sensors,
electrodes,
garments)
physiological
signals
such
as
respiration
rate
(RR),
electroencephalogram
(EEG),
electrodermal
activity
(EDA),
electrocardiogram
(ECG),
cortisol,
all
which
are
associated
with
disorders.
Databases
Web
Science
(WoS)
Scopus
were
used
identify
studies
that
utilized
monitor
specific
parameters.
Research
indicates
provide
promising
results
compared
traditional
methods,
offering
enhanced
comfort
long-term
monitoring.
Язык: Английский
Multiclass classification of epileptic seizure phases using a novel HFO-based feature extraction model
Signal Image and Video Processing,
Год журнала:
2025,
Номер
19(4)
Опубликована: Фев. 22, 2025
Язык: Английский
Exploiting adaptive neuro-fuzzy inference systems for cognitive patterns in multimodal brain signal analysis
T. Thamaraimanalan,
Dhanalakshmi Gopal,
S. Vignesh
и другие.
Scientific Reports,
Год журнала:
2025,
Номер
15(1)
Опубликована: Март 16, 2025
The
analysis
of
cognitive
patterns
through
brain
signals
offers
critical
insights
into
human
cognition,
including
perception,
attention,
memory,
and
decision-making.
However,
accurately
classifying
these
remains
a
challenge
due
to
their
inherent
complexity
non-linearity.
This
study
introduces
novel
method,
PCA-ANFIS,
which
integrates
Principal
Component
Analysis
(PCA)
Adaptive
Neuro-Fuzzy
Inference
Systems
(ANFIS),
enhance
pattern
recognition
in
multimodal
signal
analysis.
PCA
reduces
the
dimensionality
EEG
data
while
retaining
salient
features,
enabling
computational
efficiency.
ANFIS
combines
adaptability
neural
networks
with
interpretability
fuzzy
logic,
making
it
well-suited
model
non-linear
relationships
within
signals.
Performance
metrics
our
proposed
such
as
accuracy,
sensitivity,
These
additions
highlight
effectiveness
method
provide
concise
summary
findings.
achieves
superior
classification
performance,
an
unprecedented
accuracy
99.5%,
significantly
outperforming
existing
approaches.
Comprehensive
experiments
were
conducted
using
diverse
dataset,
demonstrating
method's
robustness
sensitivity.
integration
addresses
key
challenges
analysis,
artifact
contamination
non-stationarity,
ensuring
reliable
feature
extraction
classification.
research
has
significant
implications
for
both
neuroscience
clinical
practice.
By
advancing
understanding
processes,
PCA-ANFIS
facilitates
accurate
diagnosis
treatment
disorders
neurological
conditions.
Future
work
will
focus
on
testing
approach
larger
more
datasets
exploring
its
applicability
domains
neurofeedback,
neuromarketing,
brain-computer
interfaces.
establishes
capable
tool
precise
efficient
processing.
Язык: Английский
Multichannel convolutional transformer for detecting mental disorders using electroancephalogrpahy records
Scientific Reports,
Год журнала:
2025,
Номер
15(1)
Опубликована: Май 2, 2025
Mental
disorders
represent
a
critical
global
health
challenge
that
affects
millions
around
the
world
and
significantly
disrupts
daily
life.
Early
accurate
detection
is
paramount
for
timely
intervention,
which
can
lead
to
improved
treatment
outcomes.
Electroencephalography
(EEG)
provides
non-invasive
means
observing
brain
activity,
making
it
useful
tool
detecting
potential
mental
disorders.
Recently,
deep
learning
techniques
have
gained
prominence
their
ability
analyze
complex
datasets,
such
as
electroencephalography
recordings.
In
this
study,
we
introduce
novel
deep-learning
architecture
classification
of
post-traumatic
stress
disorder,
depression,
or
anxiety,
using
data.
Our
proposed
model,
multichannel
convolutional
transformer,
integrates
strengths
both
neural
networks
transformers.
Before
feeding
model
low-level
features,
input
pre-processed
common
spatial
pattern
filter,
signal
space
projection
wavelet
denoising
filter.
Then
EEG
signals
are
transformed
continuous
transform
obtain
time-frequency
representation.
The
layers
tokenize
by
our
pre-processing
pipeline,
while
Transformer
encoder
effectively
captures
long-range
temporal
dependencies
across
sequences.
This
specifically
tailored
process
data
has
been
preprocessed
transform,
technique
representation,
thereby
enhancing
extraction
relevant
features
classification.
We
evaluated
performance
on
three
datasets:
Psychiatric
Dataset,
MODMA
dataset,
Psychological
Assessment
dataset.
achieved
accuracies
87.40%
89.84%
92.28%
approach
outperforms
every
concurrent
approaches
datasets
used,
without
showing
any
sign
over-fitting.
These
results
underscore
in
delivering
reliable
disorder
through
analysis,
paving
way
advancements
early
diagnosis
strategies.
Язык: Английский
Predicting stroke severity of patients using interpretable machine learning algorithms
European journal of medical research,
Год журнала:
2024,
Номер
29(1)
Опубликована: Ноя. 14, 2024
Stroke
is
a
significant
global
health
concern,
ranking
as
the
second
leading
cause
of
death
and
placing
substantial
financial
burden
on
healthcare
systems,
particularly
in
low-
middle-income
countries.
Timely
evaluation
stroke
severity
crucial
for
predicting
clinical
outcomes,
with
standard
assessment
tools
being
Rapid
Arterial
Occlusion
Evaluation
(RACE)
National
Institutes
Health
Scale
(NIHSS).
This
study
aims
to
utilize
Machine
Learning
(ML)
algorithms
predict
using
these
two
distinct
scales.
We
conducted
this
datasets
collected
from
hospitals
Urmia,
Iran,
corresponding
assessments
based
RACE
NIHSS.
Seven
ML
were
applied,
including
K-Nearest
Neighbor
(KNN),
Decision
Tree
(DT),
Random
Forest
(RF),
Adaptive
Boosting
(AdaBoost),
Extreme
Gradient
(XGBoost),
Support
Vector
(SVM),
Artificial
Neural
Network
(ANN).
Hyperparameter
tuning
was
performed
grid
search
optimize
model
performance,
SHapley
Additive
Explanations
(SHAP)
used
interpret
contribution
individual
features.
Among
models,
RF
achieved
highest
accuracies
92.68%
dataset
91.19%
NIHSS
dataset.
The
Area
Under
Curve
(AUC)
92.02%
97.86%
datasets,
respectively.
SHAP
analysis
identified
triglyceride
levels,
length
hospital
stay,
age
critical
predictors
severity.
first
apply
models
scales
use
enhances
interpretability
increasing
clinicians'
trust
algorithms.
best-performing
can
be
valuable
tool
assisting
medical
professionals
settings.
Язык: Английский