Abstract
The sense of smell is one of the most important organs in humans, and olfactory imaging can detect signals in the anterior orbital frontal lobe. This study assessed olfactory stimuli using support vector machines (SVMs) with signals from functional near-infrared spectroscopy (fNIRS) data obtained from the prefrontal cortex. These data included odor stimuli and air state, which triggered the hemodynamic response function (HRF), determined from variations in oxyhemoglobin (oxyHb) and deoxyhemoglobin (deoxyHb) levels; photoplethysmography (PPG) of two wavelengths (raw optical red and near-infrared data); and the ratios of data from two optical datasets. We adopted three SVM kernel functions (i.e., linear, quadratic, and cubic) to analyze signals and compare their performance with the HRF and PPG signals. The results revealed that oxyHb yielded the most efficient single-signal data with a quadratic kernel function, and a combination of HRF and PPG signals yielded the most efficient multi-signal data with the cubic function. Our results revealed superior SVM analysis of HRFs for classifying odor and air status using fNIRS data during olfaction in humans. Furthermore, the olfactory stimulation can be accurately classified by using quadratic and cubic kernel functions in SVM, even for an individual participant data set.
Highlights
Support vector machines (SVMs) help classify human data from functional nearinfrared spectroscopy signals, and this method has novel applications [1,2], including a recently developed neuroimaging method for evaluating neural activity signals in brain cortical regions [3]
We evaluated an innovative approach based on functional nearinfrared spectroscopy (fNIRS) signals for assessing olfactory signals in the prefrontal cortex (PFC) through support vector machines (SVMs)-based classification
This study reports the potential of using an SVM for training five types of single fNIRS
Summary
Support vector machines (SVMs) help classify human data from functional nearinfrared spectroscopy (fNIRS) signals, and this method has novel applications [1,2], including a recently developed neuroimaging method for evaluating neural activity signals in brain cortical regions [3]. The classification accuracy of the eyes-open paradigm is 77.0%; that of the eyes-closed paradigm is 75.6% [4]. FNIRS can be performed with the eyes open or closed during the activation of the prefrontal cortex (PFC). A three-choice system-paced single trial with separate mental arithmetic and mental signing tasks in the no-control state has been developed, and a linear classifier achieved overall classification accuracy of 56.2% [6]. Numerous studies have reported that an SVM algorithm using fNIRS signals may have low accuracy. Studies on olfaction have extensively used SVMs or other algorithms [7,8,9,10]
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