Advances in neuroscience and marketing: analyzing tool possibilities and research opportunities

3.1.1 Skin conductance.

Skin conductance responses (also called galvanic responses or impedance levels) refer to the ability of the skin to conduct electricity derived from an external application of direct current of constant voltage. The activity of eccrine sweat glands is responsible for modifications in skin conductance, which are the reflex of the secretion of sweat from these glands. Because sweat constitutes an electrolyte solution, the presence of more sweat in skin pores increases skin conductivity. The sympathetic branch of the autonomic nervous system is responsible for eccrine sweating, so skin conductance indicates the intensity, arousal or emotional arousal of the sympathetic autonomic nervous system. The electrodes needed to measure skin conductance are placed on the distal (first) phalanges of the index and middle finger (Figure 1(a)). The total cost per hour of a galvanic response session is between €25 and €100/h.

Recent research in the field of consumer behavior has evaluated electrical skin activity responses in responsible consumption or environmental settings (Martinez-Fiestas et al., 2015), radio or television effectiveness or tourism destination communication campaigns (Li et al., 2018).

3.1.2 Facial electromyography.

Facial electromyography (EMG) records the electrical signals associated with the subtle movements of facial muscles and is able to detect facial muscle contractions in response to affective information, even though such activity is not obviously perceived (Li et al., 2018). Research in the field of psychophysiology has shown that facial EMG is an established index of hedonic valence (Martinez-Fiestas et al., 2015). More specifically, the response of three facial muscles is used (Figure 1(b)):

1. Increased activity on the superciliary corrugator muscle, which causes the frown to furrow, is associated with negative emotions.

2. Increased activity of another muscle, the zygomaticus major, which is associated with positive emotions during viewing and listening to pleasant and positive images and sounds.

3. Increased activity in the orbicularis, which has been associated with positive emotions and high arousal during viewing affective images and media.

Given the enormous usefulness of EMG in identifying experienced affective valence, studies in the branch of consumer behavior have used such a tool to evaluate the emotional content of political and environmental (Martinez-Fiestas et al., 2015) messages, or the effectiveness of tourism advertising (Li et al., 2018). The total cost per hour of a galvanic response session is between €30 and €1,000/h.

3.1.3 Electrocardiogram.

Heart rate variability consists of the physiological event of variation in the time interval among heartbeats (Lang et al., 1998). This heart variability is related to the activations of the sympathetic (responsible for energy mobilization) and parasympathetic (responsible for energy conservation) systems of the PNS. Its recording is developed through electrocardiography, which measures the number of heart contractions per minute (see Figure 1(c)). Research in the field of psychology concludes that the heart rate provides two psychological significances (Lang, 1998):

1. On the one hand, studies agree that cardiac changes are due to a motivational/emotional type of adaptation to fight or resting state circumstances (Bradley et al., 2005). For example, fear, stress or physical exercise implies a higher heart rate.

2. Second, cardiac changes are due to cognitive functions of an attentional, perceptual or mental processing type (Bradley et al., 2005). This fact implies that when we experience an attentional process, we are oriented toward that stimulus because we need to process it, a fact that translates into a greater deceleration of the cardiac response.

Literature in the branch of consumer behavior has used heart rate to assess psychological processes related to attention and motivation/emotion in marketing settings. More specifically, research has used heart rate measurements in the fields of online (Guixeres et al., 2017) or environmental (Martinez-Fiestas et al., 2015) advertising. Electrocardiogram (EKG) sessions usually cost between €15 and €100/h.

3.1.4 Eye-tracking.

The eye-tracking methodology provides observable evidence of how individuals attend to audiovisual information over time. Whether reading or searching for an object, eye movements consist of two alternating events, namely, fixations, when the eyes keep still during 200–300 ms, and saccades, when the eyes quickly move by means of “jumps” (Casado-Aranda, 2021). Information processing takes place during fixations, when a specific area of the visual field is projected onto the fovea. In marketing research, eye-tracking data usually cover four major issues, namely, when, how often, for how long and what consumers look at. Eye-tracking researchers have used three main measures derived from pupil measurement (Manippa et al., 2017):

1. Time to first fixation, referring to the time it takes a consumer to look at a specific area of interest.

2. Number of fixations, which is related to the number of times a consumer looks at a specific area of interest. It is a measure related to the interest or relevance triggered by a stimulus.

3. Pupil size or pupil dimensions (in millimeters) upon exposure to a marketing stimulus, which is positively related to higher cognitive load and with emotional arousal during image viewing (Bradley et al., 2005).

Eye-tracking sessions usually cost between €10 and €100/h (Figure 1(d)).

Most marketing research has largely used eye-tracking to measure attention derived from two types of processes: top-down and bottom-up control. First, the individual influences attention, developing top-down control to select crucial information and purposely to pay attention to some parts of the information. Scholars have particularly analyzed the attentional processes toward marketing stimuli considering consumers’ objectives (Pieters et al., 2010). Moreover, the features of a specific stimulus itself are able to capture attention regardless of the individual, thus applying stimulus-driven or bottom-up control over attention. In this regard, marketing academics have analyzed attention toward specific media features of advertising design, such as animation (Casado-Aranda et al., 2018a, 2018b).

3.2.1 Functional magnetic resonance imaging.

This is a non-invasive tool that records modifications in the brain’s blood oxygenation-dependent level (called the fMRI BOLD signal) derived from metabolic changes in the blood flow triggered by neural activity. Specifically, scholars use the MRI scanner that records contrasts between the activity levels of deep brain structures, which are involved, according to the traditional cognitive and neuroscience literature, with particular mental functions difficult to access through psychological tools, such as fear, guilt, cognitive overload, self-relevance or intentional efforts. This technique makes it possible to localize, represent and visualize such activations while participants undergo marketing-related tasks (Solnais et al., 2013).

fMRI experiments require participants to horizontally rest in the fMRI scanner while it processes the stimuli of interest. Inside the MRI scanner room, and once lying on the horizontal couch, the participant has a mirror reflecting a screen located behind the MRI scanner directly in front of his or her eyes. The screen precisely exposes the stimuli sent from the investigator’s computer, displayed through a projector. Once inside the scanner, participants engage in experimental tasks and make decisions through two push-button controls (see Figure 2).

The great strength of fMRI lies in its high spatial resolution, which allows the determination of neural activity from 3 in 3 mm³. fMRI recordings, on the contrary, could be subject to artifacts, namely, head movement or breathing. fMRI scanners, nevertheless, have a low temporal resolution, which means that they are not able to measure significant changes over short periods of time, such as millions of milliseconds (Dimoka, 2010). fMRI scholars pay €200–€800/h.

Specifically, in consumer neuroscience, fMRI has been used to determine brain differences in the perception of PayPal or debit card (Casado-Aranda et al., 2018) or to explore the neural manifestations of creative and attractive packaging (Reimann et al., 2010).

3.2.2 Electroencephalography.

Electroencephalography (EEG) constitutes a tool that records modifications in neural electrical activity in the cerebral cortex. Specifically, it records the frequency of brain electrical currents and changes in their voltage. In particular, it makes use of electrodes placed on the scalp, which function as individual channels and are then amplified to facilitate statistical analysis. To obtain statistically valid results, typically, researchers use EEG acquisition systems with 128 electrodes in 10-20 or 10-5 international systems, which refer to the percentage of distance – 5, 10 or 20 – at which the electrodes should be placed on the frontal, occipital, right and left side of the skull (Oostenveld and Praamstra, 2001).

Among the characteristics that justify the usefulness of EEG are a high spatial resolution (from <10 to >500 ms); low cost – compared to fMRI, the cost of each participant round is between €50 and €1,000/h; and a high level of compatibility with other psychological techniques, namely, 32% of experiments combine EEG with eye-tracking, heart rate, facial EMG and galvanic response (Sánchez-Fernández et al., 2021). Despite these advantages, their application has not achieved high levels of acceptance because of two main drawbacks: low spatial resolution (1–3 cm³) and inability to pick up the activity of internal structures of brain regions of enormous interest for human decision-making, such as the amygdala (Figure 2).

According to the study by Sánchez-Fernández et al. (2021), EEG is the second most widely used neuroimaging tool in the field of marketing research, after fMRI, with 30% of studies using this method. Its application has recently focused on evaluating attentional and memory and emotional processes (Astolfi et al., 2008) related to exposure to marketing stimuli.

3.2.3 Functional near-infrared spectroscopy.

Functional near-infrared spectroscopy (fNIRS) constitutes a recently developed optical imaging tool that “measures changes in hemoglobin (Hb) flux within the brain through Hb absorption spectra in the near-infrared range” (Sánchez-Fernández et al., 2021). “The spatial resolution and penetration depth of fNIRS images are up to 2 cm, making it suitable for monitoring brain areas located in the prefrontal cortex, a brain region that is central to human preferences” (Sánchez-Fernández et al., 2021) (Figure 2). Similarly, mobile fNIRS extends near-infrared light through the scalp and measures optical density fluctuations derived from metabolic modifications within the brain. Studies have even corroborated that the fNIRS signal correlates with the fMRI BOLD signal (Sánchez-Fernández et al., 2021). This tool even has some advantages when compared to fMRI, as it allows to measure the neural activity of the participants in environments more naturalistic and closer to real purchasing processes, in which the participant moves. Yet, as in the case of EEG, its low spatial resolution does not allow measurement of activations in inner brain areas, such as the hippocampus.

Consumer neuroscience studies have recently used fNIRS for the evaluation of health communication campaigns (Cuesta et al., 2020) and real purchasing decisions (Çakir et al., 2018). Scholars are also prone to using fNIRS as the cost of each participant rounds between €20 and €500/h. Thus far, only 4% of consumer behavior studies reverted to fNIRS to inform on marketing processes.

3.2.4 Secondary brain imaging techniques.

Although secondarily, there is also research in the marketing field that has used three additional neuroimaging techniques, namely magnetoencephalography (MEG) and brain stimulation techniques – such as the transcranial direct current stimulation (tDCS) and the transcranial magnetic stimulation (TMS). First, the rationale behind the MEG is pretty much the same as EEG but it records activation within the neural magnetic field. MEG has also good temporal resolution and even a greater spatial localization than EEG, which allows a better recording of deeper brain structures (Harris et al., 2018). The main application of MEG in the marketing field has focused on identifying striate cortical activation related to recall and affective reactions toward audiovisual advertising (Harris et al., 2018). Second, tDCS constitutes a non-invasive brain stimulation technique, which uses direct electrical currents to stimulate specific parts of the brain. Thirdly, TMS makes use of a modifiable magnetic field aiming to provoke electric current within a particular brain network by means of electromagnetic induction. Much of the research using these neurostimulation tools has been used in the field of consumer food decision-making (Manippa et al., 2017).

4.1.1 Predicting product purchasing decisions.

First, neurophysiological tools can contribute to the understanding of the neurological basis of consumer purchase decisions. Although the consumer behavior literature has traditionally elucidated that variables such as perceived value, preference, product quality, trust, intention toward product purchase and satisfaction may lead to product purchase and repurchase, the nature of purchasing itself is not fully understood. Some seminal works such as that of Knutson et al. (2007) used fMRI for the first time and confirmed that purchase decisions are preceded by brain circuits related to anticipatory positive affect and emotion, such as the medial prefrontal cortex (MPFC). These results can serve as a guide for the design and test of products and services that include features that trigger activations in these brain areas.

Second, neurophysiological methods can inform about the nature, dimensionality and causal relationships between product purchase drivers. For example, although some research using fMRI or EEG has already elucidated the neural nature and dimensionality of trust or preferences (Dimoka, 2010), more research is needed to explore if constructs such as trust, perceived value or loyalty could be considered as different based on distinct activations in affective or cognitive-related brain networks. These studies should pay special attention to identifying the neural correlates of consumer involvement, a powerful precursor of purchase intentions and behaviors (Casado-Aranda et al., 2018), whose neural affective or cognitive nature has not yet been elucidated. In addition, because these methodologies allow a real-time data collection and a dynamic time series analysis, they could measure the flow of a single or several marketing-related constructs synchronously, thus enabling to ascertain the temporal order of diverse constructs or their dimensions. Along this latter line, marketing scholars have largely used adaptations of the theory of planned behavior (Ajzen, 1991) as a model to explain product purchases and have considered that social norms, subjective norms and perceived control are antecedents of attitudes, these latter preceding purchase intentions and behaviors. “Because emotional processes often precede cognitive ones, neurophysiological tools could illuminate the temporal dynamics of these constructs” (Dimoka, 2010) based on their cognitive or affective neural correlates.

4.1.2 Consumer responses to branding efforts.

Brands constitute one of the most remarkable cues in the product purchase decision process, and traditional marketing research has attempted to understand whether and how brand positioning efforts affect brand personality, brand experience, brand preference and, more broadly, purchase intentions. Consumer neuroscience is already taking the first steps in elucidating how branding efforts modulate neural representations toward favorite brands. The seminal Coke–Pepsi fMRI study by McClure et al. (2004) explained for the first time that brand preferences toward Coke are based on brand recognition (because of stronger brain activations of the dorsolateral prefrontal cortex, which is associated with cognitive information processing) and not taste preferences (as both brands elicited pleasure-related brain areas).

Neuroimaging methods can also be used to better discern differences in the neural processing of prestigious/luxury brands (e.g. Porsche) and pragmatic/functional brands (e.g. Renault). The results of the study by Schaefer and Rotte (2007) showed that while brands that evoke social dominance (i.e. Porsche) activate brain areas associated with self-relevance, functional brands increase activations in cognitive control. These findings could help test whether a company’s brand positioning is coherent with its value proposition (e.g. more emotional or functional) considering the type of brain responses (namely, self-relevance or cognitive control/reasoning) they evoke. Future research could even analyze the extent to which diverse consumers’ personality traits (e.g. extraversion or openness) are associated with these activations during brand exposure, as this could constitute an efficient segmentation strategy building upon neural responses. Brain imaging techniques could also help identify the underexplored dimensions of constructs such as brand experience (namely, sensorial, emotional, intellectual, behavioral and social experiences) or brand loyalty (customer commitment and brand repurchase intention), as well as the temporal order of brand-related constructs.

Given the powerful ability of physiological tools to track emotional intensity (e.g. skin conductance), visual attention (e.g. eye-tracking) or valence (e.g. EMG), they could directly measure the extent to which different proposals of logos (e.g. colors, shapes and texts), slogans or brand names increase skin sweating levels, number of fixations, pupil size and activations of facial muscles, and thus infer their relative effectiveness.

4.1.3 Packaging.

Physiological tools are especially useful for helping product designers to create attractive packages based on the psychological reactions to package cues. For example, eye-tracking measures could advise package designers on the position in which they should place labels, information of interest (e.g. nutrition or country of origin), graphs or brand logos based on where, when and for how long the user looks at different package locations. Facial EMG could also be useful to detect negative emotions triggered by the evaluation of diverse package designs. Furthermore, because the cognitive neuroscience literature has already cleared up the neural correlates of esthetics – namely, brain areas linked to positive value and reward, such as ventral striatum (Reimann et al., 2010) – designers could use such brain areas to test diverse design prototypes. In addition, consumer neuroscience studies could be practical as a direct usability criterion by associating package usability measures (such as technical, functional or informative quality) with neurophysiological metrics. Such physiological investigations could make use of prior packages with diverse levels of usability on specific dimensions (such as functional) to explore how functional differences are represented as neurophysiological distinctions.

Brain imaging techniques could be of great utility for identifying cognitive and affective processes responsible for mediating the valuation bias toward contextual package cues, such as labeling. Particularly, the traditional consumer behavior literature has confirmed that fair trade labels (vs conventional), organic product labels, nutritional traffic lights or country of origin labels convey inherently rewarding or negative properties, such as feeling good/bad about oneself for buying a national product, doing something good/bad or buying healthy food (Asioli et al., 2017). However, little is known about the mechanisms that determine consumer choices based on these labels. Neurophysiological tools are recently revealing, for example, that neural mechanisms related to self-relevance and positive value are responsible for the higher preference toward home products, and risk-related brain regions responsible for the avoidance of foreign products (Casado-Aranda et al., 2021). These neural mechanisms can be used to test the effectiveness of other product labels, such as denominations of origin and certificates from health institutions, that support the product or certificates from external institutions (such as TripAdvisor).