Cognitive science diagnoses several disorders of consciousness (minimally conscious state, Persistent vegetative state, Locked-in syndrome, chronic coma, Brain stem death), which is curious in that we do not know (for sure) what consciousness is or is not.

Bottom line is that I agree that we need a theory-based assessment of consciousness from we can determine some norms, and then we can diagnose disorders of consciousness.

Full Citation: 
Fingelkurts, AA, Fingelkurts, AA, Bagnato, S, Boccagni, C, and Galardi, G. (2014, Jun 4). Do we need a theory-based assessment of consciousness in the field of disorders of consciousness? Frontiers in Human Neuroscience; 8:402. doi: 10.3389/fnhum.2014.00402

Do we need a theory-based assessment of consciousness in the field of disorders of consciousness?

Alexander A. Fingelkurts [1], Andrew A. Fingelkurts [1], Sergio Bagnato [2,3], Cristina Boccagni [2,3] and Giuseppe Galardi [2,3]

1. Research Department, BM-Science – Brain and Mind Technologies Research Centre, Espoo, Finland
2. Neurorehabilitation Unit, Rehabilitation Department, Fondazione Istituto “San Raffaele-G. Giglio,” Cefalù, Italy
3. Neurophysiology Unit, Rehabilitation Department, Fondazione Istituto “San Raffaele-G. Giglio,” Cefalù, Italy

Adequate assessment of (un)consciousness is not only of theoretical interest but also has a practical and ethical importance, especially when it comes to disorders of consciousness (DOC). Accurately determining the presence or absence of consciousness in patients with DOC allows informed decisions to be made about long-term care support, referral for rehabilitation, pain management and withdrawal of life support.

In spite of significant progress in neuroimaging and the introduction of clear-cut clinical diagnostic criteria, determining the (un)consciousness still presents an important clinical problem: errors are common and have been shown to be as high as 37–43% (Tresch et al., 1991; Childs et al., 1993; Andrews et al., 1996; Schnakers et al., 2006).

Assessment errors arise because the evaluation of patients with DOC is based mostly on clinical observation of subjectively interpreted behavioral responses, while conscious experience often occurs without any behavioral signs. Additionally behavioral responses of such patients are usually limited by their cognitive dysfunctions and/or by their frequent motor impairment. Therefore, determining if a non-communicative or minimally communicative patient is phenomenally conscious poses a major clinical and ethical challenge. For this reason, there is a need for paraclinical diagnostic markers for the presence or absence of consciousness.

We believe that a theoretical account of what conscious experience is and how it emerges within the brain will advance the search for appropriate neuromarkers of the presence or absence of consciousness in non-communicative brain-damaged patients.

In our view, several important considerations need to be kept in mind:

Consciousness vs. Vigilance

Consciousness is often conceptualized as a phenomenon with two components: wakefulness and awareness (Posner et al., 2007). Though such understanding is currently quite wide-spread, it confuses and mixes two different and independent phenomena: subjective awareness and vigilance. While awareness is an important component of consciousness, wakefulness belongs to the vigilance domain. Independence of these two concepts can be demonstrated by examples from a daily life: (a) we are able to unconsciously perform complex actions like brushing our teeth or driving a car while being completely awake; (b) being at the same level of wakefulness we are usually aware of some events/stimuli while unaware of others; and (c) during sleep we can be aware of our phenomenal experience (dreams) but are not awake. Hence, wakefulness is not a component of consciousness but of vigilance. Vigilance, however, affects consciousness by limiting the amount of information available for conscious access (Rusalova, 2006), thus affecting the amount of content (Overgaard and Overgaard, 2010).

Is Consciousness Gradually Continuous or Discrete (“All-or-None”)?

From the abovementioned fallacy, another misconception arises—levels of consciousness. The assumption is that consciousness itself can be somehow diminished (less consciousness) or increased (more consciousness), and thus considered to be gradual (Laureys et al., 2002; Vanhaudenhuyse et al., 2010a). However, there is no introspective evidence to support this widely accepted idea (Overgaard and Overgaard, 2010). Indeed, from a third-person perspective, consciousness presents itself in varying amounts, depending on the level of vigilance of the studied subject. However, what is important is that from the first-person perspective one is either discretely fully aware or unaware of something. It is the amount of content that varies gradually (Overgaard and Overgaard, 2010). There is no additional degree of consciousness during such awareness of the content (for a discussion see Fingelkurts et al., 2012a). In other words, consciousness is not merely a quantitative matter of a degree but in fact a qualitative matter of absence or presence of a particular state (Plum et al., 1998). In this sense, when consciousness is separated from arousal/wakefulness, then it is more of a categorical (all-or-none) phenomenon rather than a continuous (gradual) one (Fingelkurts et al., 2012a). It is the degree of vigilance (wakefulness) that conflates the expression of consciousness, resulting in an illusion of its continuous or graded nature (Hudetz, 2010).

What is Then Consciousness?

It is reasonable to assume that to be conscious is to be in a particular state which has projections onto mental/ psychological, neurophysiological and cognitive/behavioral dimensions (Edelman, 1989; Sokolov, 1990; Flohr, 1991; Tononi, 2008). Currently we do not know all parameters of this state, but recent empirical studies have provided several important observations (see Figure 1):

• The realization of a particular state of consciousness requires particular level of vigilance [and hence a preservation of the autonomic nervous system (Plum and Posner, 1980; Wijnen et al., 2006)], a corresponding functional state and physical integrity of the brain (Pistoia and Sara, 2012).
• A given conscious state should have a particular duration: it must be longer than the time it takes for the simplest cognitive act to be completed, which is on the order of several hundreds of milliseconds (Pöppel, 1997; Geissler et al., 1999; VanRullen and Koch, 2003). It seems that duration less than this threshold makes a state un-conscious (still mental domain) or non-conscious (non-mental neurophysiological domain) (for a discussion see Fingelkurts et al., 2010; Bagnato et al., 2013).
• It seems that the state of consciousness is supported by medium values of such characteristics of neuronal assembles as their functional size, life span and stability (Figure 1). Indeed, consciousness is lost when neuronal assembles' size, life span and stability decrease as is the case for patients in vegetative state (VS) or under general anesthesia (Greenfield and Collins, 2005; Fingelkurts et al., 2012b). Likewise, consciousness is lost when these characteristics are changed in the opposite direction as in the case of patients during the generalized seizure (Martin, 1991). Curiously, the speed of the growth of neuronal assemblies is slow during a conscious state but it increases significantly when consciousness is lost (Fingelkurts et al., 2012b).
• Similarly, both low (like in VS or general anesthesia) and high (like in seizure) levels of synchrony among neuronal assemblies result in a dramatic loss of consciousness (Flohr, 1995; Mashour, 2004; John and Prichep, 2005; Blumenfeld, 2008; Cavanna and Monaco, 2009; Hudetz, 2010; Fingelkurts et al., 2012b) (Figure 1).
• High strength of default mode network synchrony is required to support representational content integrated within the first-person perspective (Vanhaudenhuyse et al., 2010b; Fingelkurts et al., 2012c).
• The state of consciousness is dominated by EEG fast-alpha and beta oscillations (Fingelkurts et al., 2012a,b,c see also Gugino et al., 2001; Kuizenga et al., 2001; Babiloni et al., 2006, 2009; Rusalova, 2006; Başar and Güntekin, 2009) that may be considered necessary and a minimally sufficient neural condition for a conciseness to be expressed.
• The state of consciousness is independent from specialized cognitive processes like episodic memory, language, introspection or reflection, sense of space, sense of body, sense of self, or sensorimotor processing, or attention as it follows from neurological evidence (for the reviews see Tononi and Laureys, 2008; Boly et al., 2009).

FIGURE 1  

Figure 1. Schematic illustration relating consciousness expression and neuronal assembly characteristics. The stepwise line represents the idea that gradual changes in neuronal mechanisms need to be accumulated to reach a particular threshold level required for qualitative change in the functional state (Bagnato et al., 2013). During VS as a result of a brain injury, the functions of the neural net subtending consciousness (awareness) are reduced in both hemispheres below the threshold level required for minimal consciousness expression. The recovery of consciousness is a dynamic process that involves many plastic changes in many brain structures. If this reorganization crosses the threshold of the minimal neuronal mechanisms that are jointly sufficient for any conscious awareness (particular level of the size, life-span, stability and speed of growth of neuronal assemblies, as well as the amount and strength of functional connectivity between them), the patient will regain consciousness (Fingelkurts et al., 2012a,b). The critical factor regulating the occurrence or absence of consciousness recovery is the distance of these functional characteristics of neuronal assemblies from this threshold level (Bagnato et al., 2013).VS, vegetative state; MCS, minimally conscious state; dashed horizontal line illustrates a threshold of the minimal neuronal mechanisms that are jointly sufficient for any conscious awareness to emerge.

Taken together (Figure 1) these findings suggest that consciousness is an emergent phenomenon of coherent dynamic binding of multiple, relatively large, long-lived and stable, but transient alpha and beta generated neuronal assemblies organized as synchronized patterns within a nested, hierarchical brain architecture. It seems that these are minimally sufficient conditions at the more basic level (brain) that are required for the emergent quality (conscious mind) to manifests itself. Indeed, if phenomenal consciousness is a biological phenomenon within the confines of the brain, then there must be a specific level of brain organization and a specific spatial–temporal grain in it where consciousness resides. In other words, we could expect that at the lower (in comparison with the phenomenal consciousness) level of brain organization there should be non-experiential entities (some complex electrophysiological mechanisms) that function as the direct realization base of the phenomenal world (Fingelkurts et al., 2010, 2013a). The abovementioned nested hierarchical architecture of separate and synchronized neuronal assemblies forms the very particular level of brain functioning, so-called operational architectonics level, which on the one hand intervenes between physical level of the brain where it literally resides, and on the other, is isomorphic to the experiential/subjective phenomenal structure of the mind (Fingelkurts et al., 2010). In other words, the level of the operational architectonics has emergent properties relatively independent from the neurophysiological/neuroanatomical properties of the physical level. And the phenomenal level supervenes on this operational level with one-to-one correspondence thus making it ontologically inseparable from it (though it is separable from the brain neuroanatomical processes through the operational level) (Fingelkurts et al., 2013a).

Analytic Model for Assessing Consciousness

Patients in VS or in minimally conscious state (MCS) offer a unique opportunity to study the neural basis of (un)consciousness due to the fact that impairment in awareness of self and environment is dissociated in such patients from preserved and stable wakefulness. We believe that an appropriate level of consciousness description should articulate the operational level of brain organization where the phenomenal/conscious phenomena reside (Fingelkurts et al., 2013b). Electroencephalogram (EEG) is a suitable and adequate measure for the instrumental analysis of such operational level, because it (a) provides a direct (in contrast to indirect fMRI an PET) measure of the behavior of large-scale neuronal networks with a millisecond temporal resolution and reflects functional properties and states of brain functioning as well as being closely connected to information processing in/among neuronal assemblies (for a discussion see Fingelkurts et al., 2012a) and (b) enables clinicians to assess spontaneous brain activity at each level of vigilance and in any state of consciousness, bypassing the need to elicit a behavioral or any other response from the patient (Vanhaudenhuyse et al., 2010b).

Following Baars's (1988) recommendation, an experimental analytic model for the assessment of consciousness should consider only those EEG parameters that satisfy the rule: (i) NORM ≥ MCS > VS for subjective awareness of self and environment, (ii) NORM ≥ MCS < VS for subjective unawareness of self and environment. This model was already successfully used in several recent studies (Fingelkurts et al., 2012a,b,c, 2013b).

In conclusion we argue that in the situation where there is no consensus on what would constitute the reliable markers of consciousness in the absence of the subject's report, a theory-based insight into neural substrates and mechanisms involved in conscious content may be useful for detecting the presence of conscious experiences in non-communicating subjects.

Do we Need a Theory-Based Assessment of Consciousness for Proper Rehabilitation of Patients with DOC?

On the basis of the foregoing concepts, we may assume that patients with similar clinical behavior (i.e., VS or MCS) differ considerably in their level of operational architectonic dysfunction and that in turn translates into different expression of consciousness (Fingelkurts et al., 2012b). This is a critical point, if we consider that chances of recovery from a DOC (particularly, from a VS) depend on the interaction of two main factors: (i) the degree of impairment of neuronal systems supporting consciousness, and (ii) the amount of spontaneous and rehabilitation-induced plastic changes aimed to restore brain functions and connectivity within nested operational architectonics (Bagnato et al., 2013). If so, the precise measurement of brain dysfunction characteristics will be decisive, as it will allow rehabilitative treatments to be tailored for each patient. In the future, we may test the effectiveness of specific interventions (i.e., cognitive rehabilitations, drugs or neurostimulation) in patients in VS or MCS by evaluating the effects of the treatments on the patients' neuronal assembly characteristics mentioned earlier. We will then be able to choose the best rehabilitative intervention (or a suitable combination of treatments) for each patient with severe DOC by taking in consideration neurophysiological markers that are easily quantifiable at any stage of rehabilitation.

Conflict of Interest Statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

The authors would like to thank Dmitry Skarin for English editing.

References available at the Frontiers site.

UCLA Psychologists Report New Insights on Human Brain, Consciousness (via Tracing Knowledge)

Regions displaying a significant effect of condition on local metrics. (a) Nodal strength (yellow-red colors indicate regions in which degree was stronger, on average, for the S [propofol sedation] and LOC [loss of consciousness] conditions, while blue/light-blue colors indicate regions in which degree was stronger for W [wakefulness] and R [after conscious recovery]). (b) Local efficiency (yellow-red colors indicate regions in which the measure is stronger, on average for the LOC and R conditions). Color intensity is assigned on the basis of the (FDR adjusted) p-value for the condition factor in the 2-way repeated measures ANOVA. (Surface rendering was performed using Caret [98].)  doi:10.1371/journal.pcbi.1003271.g006

An interesting new study from researchers at UCLA has provided insights into what happens in the brain as a person shifts from consciousness to being unconscious following administration of the anesthetic propofol. Not only does this tell us a lot about unconsciousness, it also suggests that consciousness "arises from the mode in which billions of neurons communicate with one another."

Key points:

• Monti and his colleagues used functional magnetic resonance imaging (fMRI) to study how the flow of information in the brains of 12 healthy volunteers (ages 18 to 31, 6 men and 6 women) changed as they lost consciousness under anesthesia with propofol. 
• Analysis of “network properties” of subjects’ brains conducted with graph theory (often used to study air-traffic patterns, information on the Internet, and social groups, among other topics).
• When we become unconsciousness, communication between brain areas becomes extremely inefficient (each area of the brain became very distant from every other, making it difficult for information to travel from one place to another).
• This research shows that consciousness is not a localized event in the brain - it “arises from the mode in which billions of neurons communicate with one another.”

Below is the press release followed by the abstract and author summary of the PLoS Computational Biology article. I found this via the blog, Chasing Knowledge.

UCLA psychologists report new insights on human brain, consciousness

October 17, 2013 | By UCLA Newsroom
Original online publication: UCLA Newsroom
PDF: UCLA psychologists report new insights on human brain, consciousness : UCLA Newsroom

UCLA psychologists have used brain-imaging techniques to study what happens to the human brain when it slips into unconsciousness. Their research, published Oct. 17 in the online journal PLOS Computational Biology, is an initial step toward developing a scientific definition of consciousness.

“In terms of brain function, the difference between being conscious and unconscious is a bit like the difference between driving from Los Angeles to New York in a straight line versus having to cover the same route hopping on and off several buses that force you to take a ‘zig-zag’ route and stop in several places,” said lead study author Martin Monti, an assistant professor of psychology and neurosurgery at UCLA.

Monti and his colleagues used functional magnetic resonance imaging (fMRI) to study how the flow of information in the brains of 12 healthy volunteers changed as they lost consciousness under anesthesia with propofol. The participants ranged in age from 18 to 31 and were evenly divided between men and women.

The psychologists analyzed the “network properties” of the subjects’ brains using a branch of mathematics known as graph theory, which is often used to study air-traffic patterns, information on the Internet and social groups, among other topics.

“It turns out that when we lose consciousness, the communication among areas of the brain becomes extremely inefficient, as if suddenly each area of the brain became very distant from every other, making it difficult for information to travel from one place to another,” Monti said.

The finding shows that consciousness does not “live” in a particular place in our brain but rather “arises from the mode in which billions of neurons communicate with one another,” he said.

When patients suffer severe brain damage and enter a coma or a vegetative state, Monti said, it is very possible that the sustained damage impairs their normal brain function and the emergence of consciousness in the same manner as was seen by the life scientists in the healthy volunteers under anesthesia.

“If this were indeed the case, we could imagine in the future using our technique to monitor whether interventions are helping patients recover consciousness,” he said.

“It could, however, also be the case that losing consciousness because of brain injury affects brain function through different mechanisms,” said Monti, whose research team is currently addressing this question in another study.

“As profoundly defining of our mind as consciousness is, without having a scientific definition of this phenomenon, it is extremely difficult to study,” Monti noted. This study, he said, marks an initial step toward conducting neuroscience research on consciousness.

The research was conducted at Belgium’s University Hospital of Liege.

Monti’s expertise includes cognitive neuroscience, the relationship between language and thought, and how consciousness is lost and recovered after severe brain injury. He was part of a team of American and Israeli brain scientists who used fMRI on former Israeli Prime Minister Ariel Sharon in January 2013 to assess his brain responses.

Surprisingly, Sharon, who was presumed to be in a vegetative state since suffering a brain hemorrhage in 2006, showed significant brain activity, Monti and his colleagues reported.

The former prime minister was scanned to assess the extent and quality of his brain processing, using methods recently developed by Monti and his colleagues. The scientists found subtle but encouraging signs of consciousness.

Co-authors of the current research included Evan Lutkenhoff, a UCLA postdoctoral scholar in Monti’s laboratory; Mikahil Rubinov of Cambridge University in the U.K.; and Steven Laureys, who leads the Coma Science Group at the Cyclotron Research Center and the department of neurology at Belgium’s Sart Tilman Liege University Hospital.

The study was funded primarily by the James S. McDonnell Foundation.

___ Read straight from UCLA Newsroom

Reference paper

Dynamic Change of Global and Local Information Processing in Propofol-Induced Loss and Recovery of Consciousness

Martin M. Monti, Evan S. Lutkenhoff, Mikail Rubinov, Pierre Boveroux, Audrey Vanhaudenhuyse, Olivia Gosseries, Marie-Aurélie Bruno, Quentin Noirhomme, Mélanie Boly, Steven Laureys

Abstract

Whether unique to humans or not, consciousness is a central aspect of our experience of the world. The neural fingerprint of this experience, however, remains one of the least understood aspects of the human brain. In this paper we employ graph-theoretic measures and support vector machine classification to assess, in 12 healthy volunteers, the dynamic reconfiguration of functional connectivity during wakefulness, propofol-induced sedation and loss of consciousness, and the recovery of wakefulness. Our main findings, based on resting-state fMRI, are three-fold. First, we find that propofol-induced anesthesia does not bear differently on long-range versus short-range connections. Second, our multi-stage design dissociated an initial phase of thalamo-cortical and cortico-cortical hyperconnectivity, present during sedation, from a phase of cortico-cortical hypoconnectivity, apparent during loss of consciousness. Finally, we show that while clustering is increased during loss of consciousness, as recently suggested, it also remains significantly elevated during wakefulness recovery. Conversely, the characteristic path length of brain networks (i.e., the average functional distance between any two regions of the brain) appears significantly increased only during loss of consciousness, marking a decrease of global information-processing efficiency uniquely associated with unconsciousness. These findings suggest that propofol-induced loss of consciousness is mainly tied to cortico-cortical and not thalamo-cortical mechanisms, and that decreased efficiency of information flow is the main feature differentiating the conscious from the unconscious brain.

Author Summary

One of the most elusive aspects of the human brain is the neural fingerprint of the subjective feeling of consciousness. While a growing body of experimental evidence is starting to address this issue, to date we are still hard pressed to answer even basic questions concerning the nature of consciousness in humans as well as other species. In the present study we follow a recent theoretical construct according to which the crucial factor underlying consciousness is the modality with which information is exchanged across different parts of the brain. In particular, we represent the brain as a network of regions exchanging information (as is typically done in a comparatively young branch of mathematics referred to as graph theory), and assess how different levels of consciousness induced by anesthetic agent affect the quality of information exchange across regions of the network. Overall, our findings show that what makes the state of propofol-induced loss of consciousness different from all other conditions (namely, wakefulness, light sedation, and consciousness recovery) is the fact that all regions of the brain appear to be functionally further apart, reducing the efficiency with which information can be exchanged across different parts of the network.

___Read straight from PLoS Comput Biol 9(10): e1003271. doi:10.1371/journal.pcbi.1003271