Disrupted functional brain connectivity networks in children with attention-deficit/hyperactivity disorder: evidence from resting-state functional near-infrared spectroscopy

Mengjing Wang; Zhishan Hu; Lu Liu; Haimei Li; Qiujin Qian; Haijing Niu

doi:10.1117/1.NPh.7.1.015012

11 March 2020 Disrupted functional brain connectivity networks in children with attention-deficit/hyperactivity disorder: evidence from resting-state functional near-infrared spectroscopy

Mengjing Wang, Zhishan Hu, Lu Liu, Haimei Li, Qiujin Qian, Haijing Niu

Author Affiliations +

Neurophotonics, Vol. 7, Issue 1, 015012 (March 2020). https://doi.org/10.1117/1.NPh.7.1.015012

Abstract

Significance: Attention-deficit/hyperactivity disorder (ADHD) is the most common psychological disease in childhood. Currently, widely used neuroimaging techniques require complete body confinement and motionlessness and thus are extremely hard for brain scanning of ADHD children.

Aim: We present resting-state functional near-infrared spectroscopy (fNIRS) as an imaging technique to record spontaneous brain activity in children with ADHD.

Approach: The brain functional connectivity was calculated, and the graph theoretical analysis was further applied to investigate alterations in the global and regional properties of the brain network in the patients. In addition, the relationship between brain network features and core symptoms was examined.

Results: ADHD patients exhibited significant decreases in both functional connectivity and global network efficiency. Meanwhile, the nodal efficiency in children with ADHD was also found to be altered, e.g., increase in the visual and dorsal attention networks and decrease in somatomotor and default mode networks, compared to the healthy controls. More importantly, the disrupted functional connectivity and nodal efficiency significantly correlated with dimensional ADHD scores.

Conclusions: We clearly demonstrate the feasibility and potential of fNIRS-based connectome technique in ADHD or other neurological diseases in the future.

1. Introduction

Attention-deficit/hyperactivity disorder (ADHD) is a prevalent childhood-onset neurobehavioral disorder. Typical symptoms are age-inappropriate levels of inattention, hyperactivity, and impulsivity, which often lead them to dysfunctions in academic performance and social skills.¹

Recent neuroimaging studies have demonstrated the disruption of functional or structural brain network organization in children with ADHD.²^–⁶ According to the dual pathway model of ADHD, the main disruptions often occurred in the executive circuit or the reward circuit.⁷^–¹⁰ Recently, evidences also suggest that visual network, which plays a key role in sustained attention,²^,¹¹ exhibits disconnection between the visual and other brain regions in children with ADHD.¹²^,¹³ Furthermore, it has also been found that the brain network topology is altered in children with ADHD.¹⁴^–¹⁹ For example, the ADHD patients exhibited decreased global efficiency and increased local efficiency compared to healthy individuals.¹⁴^,²⁰ These altered functional network characteristics were associated with various of clinical scores of ADHD or deficits in related cognitive functions.⁹^,¹²^,¹³^,²¹^–²³ With these advances, however, the techniques are still frequently argued about complete body confinement and steadiness during brain scanning of children, especially involving children with ADHD due to their hyperactive characteristics.²⁴

Functional near-infrared spectroscopy (fNIRS) is an optics-based brain imaging tool. It shows the advantages of high motion tolerance, few body constraints, and high portability.²⁵ In recent years, fNIRS has been frequently used to explore the neural basis underlying different cognitive demands related to the ADHD, such as inhibition,²⁶ working memory,²⁷ cognitive flexibility,²⁸ attention,²⁹ and emotion regulation.³⁰

Resting state is a natural imaging paradigm, and the resting-state fNIRS (rs-fNIRS) imaging has advantages over task-associated fNIRS.³¹ Due to its convenient operating procedure, rs-fNIRS can be easily operated in clinical practice, especially for child patients. Using rs-fNIRS, our group has demonstrated the feasibility,³² reliability,³³^,³⁴ and reproducibility³⁵ of this technique in characterizing functional connectivity and network topological properties. Furthermore, we and other groups have also demonstrated that rs-fNIRS technique can reveal the changes of brain network organization during normal development³⁶^–⁴⁰ and under psychopathological conditions.⁴¹^–⁴⁷ These studies demonstrate that rs-fNIRS can be a promising tool in identifying disrupted brain networks in children with ADHD.

However, no rs-fNIRS study has been applied to explore the alterations in brain topological organization in ADHD children. To bridge this gap, we conducted an rs-fNIRS study with 30 ADHD patients and 30 healthy controls (HCs). As one of the neurodevelopment disorders, there is growing evidence from fMRI studies supporting both categorical and dimensional aspects of ADHD.⁴⁸^,⁴⁹ Therefore, we hypothesized that the children with ADHD would exhibit aberrant network properties when compared to the HC group, which can assist the categorical diagnosis of ADHD. Furthermore, we hypothesized that these properties would be associated with dimensional ADHD scores.

2. Methods

2.1.

Participants

Sixty participants were recruited for this study, which comprised 30 children with ADHD (boys, 7 to 12 years) and 30 sex-, age-, and education-matched HCs. The children with ADHD were recruited from Peking University Sixth Hospital, Beijing, China, and HCs were enrolled from a primary school in the local community. For the children with ADHD, the inclusion criteria were as follows: (1) a full-scale intelligence quotient $(IQ) \geq 80$ ; (2) right-handed; and (3) drug-naïve and free of other medical intervention. In addition, children with a diagnosis or history of head trauma with loss of consciousness, a history of neurological illness or other severe disease such as epilepsy, schizophrenia, pervasive developmental disorders (including autism spectrum disorders) or mental retardation were excluded.

The ADHD and comorbidities were diagnosed according to the DSM-IV criteria based on a semistructured interview using the clinical diagnostic interview scale⁵⁰^,⁵¹ by an experienced child psychiatrist. Accordingly, the children with ADHD can be categorized into inattentive type [ADHD-I, sample size $(n) = 22$ ] and ADHD combined type (ADHD-C, $n = 8$ ). Meanwhile, 25 of the children with ADHD exhibited comorbidities, such as disruptive behavior ( $n = 8$ ), anxiety disorder ( $n = 2$ ), mood disorder ( $n = 3$ ), tic disorder ( $n = 6$ ), and learning disorder ( $n = 17$ ). In addition, the DSM-IV symptoms of children with ADHD were scored using the ADHD rating scale-IV (ADHD RS-IV) to index the severity of ADHD.⁵² The items were rated on a four-point Likert-type scale (0 = never, 1 = sometimes, 2 = often, and 3 = always) by parents. Accordingly, the “inattentive,” “hyperactive/impulsive,” and “total” scores were computed for each child with ADHD.

This study was approved by the Ethics and Committee of Peking University Sixth Hospital/Institute of Mental Health. All subjects were treated according to the Declaration of Helsinki. Written informed consent was obtained from parents of the children. Meanwhile, the children aged above 10 years old also provided written informed consent by themselves. All the children provided oral consent before the experiment and were free to withdraw from the experiment at any time for any reason without prejudice to future care.

2.2.

fNIRS Data Acquisition and Preprocessing

fNIRS data were collected using a multichannel continuous wave near-infrared optical imaging system (Hui Chuang, China) with a sampling rate of 17 Hz. This system contains 24 light sources and 28 detectors. The optode arrays generated 80 different measurement channels with a fixed 3-cm interoptode distance, which covered primary regions of the whole head, e.g., frontal, temporal, parietal, and visual cortexes [Figs. 1(a) and 1(b)]. The optodes were placed according to the international 10–20 system, with the external auditory canals and vertex as the reference points. A resting-state fNIRS signal recording was lasted at least 12 min. During the recording, the participants were instructed to sit still and close their eyes without falling asleep. Such resting-state recording did not require overt perceptual input or behavioral output. Positions of the measurement channels were labeled by vitamin E capsules on an arbitrarily chosen participant, which were visible in the structural MRI imaging from a Siemens 3.0 Tesla scanner. According to the obtained spatial coordinates, these channels were displayed on Yeo et al.’s network template⁵³ [Fig. 1(c)], in which six functional networks (i.e., the default, frontoparietal control, ventral attention, somatomotor, dorsal attention, and visual networks) were presented and labeled by different colors.

Fig. 1

Schematic diagram of experimental data acquisition. (a) Photo obtained from a participant during the data collection. (b) Optodes and channels. The red circles represent the sources and the blue circles represent the detectors. Meanwhile, the green lines linking the sources and detectors represent the formed measurement channels. (c) The arrangement of the whole-head 80 measurement channels on a functional network brain template.⁵³

We used an in-house FC-NIRS package²⁵ to preprocess the fNIRS data. Similar to our previous studies,³³ a bandpass filter (0.01 to 0.1 Hz) was first conducted to eliminate the effects of low-frequency drift and high-frequency neurophysiological noise. Subsequently, we calculated the relative changes in the concentrations of oxygen-hemoglobin and deoxygen-hemoglobin using the modified Beer–Lambert law.³² Then we extracted 8 min stable hemoglobin time series for each participant. Finally, similar to our previous studies,³³^,³⁶^,⁴⁵^,⁴⁶ we conducted a temporal independent component analysis to remove systematic physiological noise (e.g., superficial signal) and motion-induced artifacts.⁵⁴ Specifically, these noise components were identified according to the components’ temporal profiles, spatial maps, and power spectra. A component would be considered noise if it met one of the following criteria: (1) the corresponding temporal profile included sudden jumps, slowly varied U or inverted U-shaped spike, or numerous intercurrent quick spikes (e.g., motion artifacts); (2) the dominant frequency of power spectra of the component was outside the range of 0.01 to 0.1 Hz; and (3) the spatial map of the component presented a global and spatially dispersive pattern (e.g., physiological interference). Once the noise components were identified, the concentration signal was subsequently reconstructed with these particular components eliminated from the original hemoglobin time course. The filtered concentration signal was used for further analysis. In this study, we used oxy-hemoglobin signal to present the following results because the HbO signal generally has a better signal-to-noise ratio than the HbR signal.⁵⁵

2.3.

Functional Connectivity Calculation and Brain Network Construction

For each participant, functional connectivity was calculated by conducting Pearson correlation analyses between time series of every pair of nodes, where the nodes were the measurement channels. This procedure generated an $80 \times 80$ correlation matrix for each participant. Of note, these correlation coefficients ( $r$ ) were normalized to $z$ -values with Fisher’s $r$ -to- $z$ transformation. With a predetermined sparsity that denotes the number of actual connections divided by the maximum possible number of connections in the network, the correlation matrix was then thresholded into a binary matrix that described the topological organization of the functional networks. As in our previous studies,³⁶^,³⁷ we chose the sparsity of 0.2 to construct the brain network.

2.4.

Brain Network Analysis

A graph theory method was used to characterize the topological organization of the brain functional networks in the ADHD and HC groups. Network measures were calculated using our FC-NIRS package.²⁵ In fNIRS-derived brain network studies, topological network efficiency has been frequently used to characterize the capacity of parallel information processing within a brain network. We, therefore, focused on efficiency-related parameters, i.e., nodal efficiency, global efficiency, and local efficiency, to examine the differences in these efficiency measures between the ADHD and HC groups. The definitions for these parameters are described below.

The global efficiency $E_{glob}$ represents the information transfer efficiency across the network, which is defined as the inverse of the harmonic mean of the shortest path length between any two nodes⁵⁶

Eq. (1)

E_{glob} = \frac{1}{N (N - 1)} \sum_{i \neq j \in G} \frac{1}{d_{i j}},

where

d_{i j}

is the shortest path length between node

i

and node

j

. Meanwhile, the local efficiency

E_{loc}

is defined as the average global efficiency of all subgraphs of the neighbors of node

i

(

G_{i}

)

Eq. (2)

E_{loc} = \frac{1}{N} \sum_{i \in G} E_{glob} (G_{i}) .

In addition, for a given node $i$ , its efficiency in information transfer is measured by $E_{nod}$ , which is defined as the harmonic mean of the shortest path length between this node and its neighbors

Eq. (3)

E_{nod} = \frac{1}{N - 1} \sum_{i \neq j \in G} \frac{1}{d_{i j}} .

2.5.

Statistical Analysis

Two-sample $t$ -tests were adopted to compare the differences in demographics or core symptoms between the ADHD and HC groups. For functional connectivity, a network-based statistic approach⁴⁶^,⁵⁷ was adopted to compare the functional connectivity differences between the ADHD and HC groups. Specifically, two-sample $t$ -tests with a threshold of $p < 0.001$ were performed to identify the suprathreshold connections. These connections formed one or more subgraphs (components). Subsequently, 1000 permutations were performed to determine the significance of each component. Finally, the most significant component was selected to represent the altered functional connectivity. Furthermore, previous studies have found that the analogous regions in the resting-state network are strongly connected,⁵⁸ and altered homotopic connectivity has been associated with many psychiatric conditions.⁵⁹^–⁶¹ In order to characterize the spatial attributes of the altered functional connectivity, we categorized the altered functional connectivity into three spatially different groups: (1) homotopic connectivity, denoting the interhemispheric connectivity between homologous regions; (2) intrahemispheric connectivity, denoting the connectivity between regions in the same hemisphere; and (3) heterotopic connectivity, denoting the interhemispheric connectivity that was not homotopic connectivity.⁶² For network efficiency, two-sample $t$ -tests were also adopted to compare the differences between groups.

2.6.

Relationship Between Altered Brain Functional Connectivity/Network Features and ADHD Core Symptoms

To test the associations between altered brain functional connectivity/network features and core symptoms (e.g., inattentive, hyperactive/impulsive, and total scores) in ADHD, Pearson correlation analyses were performed in the ADHD group with significance threshold of $p < 0.05$ . Before the correlation analyses, the effects of age, sex, and years of education were removed by multiple linear regression.

3. Results

3.1.

Demographic and Core Symptoms

The $t$ -test results for the demographic and core symptoms between the two groups are listed in Table 1. The ADHD and HC groups showed no significant differences in age or IQ. However, the children with ADHD exhibited significantly higher scores in core symptoms including inattentive, hyperactive/impulsive, and total scores ( $p < 0.01$ ) compared to the HCs.

Table 1

The demographic and clinical characteristics of children with ADHD and HCs.

	ADHD (n=30)	HC (n=30)	t value	p value
Age in month ( $mean \pm SD$ )	$114.8 \pm 19.2$	$113.7 \pm 10.0$	0.28	0.782
IQ ( $mean \pm SD$ )	$109.8 \pm 12.9$	$115.7 \pm 12.6$	$- 1.82$	0.075
ADHD symptoms ( $mean \pm SD$ )
Inattentive	$16.1 \pm 2.9$	$8.6 \pm 4.7$	7.52	$< 0.001$
Hyperactive/impulsive	$10.9 \pm 5.4$	$7.0 \pm 4.8$	2.98	0.004
Total	$27.0 \pm 6.6$	$15.6 \pm 8.7$	5.73	$< 0.001$

3.2.

Decreased Functional Connectivity in Children with ADHD

Figure 2(a) shows the group-averaged connectivity strength in children with ADHD and HC groups. It was found that the averaged connectivity strength in ADHD was much lower (e.g., in somatomotor and dorsal attention networks) than that in HC although the spatial patterns of the functional connectivity maps between two groups exhibited obvious similarity. Quantitatively, the mean values of connectivity strength and its standard deviations were $0.37 \pm 0.13$ for ADHD group and $0.42 \pm 0.14$ for HC group [Fig. 2(b)]. Furthermore, the number of functional connectivity strength lower than 0.4 was much larger in ADHD group compared to that in HC group [Fig. 2(c)].

Fig. 2

Spatial patterns of the functional connectivity in ADHD and HC groups. (a) Functional connectivity maps for these two groups. (b) Histograms of the functional connectivity distribution. The functional connectivity displayed approximately normal configuration in both ADHD and HC groups. (c) The stacked bar chart of functional connectivity across different thresholds.

Figure 3 shows the statistical differences in functional connectivity between ADHD and HC groups, in which significantly decreased functional connectivity was consistently found in ADHD group ( $p < 0.05$ ). Specifically, the changes in homotopic functional connectivity were mainly located in the default mode network, visual network, and between frontoparietal and dorsal attention networks. For intrahemispheric functional connectivity, the significantly altered connectivity was primarily centered in the right hemisphere involving the regions of default mode network, dorsal attention network and visual networks. For heterotopic functional connectivity, the changes were mainly located in the regions of frontoparietal and somatomotor networks in the right hemisphere and the regions of parietal and visual cortex in the left hemisphere.

Fig. 3

Significantly decreased functional connectivity in children with ADHD. The decreased functional connectivity was categorized into three groups: homotopic, intrahemispheric, and heterotopic connections. The dots represent measurement channels, and the colors label the cortical location of these channels.

3.3.

Disrupted Brain Network Topology in Children with ADHD

For global network properties, the global efficiency in children with ADHD significantly decreased as compared to that in the HC group [Fig. 4(a)]. However, no significant difference was found in the local efficiency between two groups [Fig. 4(b)].

Fig. 4

Group differences in (a) global, (b) local, and (c) nodal efficiencies. In (c), the red circles with white and black points indicate that the nodal efficiency significantly decreased and increased, respectively, in children with ADHD as compared to HC group.

For regional nodal characteristic, the ADHD group exhibited both decreased and increased nodal efficiency in some primary brain regions [Fig. 4(c)] ( $p < 0.05$ ). Specifically, the decreased nodal efficiency was mainly located in the right hemisphere involving the somatomotor, default mode, and frontoparietal networks, and the increased nodal efficiency was mainly located in the left hemisphere involving the visual and dorsal attention networks.

3.4.

Relationship Between Brain Network Features and Core Symptoms

Figure 5 shows the correlation relationships between functional connectivity and core symptoms. Four functional connections were found to be associated with the core symptoms. Specifically, functional connectivity that linked the left frontoparietal and right somatomotor networks [green line in Fig. 5(a)] showed a significantly negative correlation with the hyperactive/impulsive score in the children with ADHD [Fig. 5(b)]. The functional connectivity that linked the right frontoparietal and visual networks [brown lines in Fig. 5(a)] showed a significantly negative correlation with both the hyperactive/impulsive score and the total score in the children with ADHD [Fig. 5(c)].

Fig. 5

The relationship between functional connectivity and core symptoms in the ADHD group. (a) The connections showed significant correlation with core symptoms. (b) The scatter plotted between core symptoms and functional connectivity. (c) The scatter plotted between core symptoms and mean functional connectivity between right frontoparietal and visual networks.

For nodal efficiency, we identified one node in the right somatomotor network, as indicated by a black arrow in Fig. 6(a), showed a significantly negative correlation with both the hyperactive/impulsive and the total scores [Figs. 6(b) and 6(c)]. For the global and local network efficiency measures, no significant correlations were found between these features and core symptoms.

Fig. 6

The relationship between nodal efficiency in the right somatomotor network and core symptoms.

4. Discussion

The categorical–dimensional hybrid model of ADHD has provided insights to the pathophysiological mechanisms of this disorder in recent years.⁴⁸^,⁴⁹ In this study, we used the rs-fNIRS and network analysis approach to study functional connectivity and topological network characteristics in the children with ADHD and the HC group, from the both categorical and dimensional perspectives. From the categorical perspective, we observed significant group differences as demonstrated by widespread reduction of functional connectivity strength, global network efficiency, and regional nodal efficiency in ADHD group. From the dimensional perspective, the disrupted functional connectivity and nodal efficiency significantly correlated with dimensional ADHD scores.

This study showed that children with ADHD, compared to the HCs, exhibited decreased homotopic, intrahemispheric, and heterotopic functional connectivity (i.e., disconnection). Specifically, the decreased homotopic connectivity was primarily located in the prefrontal cortices and bilateral posterior cortices involving dorsal attention networks and visual networks, which are, respectively, related to executive,⁶³ attention,⁶⁴ and visual sensory processing.⁶⁵ Impairments in these cognitive processes have long been associated with ADHD.⁶⁶ As such, our results are compatible with the previous findings and demonstrated the importance of the homotopic connectivity in cognitive functions;⁵⁹^–⁶¹ they further reveal that decreased homotopic functional connectivity impairs corresponding cognitive processes, which causes the ADHD symptoms. In addition, the disconnection between visual network and other cortical regions in our study is in line with the studies suggesting the potential important role of the visual network in ADHD.¹²^,¹³ Furthermore, the disconnection between frontoparietal network and visual/attention networks in this study provides further evidence for the dual pathway model of ADHD,⁷ in which weaker regulation in the executive circuit from the frontal cortex to the visual and attention networks was identified. Moreover, previous studies also found that dysfunctions in the right prefrontal cortex were associated with ADHD.²⁶^,⁶⁷

We also found decreased global efficiency in the ADHD group, which are consistent with the previous investigations from fMRI-derived network analysis in the patient group.¹⁴^,²⁰ In addition, we identified decreased nodal efficiency in the right hemisphere involving the default mode, somatomotor, and frontoparietal networks, as well as the increased nodal efficiency in the left hemisphere involving the dorsal attention and visual networks. According to the dual pathway model, it is reasonable to assume that the ADHD symptoms are associated with insufficient coordination between default mode, somatomotor, and frontoparietal networks and other brain regions, and the information overload in visual and attention networks.

The correlation results further confirmed the relationship between the functional connectivity network and ADHD symptoms. Specifically, decreased connectivity between the frontoparietal network and visual network was associated with increased hyperactive/impulsive and total scores in ADHD. This provides further evidence that the insufficient coordination between frontal cortex and visual networks may underlie the hyperactive/impulsive symptom in ADHD. In addition, the decreased nodal efficiencies in the right somatomotor network showed a negative correlation with the hyperactive/impulsive and total scores, which suggests that children with hyperactive/impulsive symptoms tended to have reduced information processing efficiency in the brain regions, i.e., somatomotor regions.

Despite the intriguing findings in our study, several issues need to be addressed. First, the approach adopted in this study should be applied to a larger sample to validate its robustness. Second, only the boys with ADHD were enrolled in this study, which limited the examination of the influence from gender differences on the current findings.⁶⁸ Third, most of the participants in this study exhibited comorbidities. It is known that ADHD-related comorbidities would affect neurological change of the spontaneous brain activity of the patients.⁶⁹^,⁷⁰ However, due to the relatively small sample size in this study, it remains unknown how the comorbidities would influence the current findings. Further sample collection in the future may provide better understanding of the potential confounding effects of comorbidities. Fourth, diagnosis of ADHD at an earlier age is critical for the earlier medical intervention, and applying our current approach to the infant and natal subjects benefits the diagnosis of ADHD. Last but not least, longitude investigation is highly preferable to reveal the neural development of ADHD.

It is noteworthy that the diagnosis of ADHD still heavily relies on the clinical information provided by parents and teachers and the ratings of the ADHD presentations.⁷¹ More quantitative biomarkers for ADHD benefit the diagnostic and therapeutic assessment of ADHD. Our current study validated rs-fNIRS as a potential tool in characterizing cortical network changes in patients with ADHD, which can serve as a potential biomarker for the diagnosis of ADHD.

5. Conclusions

In summary, we validated that the rs-fNIRS is a promising technique to characterize the topological network properties associated with ADHD. This study not only provides potential biomarkers for the diagnosis of ADHD but also has potential application for the investigation of neural basis underlying development, aging, and neurological diseases.

Disclosures

The authors declare no conflicts of interest.

Acknowledgments

This study was supported by the National Natural Science Foundation of China (Nos. 81761148026, 81571340, 81571755, and 81873802).

References

1.

S. P. Hinshaw, “Attention deficit hyperactivity disorder (ADHD): controversy, developmental mechanisms, and multiple levels of analysis,” Annu. Rev. Clin. Psychol., 14 291 –316 (2018). https://doi.org/10.1146/annurev-clinpsy-050817-084917 1548-5943 Google Scholar

2.

F. X. Castellanos and E. Proal, “Large-scale brain systems in ADHD: beyond the prefrontal-striatal model,” Trends in Cognit. Sci., 16 (1), 17 –26 (2012). https://doi.org/10.1016/j.tics.2011.11.007 TCSCFK 1364-6613 Google Scholar

3.

A. Cubillo et al., “A review of fronto-striatal and fronto-cortical brain abnormalities in children and adults with attention deficit hyperactivity disorder (ADHD) and new evidence for dysfunction in adults with ADHD during motivation and attention,” Cortex, 48 (2), 194 –215 (2012). https://doi.org/10.1016/j.cortex.2011.04.007 Google Scholar

4.

K. Konrad and S. B. Eickhoff, “Is the ADHD brain wired differently? A review on structural and functional connectivity in attention deficit hyperactivity disorder,” Hum. Brain Mapp., 31 (6), 904 –916 (2010). https://doi.org/10.1002/hbm.21058 HBRME7 1065-9471 Google Scholar

5.

M. Oldehinkel et al., “Functional connectivity in cortico-subcortical brain networks underlying reward processing in attention-deficit/hyperactivity disorder,” Neuroimage Clin., 12 796 –805 (2016). https://doi.org/10.1016/j.nicl.2016.10.006 Google Scholar

6.

P. Shaw et al., “Attention-deficit/hyperactivity disorder is characterized by a delay in cortical maturation,” Proc. Natl. Acad. Sci. U. S. A., 104 (49), 19649 –19654 (2007). https://doi.org/10.1073/pnas.0707741104 Google Scholar

7.

E. J. S. Sonuga-Barke, “The dual pathway model of AD/HD: an elaboration of neuro-developmental characteristics,” Neurosci. Biobehav. Rev., 27 (7), 593 –604 (2003). https://doi.org/10.1016/j.neubiorev.2003.08.005 NBREDE 0149-7634 Google Scholar

8.

N. D. Volkow et al., “Motivation deficit in ADHD is associated with dysfunction of the dopamine reward pathway,” Mol. Psychiatry, 16 (11), 1147 –1154 (2011). https://doi.org/10.1038/mp.2010.97 Google Scholar

9.

F. D. Zepf et al., “Functional connectivity of the vigilant-attention network in children and adolescents with attention-deficit/hyperactivity disorder,” Brain Cognit., 131 56 –65 (2019). https://doi.org/10.1016/j.bandc.2017.10.005 Google Scholar

10.

D. Tomasi and N. D. Volkow, “Abnormal functional connectivity in children with attention-deficit/hyperactivity disorder,” Biol. Psychiatry, 71 (5), 443 –450 (2012). https://doi.org/10.1016/j.biopsych.2011.11.003 BIPCBF 0006-3223 Google Scholar

11.

X. Li et al., “Atypical pulvinar-cortical pathways during sustained attention performance in children with attention-deficit/hyperactivity disorder,” J. Am. Acad. Child Adolesc. Psychiatry, 51 (11), 1197 –1207.e4 (2012). https://doi.org/10.1016/j.jaac.2012.08.013 Google Scholar

12.

C. Zhan et al., “Structural and functional abnormalities in children with attention-deficit/hyperactivity disorder: a focus on subgenual anterior cingulate cortex,” Brain Connect, 7 (2), 106 –114 (2017). https://doi.org/10.1089/brain.2016.0444 Google Scholar

13.

Q. Lin et al., “Aberrant white matter properties of the callosal tracts implicated in girls with attention-deficit/hyperactivity disorder,” Brain Imaging Behav., (2018). Google Scholar

14.

L. Wang et al., “Altered small-world brain functional networks in children with attention-deficit/hyperactivity disorder,” Hum. Brain Mapp., 30 (2), 638 –649 (2009). https://doi.org/10.1002/hbm.20530 HBRME7 1065-9471 Google Scholar

15.

Q. Cao et al., “Probabilistic diffusion tractography and graph theory analysis reveal abnormal white matter structural connectivity networks in drug-naive boys with attention deficit/hyperactivity disorder,” J. Neurosci., 33 (26), 10676 –10687 (2013). https://doi.org/10.1523/JNEUROSCI.4793-12.2013 JNRSDS 0270-6474 Google Scholar

16.

J. F. Saad et al., “Regional brain network organization distinguishes the combined and inattentive subtypes of attention deficit hyperactivity disorder,” NeuroImage: Clin., 15 383 –390 (2017). https://doi.org/10.1016/j.nicl.2017.05.016 Google Scholar

17.

J. Hong et al., “Age-related connectivity differences between attention deficit and hyperactivity disorder patients and typically developing subjects: a resting-state functional MRI study,” Neural Regener. Res., 12 (10), 1640 –1647 (2017). https://doi.org/10.4103/1673-5374.217339 Google Scholar

18.

M. Cao et al., “Imaging functional and structural brain connectomics in attention-deficit/hyperactivity disorder,” Mol. Neurobiol., 50 (3), 1111 –1123 (2014). https://doi.org/10.1007/s12035-014-8685-x MONBEW 0893-7648 Google Scholar

19.

L. Marcos-Vidal et al., “Local functional connectivity suggests functional immaturity in children with attention-deficit/hyperactivity disorder,” Hum. Brain Mapp., 39 (6), 2442 –2454 (2018). https://doi.org/10.1002/hbm.24013 HBRME7 1065-9471 Google Scholar

20.

P. Lin et al., “Global and local brain network reorganization in attention-deficit/hyperactivity disorder,” Brain Imaging Behav., 8 (4), 558 –569 (2013). https://doi.org/10.1007/s11682-013-9279-3 Google Scholar

21.

M. D. Rosenberg et al., “A neuromarker of sustained attention from whole-brain functional connectivity,” Nat. Neurosci., 19 (1), 165 –171 (2015). https://doi.org/10.1038/nn.4179 NANEFN 1097-6256 Google Scholar

22.

M. Oldehinkel et al., “Attention-deficit/hyperactivity disorder symptoms coincide with altered striatal connectivity,” Biol. Psychiatry Cognit. Neurosci. Neuroimaging, 1 (4), 353 –363 (2016). https://doi.org/10.1016/j.bpsc.2016.03.008 Google Scholar

23.

X. H. Wang, Y. Jiao and L. Li, “Predicting clinical symptoms of attention deficit hyperactivity disorder based on temporal patterns between and within intrinsic connectivity networks,” Neuroscience, 362 60 –69 (2017). https://doi.org/10.1016/j.neuroscience.2017.08.038 Google Scholar

24.

F. X. Castellanos and Y. Aoki, “Intrinsic functional connectivity in attention-deficit/hyperactivity disorder: a science in development,” Biol. Psychiatry Cognit. Neurosci. Neuroimaging, 1 (3), 253 –261 (2016). https://doi.org/10.1016/j.bpsc.2016.03.004 Google Scholar

25.

J. Xu et al., “FC-NIRS: a functional connectivity analysis tool for near-infrared spectroscopy data,” BioMed. Res. Int., 2015 248724 (2015). https://doi.org/10.1155/2015/248724 Google Scholar

26.

Y. Monden et al., “Individual classification of ADHD children by right prefrontal hemodynamic responses during a go/no-go task as assessed by fNIRS,” Neuroimage Clin., 9 1 –12 (2015). https://doi.org/10.1016/j.nicl.2015.06.011 Google Scholar

27.

W. A. Knowles, “Reduced lateral prefrontal activation in adult patients with attention-deficit/hyperactivity disorder (ADHD) during a working memory task: a functional near-infrared spectroscopy (fNIRS) study,” Adv. Exp. Med. Biol., 577 (13), 19 –45 (2006). https://doi.org/10.1016/j.jpsychires.2007.11.011 AEMBAP 0065-2598 Google Scholar

28.

J. A. King et al., “Inefficient cognitive control in adult ADHD: evidence from trial-by-trial Stroop test and cued task switching performance,” Behav. Brain Funct., 3 42 (2007). https://doi.org/10.1186/1744-9081-3-42 1744-9081 Google Scholar

29.

P. Weber, J. Lutschg and H. Fahnenstich, “Cerebral hemodynamic changes in response to an executive function task in children with attention-deficit hyperactivity disorder measured by near-infrared spectroscopy,” J. Dev. Behav. Pediatr., 26 (2), 105 –111 (2005). https://doi.org/10.1097/00004703-200504000-00005 JDBPD5 0196-206X Google Scholar

30.

H. Ichikawa et al., “Hemodynamic response of children with attention-deficit and hyperactive disorder (ADHD) to emotional facial expressions,” Neuropsychologia, 63 51 –58 (2014). https://doi.org/10.1016/j.neuropsychologia.2014.08.010 NUPSA6 0028-3932 Google Scholar

31.

H. Niu and Y. He, “Resting-state functional brain connectivity: lessons from functional near-infrared spectroscopy,” Neuroscientist, 20 (2), 173 –188 (2014). https://doi.org/10.1177/1073858413502707 NROSFJ 1073-8584 Google Scholar

32.

H. J. Niu et al., “Revealing topological organization of human brain functional networks with resting-state functional near infrared spectroscopy,” PLoS One, 7 (9), e45771 (2012). https://doi.org/10.1371/journal.pone.0045771 POLNCL 1932-6203 Google Scholar

33.

H. Niu et al., “Test-retest reliability of graph metrics in functional brain networks: a resting-state fNIRS study,” PLoS One, 8 (9), e72425 (2013). https://doi.org/10.1371/journal.pone.0072425 POLNCL 1932-6203 Google Scholar

34.

M. Wang, Z. Yuan and H. Niu, “Reliability evaluation on weighted graph metrics of fNIRS brain networks,” Quant. Imaging Med. Surg., 9 (5), 832 –841 (2019). https://doi.org/10.21037/qims Google Scholar

35.

H. Niu et al., “Resting-state functional connectivity assessed with two diffuse optical tomographic systems,” J. Biomed. Opt., 16 (4), 046006 (2011). https://doi.org/10.1117/1.3561687 JBOPFO 1083-3668 Google Scholar

36.

L. Cai, Q. Dong and H. Niu, “The development of functional network organization in early childhood and early adolescence: a resting-state fNIRS study,” Dev. Cognit. Neurosci., 30 223 –235 (2018). https://doi.org/10.1016/j.dcn.2018.03.003 Google Scholar

37.

L. Cai et al., “Functional near-infrared spectroscopy evidence for the development of topological asymmetry between hemispheric brain networks from childhood to adulthood,” Neurophotonics, 6 (2), 025005 (2019). https://doi.org/10.1117/1.NPh.6.2.025005 Google Scholar

38.

J. P. Culver et al., “Optical imaging of functional connectivity at the bedside,” Conf. Proc. IEEE Eng. Med. Biol. Soc., 2016 65 –67 (2016). https://doi.org/10.1109/EMBC.2016.7590641 Google Scholar

39.

B. R. White et al., “Bedside optical imaging of occipital resting-state functional connectivity in neonates,” Neuroimage, 59 (3), 2529 –2538 (2012). https://doi.org/10.1016/j.neuroimage.2011.08.094 NEIMEF 1053-8119 Google Scholar

40.

L. Li et al., “Whole-cortical graphical networks at wakeful rest in young and older adults revealed by functional near-infrared spectroscopy,” Neurophotonics, 5 (3), 035004 (2018). https://doi.org/10.1117/1.NPh.5.3.035004 Google Scholar

41.

J. Li et al., “Characterization of autism spectrum disorder with spontaneous hemodynamic activity,” Biomed. Opt. Express, 7 (10), 3871 –3881 (2016). https://doi.org/10.1364/BOE.7.003871 BOEICL 2156-7085 Google Scholar

42.

M. Imai et al., “Functional connectivity of the cortex of term and preterm infants and infants with Down’s syndrome,” NeuroImage, 85 272 –278 (2014). https://doi.org/10.1016/j.neuroimage.2013.04.080 NEIMEF 1053-8119 Google Scholar

43.

J. Cao et al., “Evaluation of cortical plasticity in children with cerebral palsy undergoing constraint-induced movement therapy based on functional near-infrared spectroscopy,” J. Biomed. Opt., 20 (4), 046009 (2015). https://doi.org/10.1117/1.JBO.20.4.046009 JBOPFO 1083-3668 Google Scholar

44.

Y. C. Song et al., “Intraoperative optical mapping of epileptogenic cortices during non-ictal periods in pediatric patients,” Neuroimage-Clin., 11 423 –434 (2016). https://doi.org/10.1016/j.nicl.2016.02.015 Google Scholar

45.

X. Y. Li et al., “Decreased resting-state brain signal complexity in patients with mild cognitive impairment and Alzheimer’s disease: a multi-scale entropy analysis,” Biomed. Opt. Express, 9 (4), 1916 –1929 (2018). https://doi.org/10.1364/BOE.9.001916 BOEICL 2156-7085 Google Scholar

46.

H. Niu et al., “Abnormal dynamic functional connectivity and brain states in Alzheimer’s diseases: functional near-infrared spectroscopy study,” Neurophotonics, 6 (2), 025010 (2019). https://doi.org/10.1117/1.NPh.6.2.025010 Google Scholar

47.

T. Fekete et al., “Small-world network properties in prefrontal cortex correlate with predictors of psychopathology risk in young children: a NIRS study,” NeuroImage, 85 345 –353 (2014). https://doi.org/10.1016/j.neuroimage.2013.07.022 NEIMEF 1053-8119 Google Scholar

48.

R. H. R. Pruim et al., “An integrated analysis of neural network correlates of categorical and dimensional models of attention-deficit/hyperactivity disorder,” Biol. Psychiatry Cognit. Neurosci. Neuroimaging, 4 (5), 472 –483 (2019). https://doi.org/10.1016/j.bpsc.2018.11.014 Google Scholar

49.

A. Elton, S. Alcauter and W. Gao, “Network connectivity abnormality profile supports a categorical-dimensional hybrid model of ADHD,” Hum. Brain Mapp., 35 (9), 4531 –4543 (2014). https://doi.org/10.1002/hbm.22492 HBRME7 1065-9471 Google Scholar

50.

R. A. Barkley, “Attention-deficit hyperactivity disorder,” Sci. Am., 279 (3), 66 –71 (1998). https://doi.org/10.1038/scientificamerican0998-66 SCAMAC 0036-8733 Google Scholar

51.

L. Yang et al., “DSM-IV subtypes of ADHD in a Chinese outpatient sample,” J. Am. Acad. Child Adolesc. Psychiatry, 43 (3), 248 –250 (2004). https://doi.org/10.1097/00004583-200403000-00004 Google Scholar

52.

S. Linyan, G. Yaoguo and W. Hong, “Norm of ADHD diagnostic scale-parent version in Chinese urban children,” Chin. J. Pract. Pediatr., 21 833 –836 (2006). Google Scholar

53.

B. T. T. Yeo et al., “The organization of the human cerebral cortex estimated by intrinsic functional connectivity,” J. Neurophysiol., 106 (3), 1125 –1165 (2011). https://doi.org/10.1152/jn.00338.2011 JONEA4 0022-3077 Google Scholar

54.

H. Zhang et al., “Functional connectivity as revealed by independent component analysis of resting-state fNIRS measurements,” Neuroimage, 51 (3), 1150 –1161 (2010). https://doi.org/10.1016/j.neuroimage.2010.02.080 NEIMEF 1053-8119 Google Scholar

55.

G. Strangman et al., “A quantitative comparison of simultaneous BOLD fMRI and NIRS recordings during functional brain activation,” Neuroimage, 17 (2), 719 –731 (2002). https://doi.org/10.1006/nimg.2002.1227 NEIMEF 1053-8119 Google Scholar

56.

V. Latora and M. Marchiori, “Efficient behavior of small-world networks,” Phys. Rev. Lett., 87 (19), 198701 –198704 (2001). https://doi.org/10.1103/PhysRevLett.87.198701 PRLTAO 0031-9007 Google Scholar

57.

A. Zalesky, A. Fornito and E. T. Bullmore, “Network-based statistic: identifying differences in brain networks,” NeuroImage, 53 (4), 1197 –1207 (2010). https://doi.org/10.1016/j.neuroimage.2010.06.041 NEIMEF 1053-8119 Google Scholar

58.

S. M. Smith et al., “Correspondence of the brain’s functional architecture during activation and rest,” 13040 –13045 (2009). https://doi.org/10.1073/pnas.0905267106 Google Scholar

59.

M. Hermesdorf et al., “Major depressive disorder: findings of reduced homotopic connectivity and investigation of underlying structural mechanisms,” Hum. Brain Mapp., 37 (3), 1209 –1217 (2016). https://doi.org/10.1002/hbm.23097 HBRME7 1065-9471 Google Scholar

60.

C. Kelly et al., “Reduced interhemispheric resting state functional connectivity in cocaine addiction,” Biol. Psychiatry, 69 (7), 684 –692 (2011). https://doi.org/10.1016/j.biopsych.2010.11.022 BIPCBF 0006-3223 Google Scholar

61.

J. S. Anderson et al., “Decreased interhemispheric functional connectivity in autism,” Cereb. Cortex, 21 (5), 1134 –1146 (2011). https://doi.org/10.1093/cercor/bhq190 53OPAV 1047-3211 Google Scholar

62.

L. E. Engelhardt et al., “Genes unite executive functions in childhood,” Psychol. Sci., 26 (8), 1151 –1163 (2015). https://doi.org/10.1177/0956797615577209 1467-9280 Google Scholar

63.

Z. Hu et al., “Linking brain activation to topological organization in the frontal lobe as a synergistic indicator to characterize the difference between various cognitive processes of executive functions,” Neurophotonics, 6 (2), 025008 (2019). https://doi.org/10.1117/1.NPh.6.2.025008 Google Scholar

64.

E. C. Cieslik et al., “Three key regions for supervisory attentional control: evidence from neuroimaging meta-analyses,” Neurosci. Biobehav. Rev., 48 22 –34 (2015). https://doi.org/10.1016/j.neubiorev.2014.11.003 NBREDE 0149-7634 Google Scholar

65.

M. A. Nazari et al., “Visual sensory processing deficit in the occipital region in children with attention-deficit / hyperactivity disorder as revealed by event-related potentials during cued continuous performance test,” Neurophysiol. Clin., 40 (3), 137 –149 (2010). https://doi.org/10.1016/j.neucli.2010.03.001 Google Scholar

66.

R. A. Barkley, “Behavioral inhibition, sustained attention, and executive functions: constructing a unifying theory of ADHD,” Psychol. Bull., 121 (1), 65 –94 (1997). https://doi.org/10.1037/0033-2909.121.1.65 PSBUAI 0033-2909 Google Scholar

67.

Y. Monden et al., “Right prefrontal activation as a neuro-functional biomarker for monitoring acute effects of methylphenidate in ADHD children: an fNIRS study,” NeuroImage: Clin., 1 (1), 131 –140 (2012). https://doi.org/10.1016/j.nicl.2012.10.001 Google Scholar

68.

D. Tomasi and N. D. Volkow, “Gender differences in brain functional connectivity density,” Hum. Brain Mapp., 33 (4), 849 –860 (2012). https://doi.org/10.1002/hbm.v33.4 HBRME7 1065-9471 Google Scholar

69.

C. Tye et al., “Altered neurophysiological responses to emotional faces discriminate children with ASD, ADHD and ASD plus ADHD,” Biol. Psychol., 103 125 –134 (2014). https://doi.org/10.1016/j.biopsycho.2014.08.013 Google Scholar

70.

A. Brown et al., “Working memory network alterations and associated symptoms in adults with ADHD and Bipolar Disorder,” J. Psychiatric Res., 46 (4), 476 –483 (2012). https://doi.org/10.1016/j.jpsychires.2012.01.008 JPYRA3 0022-3956 Google Scholar

71.

J. J. McGough and J. T. McCracken, “Assessment of attention deficit hyperactivity disorder: a review of recent literature,” Curr. Opin. Pediatr., 12 (4), 319 –324 (2000). https://doi.org/10.1097/00008480-200008000-00006 COPEE9 Google Scholar

Biography

Mengjing Wang received her bachelor’s degree in biomedical engineering from the Central South University in 2017. She is a postgraduate at the State Key Laboratory of Cognitive Neuroscience of Beijing Normal University. Her research interests are using fNIRS combined with graph theory to explore mental diseases, such as attention-deficit hyperactivity disorder and Alzheimer’s disease.

Zhishan Hu is a postdoctoral research fellow at the State Key Laboratory of Cognitive Neuroscience of Beijing Normal University. His research is focused on the use of functional near-infrared spectroscopy (fNIRS) in neuroscience investigation. These investigations include fNIRS signal processing, cognitive mechanism underlying psychiatric disorders and aging, and the role of cortical activity in cognitive processing.

Lu Liu is an associate professor at the National Clinical Research Center for Mental Disorders of Peking University Sixth Hospital. Her research interest is focused on the child and adolescent psychiatry, especially the attention deficit hyperactivity disorder.

Haimei Li is a doctor at Peking University Sixth Hospital. Her research interest is focused on the child and adolescent psychiatry, especially the attention deficit hyperactivity disorder.

Qiujin Qian is a doctor at Peking University Sixth Hospital. She is an expert in child and adolescent psychiatry.

Haijing Niu received her MS and PhD degrees in optics from Tianjin University and Beijing Normal University, followed by postdoctoral training in biomedical optics at the University of Texas at Arlington. She is an associate professor at the State Key Lab of Cognitive Neuroscience and Learning, Beijing Normal University, China. She focuses on resting-state fNIRS (rs-fNIRS) imaging studies (e.g., using rs-fNIRS data to study the human brain connectome), the software development of the rs-fNIRS data analysis, and the corresponding applications in both healthy brain development and brain diseases.

CC BY: © The Authors. Published by SPIE under a Creative Commons Attribution 4.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

Citation Download Citation

Mengjing Wang, Zhishan Hu, Lu Liu, Haimei Li, Qiujin Qian, and Haijing Niu "Disrupted functional brain connectivity networks in children with attention-deficit/hyperactivity disorder: evidence from resting-state functional near-infrared spectroscopy," Neurophotonics 7(1), 015012 (11 March 2020). https://doi.org/10.1117/1.NPh.7.1.015012

Received: 20 October 2019; Accepted: 20 February 2020; Published: 11 March 2020

Access the abstract

JOURNAL ARTICLE
13 PAGES

DOWNLOAD PAPER SAVE TO MY LIBRARY

GET CITATION

CITATIONS

Cited by 41 scholarly publications.

Explore citations on Lens.org

KEYWORDS

Brain

Visualization

Near infrared spectroscopy

Neuroimaging

Neurophotonics

Control systems

Data acquisition

Show All Keywords

Subscribe to Digital Library

Receive Erratum Email Alert

1.

Introduction

2.

Methods