Submitted Successfully!
To reward your contribution, here is a gift for you: A free trial for our video production service.
Thank you for your contribution! You can also upload a video entry or images related to this topic.
Version Summary Created by Modification Content Size Created at Operation
1
Kevin J. Black
 -- 3545 2022-10-11 18:15:50 |
2 headings & reference
Sirius Huang
 Meta information modification 3545 2022-10-12 04:33:11 |

Video Upload Options

Do you have a full video?
Send video materials Upload full video

Confirm

Are you sure to Delete?
Yes No
Cite
If you have any further questions, please contact Encyclopedia Editorial Office.
Iverson, A.M.;  Black, K.J. Situational Factors Affecting Tic Severity. Encyclopedia. Available online: https://encyclopedia.pub/entry/28942 (accessed on 18 May 2024).
Iverson AM,  Black KJ. Situational Factors Affecting Tic Severity. Encyclopedia. Available at: https://encyclopedia.pub/entry/28942. Accessed May 18, 2024.
Iverson, Ann M., Kevin J. Black. "Situational Factors Affecting Tic Severity" Encyclopedia, https://encyclopedia.pub/entry/28942 (accessed May 18, 2024).
Iverson, A.M., & Black, K.J. (2022, October 11). Situational Factors Affecting Tic Severity. In Encyclopedia. https://encyclopedia.pub/entry/28942
Iverson, Ann M. and Kevin J. Black. "Situational Factors Affecting Tic Severity." Encyclopedia. Web. 11 October, 2022.
Situational Factors Affecting Tic Severity
Edit
This entry is adapted from the peer-reviewed paper 10.3390/jcm11195930

Much of the research regarding Tourette’s syndrome (TS) has focused on why certain individuals develop tics while others do not. However, a separate line of research focuses on the momentary influences that cause tics to increase or decrease in patients who are already known to have TS or another chronic tic disorder (CTD). Environmental and internal variables such as fatigue, anxiety, and certain types of thoughts all have been shown to worsen tic severity and may even overcome the positive effects of treatment. Other influences such as stress, distraction, and being observed have had mixed effects in the various studies that have examined them. Still, other variables such as social media exposure and dietary habits have received only minimal research attention and would benefit from additional study. Understanding the impact of these environmental and internal influences provides an opportunity to improve behavioral treatments for TS/CTD and to improve the lives of those living with these conditions. 

Tourette Syndrome tic disorders tic environment severity fluctuations

1. Introduction

One way to think of how transient environmental factors modify tic severity is the ABC model of behavior, which examines antecedents and consequences of any behavior (action), both of which shape how likely that behavior is to occur. For example, if a child hits his sibling, an antecedent might be that the sibling stole his toy, and a consequence might be his parent putting him in time-out. Both the antecedents and the consequences can influence the likelihood that the behavior will be repeated. Different children may have different baseline characteristics that impact their response to particular antecedents and consequences, such as early childhood experiences, anxiety disorders, ADHD, genetic burden, and so on. Even so, Himle et al. found that “tic-exacerbating antecedents and consequences were nearly ubiquitous in a sample of children with chronic tic disorder” [1].
Understanding these environmental impacts on tics can inform both treatment and parenting strategies. For example, understanding how parental reactions to tics reinforce tics can help parents understand how to best support their children. Additionally, understanding how stress or major life events can trigger increased tic activity may help clinicians understand in what circumstances treatment alterations may be necessary. Finally, understanding the broader context in which their child’s tics occur can help families know when to expect changes in tics. For instance, much research suggests a worsening in tics is common in patients ages 8–10 [2], possibly due to “more tic-exacerbating consequences” [1]. This knowledge can aid clinicians in giving anticipatory guidance to parents.
According to one survey, the most common factors that patients with TS and their families associated with worsened tics include stress or anxiety, fatigue, holidays, birthdays, and return to school in the fall [3]. Some patients report that tics become worse in scenarios where they are particularly self-conscious of their tics, noting that “the desire to suppress them tends to make them much worse,” or “my tics get worse in any situation w[h]ere [I] particularly do not want them noticed” [4]. Additionally, some patients report that any situation in which their tics are acknowledged increases their tics: “talking about my tics … invariably makes me tic much more” [4]. Patients also reported on situations where they felt their tics were improved, such as being “deep in concentration with something else that [they are] doing” [4].
However, there is reason to believe that patient self-report measures are not always accurate. In one 2016 study, children were videotaped and surveyed about their tics during five different situations [5]. Self-reports and videotaped findings were not well correlated, but participants with higher premonitory urges to tic had more accurate self-reports. Additionally, a study that developed a scale to assess the environmental consequences for ticcing found that child-reported data may be more valid than parent-reported data [6]. These concerns regarding the validity of different types of data are important to keep in mind when evaluating the evidence regarding tic severity in different situations. 

2. Sleep

A majority of patients feel that fatigue worsens their symptoms [3][7]. In a polysomnography-based study, tic severity was positively correlated with the number of nighttime awakenings and negatively correlated with sleep efficiency, suggesting that sleep loss worsens tics [8]. Additionally, the study found that patients with TS have significantly worsened sleep efficiency than controls [8]. The surveys also show that many patients with TS exhibit parasomnias such as sleep walking (33%), sleep talking (60%), or night terrors (26%) [9]. Given that sleep problems are common in TS, they represent an attractive target for treatment, and indeed there are case reports of tics improving after sleep problems improve [10]. It is possible that sleep loss and fatigue worsen tics primarily due to a decreased ability to manage other tic triggers when fatigued [11].

3. Anxiety

Anxiety is another commonly cited trigger for tics. In one survey of 14 children with TS, the most common noted exacerbating factor was “being upset or anxious” [7]. A more recent study from Himle et al. looked at antecedents and consequences of tics using the function-based assessment of tics (FBAT) [1]. In this study, children diagnosed with comorbid internalizing disorders such as anxiety reported more tic-exacerbating antecedents than those without comorbid internalizing disorders. Additionally, the total number of antecedents was correlated with panic and somatic anxiety, and the total number of consequences was correlated with school anxiety and avoidance [1]. It is possible that children with anxiety disorders have a lower threshold for becoming anxious in response to other triggers, therefore leading to increased tics in response to a greater number of triggers. It is also possible that anxious children are more sensitive to others’ reactions to their tics, thus leading to more perceived consequences for their tics [1].
A later study of 45 children with TS by Eaton et al. showed that children with higher separation anxiety symptoms had more tics and that children with higher internalizing symptoms experienced more environmental consequences for tics. However, in this study, the environmental consequences themselves accounted for more of the variance in tics than the internalizing symptoms [12]. This suggests that while anxiety mediates the environmental impact of tics, anxiety alone does not explain differences in tic severity.
Some patients with TS experience so-called “tic attacks,” which are prolonged (>15 min) clusters of tics or tic-like movements. In one case series of 12 children with tic attacks, all children reported comorbid anxiety symptoms [13]. During the attacks themselves, they reported increased internal focus of attention on tics, suggesting a vicious cycle of anxiety leading to worsened tics and vice versa. In a different study of 75 children with tic disorders and their parents, increased family accommodation was associated with increased anxiety, as well as many other factors, including increased depressive symptoms, externalizing symptoms, aggression, rule-breaking behaviors, and functional impairment from tics [14]. Interestingly, despite being associated with many negative outcomes, increased family accommodation was not associated with increased tic severity.
However, as Godar and Bortolato [11] explained, the relationship between anxiety and TS is not clear. Several studies show a greater physiological response to stressors in patients with TS [15][16][17]. However, a recent study found that patients with TS actually showed lower levels of evening cortisol than controls [17], suggesting that perhaps tics reduce anxiety for patients with TS. Alternatively, it is also possible that the lower evening cortisol markers are simply a marker of chronic stress, which has been shown in multiple studies in non-TS patients [17][18][19][20][21].

4. Thoughts

Specific types of thoughts have also been associated with increased tics. In one study, 60 patients with TS/CTD were surveyed on their thoughts preceding tics, including three categories: anticipation (that tics may occur), interference (that they may negatively impact activities, self, or appearance), and permission (whether or not the person felt they were allowed to tic) [22]. The participants reported that all three categories of thoughts led to tics. Importantly, the interference and anticipation subscales of the Thinking About Tics inventory (THAT) were reduced in participants after cognitive behavioral therapy (CBT). Godar and Bortolato suggest that perhaps boredom leads to an increased focus on interoceptive stimuli, leading to increased tics [11].
The impact of external variables on tic frequency has long been noted. For instance, a 1978 longitudinal study of one patient noted that stressful life events overcame any positive medication effects from haloperidol [23]. In one study from 2003, 76 adults with either habit disorders or chronic tic disorders kept a daily diary of which activities were associated with tics [24]. While there were some trends in which types of activities were low or high risk for triggering tics, it was also evident that different people reacted differently to the same situations. For instance, 45% of patients with chronic tic disorders found passive attendance (i.e., watching TV or attending a hockey game) to be low-risk, while 38% found it to be high-risk. Overall, high-risk activities included socialization, waiting, and being in transit, while low-risk activities included studying and physical activity. People associated high-risk activities with tenseness, boredom, dissatisfaction, and disinterest. A Himle et al. study from 2014 showed similar results, with the most commonly noted antecedents for tics being TV or video games, home after school, homework, school classrooms, and public places [1]. This study also helped provide evidence that the consequences that occur after tics can help to explain setting effects. For instance, more attention after tics occurred 82% of the time at home after school as compared to only 37% of the time during sports/physical activity. This difference in the attention paid to tics may partially explain the common sentiment that tics are worsened at home after school versus during physical activity.

5. Stress

Nearly all patients report that stress worsens their tics [3]. However, analyzing the relationship between stress and tics is challenging, both because stress is multifactorial and because different people can react to the same stressor very differently depending on a variety of factors [11].
When measured in the laboratory setting, several studies have actually shown that tics decrease during stressful tasks. In one study of eight children with co-occurring tic and anxiety disorders, children’s heart rates and tic frequency were measured while completing stress-inducing tasks such as public speaking and discussion of family conflict [25]. They found no correlation between higher heart rate (indicating physiologic arousal) and tic frequency and, in fact, found that tic frequency decreased with higher heart rates during the speech task. In another study of 31 children and adolescents with tic disorders, tic frequency decreased while participants completed the Trier Social Stress Test, even though physiological markers of stress were present [26]. However, the techniques used to induce stress in these participants were task-based, and it is possible that the tasks themselves influenced the participants’ tics as they constituted a form of distraction.
While it is not clear that laboratory simulations of stress increase tic frequency, there is some evidence that this type of stress may impair a patient’s ability to suppress tics. In one study, 10 adolescents with TS attempted to suppress tics during stressful and non-stressful conditions [27]. Although there was no difference in tic frequency between the baseline stressful and non-stressful conditions, the participants were less able to suppress tics during stressful conditions. This result may explain the widespread perception that stress worsens tics. As far as treatments are concerned, relaxation therapy appears to be ineffective as monotherapy, again suggesting that stress per se plays only a limited role in the overall TS picture [28].
In general, laboratory conditions are best able to simulate short-term, task-based stressors, but many patients use the term “stress” to instead refer to stressful life events. In one 2003 study of children with TS and OCD, although children with these conditions scored higher than controls on a clinician-rated measure of psychosocial stressors, the Yale Children’s Global Stress Index (YCGSI), there was no correlation between the YCGSI score and tic severity [29]. However, there was a correlation between the scores on the self-reported Daily Life Stressor Scale (DLSS) and tic symptoms severity. The YCGSI was a clinician score measuring major life stressors during the past several months, while DLSS was a patient-scored measure of minor life stressors over the past week. These results suggest both that tic severity correlates better with daily life stressors than major life events and that patients are better able to evaluate their stress exposure than clinicians. This is perhaps because different patients can experience the same event as stressful or not stressful based on a wide range of individual factors.
Other studies show similar results. In a prospective longitudinal study from 2004, there was a small but statistically significant correlation between negative minor life events and tic severity on the aggregate level [30]. However, when the same study looked at the association on the individual level, only a minority of participants demonstrated a significant relationship between the two. A later prospective longitudinal study found that current psychosocial stress predicted future tic severity but not current tic severity [31]. A third study found a correlation between both major and minor life events and motor tic severity, but not vocal tic severity [32]. Taking all real-world studies together, it is clear that recent minor life stressors can play a significant role in increasing tic severity, despite the fact that laboratory-induced stressors have not been shown to have the same effect.

6. Rewards for Tic Suppression

It has been well established that rewarding patients for tic suppression decreases tics. A common study design to test this is the Tic Suppression Task, first developed by Woods and Himle [33]. In this task, the participants are placed in front of a computer or machine that they are told is a tic detector. A researcher observes unobtrusively, for instance, through a one-way mirror, to limit the impact of observation. The “tic detector” then rewards patients for tic-free intervals longer than 10 s, such as with poker chips that can be redeemed for money. The participants are observed during the baseline conditions, where they are instructed to tic freely, and suppression conditions, where they are instructed to suppress their tics and told they will be rewarded. Often, these conditions are measured several times in random order.
In one pooled analysis of nine studies using the Tic Suppression Task, 90% of the participants showed at least some suppressibility in response to immediately rewarded tic suppression [27][34][35][36][37][38][39][40][41][42]. Furthermore, about 70% of the participants showed at least a 50% reduction in tic frequency, and about 20% of the participants showed at least a 90% reduction in tic frequency. Factors associated with better suppressibility included more frequent tics and older age [43]. The addition of the stimulant dexmethylphenidate decreased tic frequency at baseline but, somewhat surprisingly, did not enhance tic suppression during the reward task [44].
Further research has demonstrated that the reward in the Tic Suppression Task must be contingent on tic suppression in order to be effective. A common research design includes a baseline condition, a verbal instructions condition, a Differential Reinforcement of Zero-rate Ticcing (Differential Reinforcement of Other behavior: DRO), and Noncontingent Reinforcement (NCR) [38][45]. The participants are instructed to suppress tics and receive rewards in both the DRO and NCR conditions. However, in the NCR conditions, the participants receive rewards regardless of the frequency of tics. The DRO condition outperforms both the NCR and verbal instruction conditions [38][45].
Importantly, it is possible to create a tic-reducing condition without the participants’ knowledge. In Woods et al. 2009, the participants completed the Tic Suppression Task with baseline, verbal instruction, and DRO conditions [46]. During the verbal instruction condition, an orange light was illuminated, and during the DRO condition, a purple light was illuminated. No lights were illuminated during the baseline conditions. The lights were not explained to the participants. The participants completed four different training sessions under these conditions. During a fifth session, the lights were illuminated during the corresponding tasks, but no suppression instructions or reinforcement were provided. Despite this, there was a statistically significant decrease in tics when the purple light was illuminated compared with no lights being illuminated. In other words, the participants had been trained without their knowledge to suppress tics when they observed a previously irrelevant stimulus, the purple light. This result has important implications as it can help explain tic variability between different environments, as there is likely differential reinforcement of tics between these different environments. This is the concept behind the functional intervention component of the Comprehensive Behavioral Intervention for Tics (CBIT), which has been tested in large, randomized controlled trials and is the main component of the CBIT-Jr intervention designed for younger children [47][48][49].

7. Distraction/Focused Attention

Multiple studies have demonstrated that tic severity worsens transiently while one focuses one’s attention on tics. One study of two children showed that talking about their tics increased tic frequency while talking about other topics did not [50]. A later study of 12 patients found that tic frequency increased when patients observed themselves ticcing via a mirror but decreased when watching a video of themselves without tics [51]. The impact of distraction, or focusing attention on something other than tics, is less consistent throughout different studies. Some studies have found that focusing attention away from tics reduces tic frequency [52]. Others have found that distraction interferes with tic suppression, thus increasing tic frequency during suppression conditions [53]. Still others have found that distraction does not impair tic suppression but that performance on the distraction task was worse during periods of tic suppression [37]. This suggests that tic suppression requires significant attention, which is perhaps why some studies show that distraction worsens patients’ ability to suppress their tics and supports patients’ observations that tic suppression can be burdensome and interfere with performance on school exams.

8. Being Observed

Studies differ in their findings as to how different types of observation by others affect tic severity. In one study that looked at tic severity at home and in the office as measured by video recordings, the patients had significantly increased tics at home [54]. The patients were recorded both with and without others in the room, and tic severity was increased when the patient was alone. However, in a similar study conducted by a different group, there was no difference in tic severity between recordings taken at home or in office, and patients had more tics when being overtly observed as compared to covertly observed [55]. Finally, a third study, which measured tic frequency across five different daily life activities, found that tic frequency was at its lowest when patients were alone [5]. Thus, the impacts of being observed are not clear.

9. Social Media Exposure

Anecdotal reports from clinicians indicate an increase in patients presenting with tics or tic-like symptoms since the COVID-19 pandemic began, and many attribute the increase to content labeled as TS on social media. Often, the symptoms on these social media sites do not represent classic Tourette’s syndrome symptomatology and instead are more consistent with a type of functional neurological disorder [56][57][58][59][60]. While there is limited research on how the popularity of such videos on social media has impacted those with pre-existing diagnoses of Tourette’s syndrome or other chronic tic disorders, it is possible that exposure to such content may increase tics in this population as well.

10. Social Situations

Several studies have found that tics are worsened in association with some social situations [1][32][61]. For example, one study showed that minor daily life events were associated with increased tics, and the most frequently cited daily life events were those involving relationships with friends [32]. A different study of patients with chronic tic disorders examined the attention paid by participants to words associated with social threat as compared to benign words [62]. They found that the CTD participants had increased attention to threat as compared to controls and that increased attention to a threat was associated with higher scores on some measures of tic severity, suggesting that social conflict and sensitivity to a social conflict may worsen tics.

11. Music

Musical performance has also been shown to decrease tics. One survey of 183 musicians with TS showed that on a scale of one (drastic symptom worsening) to five (drastic symptom improvement), the participants averaged a 4.45 rating for their symptoms while they performed music [63]. A different study videotaped eight musicians while performing, thinking about performing, and listening to music [64]. All three conditions decreased tics from baseline, with the largest improvement coming while performing. Additionally, there was a short-term decrease in tics in the period after they performed music, although the effect was small.

12. Exercise

Exercise has also been shown to decrease tic frequency, both during the exercise itself and to a lesser extent in the period immediately following the exercise [65][66]. One study also found a significant negative correlation between exercise and obsessive-compulsive behaviors, anxiety, and depression in children with tic disorders [66]. It is possible that the improvements in these other factors can partially explain the benefit in terms of tic improvement that is seen.

13. Diet and Supplements

Many families report that certain food types worsen tics. In one survey of 224 participants with TS regarding dietary habits and tic frequency, there was a significant negative effect on tics for foods containing caffeine, preserving agents, refined sugar, and sweeteners [67]. However, given that this study was based on participant self-reports, more study on this topic is necessary. The treatment of tics with the addition of certain foods or supplements has also been attempted, such as probiotics, N-acetyl cysteine, and omega-3 fatty acids, but results have generally not shown significant improvements [68][69][70]. One open-label study did show improvement in tics in patients given L-Theanine and Vitamin B6 as compared with a control condition of psychoeducation [71]. Additionally, an open-label study of magnesium and vitamin B6 showed an improvement in children with TS suffering from clinical exacerbations [72]. However, further placebo-controlled studies are necessary.

References

  1. Himle, M.B.; Capriotti, M.R.; Hayes, L.P.; Ramanujam, K.; Scahill, L.; Sukhodolsky, D.G.; Wilhelm, S.; Deckersbach, T.; Peterson, A.L.; Specht, M.W.; et al. Variables Associated with Tic Exacerbation in Children with Chronic Tic Disorders. Behav. Modif. 2014, 38, 163–183.
  2. Bloch, M.H.; Leckman, J.F. Clinical course of Tourette syndrome. J. Psychosom. Res. 2009, 67, 497–501.
  3. Bornstein, R.A.; Stefl, M.E.; Hammond, L. A survey of Tourette syndrome patients and their families: The 1987 Ohio Tourette Survey. J. Neuropsychiatry Clin. Neurosci. 1990, 2, 275–281.
  4. Turtle, L.; Robertson, M.M. Tics, twitches, tales: The experiences of Gilles de la Tourette’s syndrome. Am. J. Orthopsychiatry 2008, 78, 449–455.
  5. Barnea, M.; Benaroya-Milshtein, N.; Gilboa-Sechtman, E.; Woods, D.W.; Piacentini, J.; Fennig, S.; Apter, A.; Steinberg, T. Subjective versus objective measures of tic severity in Tourette syndrome—The influence of environment. Psychiatry Res. 2016, 242, 204–209.
  6. Capriotti, M.R.; Piacentini, J.C.; Himle, M.B.; Ricketts, E.J.; Espil, F.M.; Lee, H.J.; Turkel, J.E.; Woods, D.W. Assessing Environmental Consequences of Ticcing in Youth with Chronic Tic Disorders: The Tic Accommodation and Reactions Scale. Child. Health Care 2015, 44, 205–220.
  7. Silva, R.R.; Munoz, D.M.; Barickman, J.; Friedhoff, A.J. Environmental factors and related fluctuation of symptoms in children and adolescents with Tourette’s disorder. J. Child Psychol. Psychiatry 1995, 36, 305–312.
  8. Cohrs, S.; Rasch, T.; Altmeyer, S.; Kinkelbur, J.; Kostanecka, T.; Rothenberger, A.; Ruther, E.; Hajak, G. Decreased sleep quality and increased sleep related movements in patients with Tourette’s syndrome. J. Neurol. Neurosurg. Psychiatry 2001, 70, 192–197.
  9. Robertson, M.M.; Banerjee, S.; Eapen, V.; Fox-Hiley, P. Obsessive compulsive behaviour and depressive symptoms in young people with Tourette syndrome. A controlled study. Eur. Child Adolesc. Psychiatry 2002, 11, 261–265.
  10. Ghosh, D.; Rizkala, A.; Khuhro, A. Management of sleep problems helps improve tic control in children with Tourette Syndrome/chronic tic disorder. In Proceedings of the 47th Child Neurology Society Meeting, Chicago, IL, USA, 15–18 October 2018; p. S370.
  11. Godar, S.C.; Bortolato, M. What makes you tic? Translational approaches to study the role of stress and contextual triggers in Tourette syndrome. Neurosci. Biobehav. Rev. 2017, 76, 123–133.
  12. Eaton, C.K.; Jones, A.M.; Gutierrez-Colina, A.M.; Ivey, E.K.; Carlson, O.; Melville, L.; Kardon, P.; Blount, R.L. The Influence of Environmental Consequences and Internalizing Symptoms on Children’s Tic Severity. Child Psychiatry Hum. Dev. 2017, 48, 327–334.
  13. Robinson, S.; Hedderly, T. Novel Psychological Formulation and Treatment of “Tic Attacks” in Tourette Syndrome. Front. Pediatr. 2016, 4, 46.
  14. Storch, E.A.; Johnco, C.; McGuire, J.F.; Wu, M.S.; McBride, N.M.; Lewin, A.B.; Murphy, T.K. An initial study of family accommodation in children and adolescents with chronic tic disorders. Eur. Child Adolesc. Psychiatry 2017, 26, 99–109.
  15. Chappell, P.; Riddle, M.; Anderson, G.; Scahill, L.; Hardin, M.; Walker, D.; Cohen, D.; Leckman, J. Enhanced stress responsivity of Tourette syndrome patients undergoing lumbar puncture. Biol. Psychiatry 1994, 36, 35–43.
  16. Chappell, P.; Leckman, J.; Goodman, W.; Bissette, G.; Pauls, D.; Anderson, G.; Riddle, M.; Scahill, L.; McDougle, C.; Cohen, D. Elevated cerebrospinal fluid corticotropin-releasing factor in Tourette’s syndrome: Comparison to obsessive compulsive disorder and normal controls. Biol. Psychiatry 1996, 39, 776–783.
  17. Corbett, B.A.; Mendoza, S.P.; Baym, C.L.; Bunge, S.A.; Levine, S. Examining cortisol rhythmicity and responsivity to stress in children with Tourette syndrome. Psychoneuroendocrinology 2008, 33, 810–820.
  18. Nickel, C.; Tanca, S.; Kolowos, S.; Pedrosa-Gil, F.; Bachler, E.; Loew, T.H.; Gross, M.; Rother, W.K.; Nickel, M.K. Men with chronic occupational stress benefit from behavioural/psycho-educational group training: A randomized, prospective, controlled trial. Psychol. Med. 2007, 37, 1141–1149.
  19. Nicolson, N.A.; van Diest, R. Salivary cortisol patterns in vital exhaustion. J. Psychosom. Res. 2000, 49, 335–342.
  20. Ockenfels, M.C.; Porter, L.; Smyth, J.; Kirschbaum, C.; Hellhammer, D.H.; Stone, A.A. Effect of chronic stress associated with unemployment on salivary cortisol: Overall cortisol levels, diurnal rhythm, and acute stress reactivity. Psychosom. Med. 1995, 57, 460–467.
  21. Secunda, S.K.; Cross, C.K.; Koslow, S.; Katz, M.M.; Kocsis, J.; Maas, J.W.; Landis, H. Biochemistry and suicidal behavior in depressed patients. Biol. Psychiatry 1986, 21, 756–767.
  22. O’Connor, K.; St-Pierre-Delorme, M.E.; Leclerc, J.; Lavoie, M.; Blais, M.T. Meta-cognitions in tourette syndrome, tic disorders, and body-focused repetitive disorder. Can. J. Psychiatry 2014, 59, 417–425.
  23. Surwillo, W.W.; Shafii, M.; Barrett, C.L. Gilles de la Tourette syndrome: A 20-month study of the effects of stressful life events and haloperidol on symptom frequency. J. Nerv. Ment. Dis. 1978, 166, 812–816.
  24. O’Connor, K.; Brisebois, H.; Brault, M.; Robillard, S.; Loiselle, J. Behavioral activity associated with onset in chronic tic and habit disorder. Behav. Res. Ther. 2003, 41, 241–249.
  25. Conelea, C.A.; Ramanujam, K.; Walther, M.R.; Freeman, J.B.; Garcia, A.M. Is There a Relationship Between Tic Frequency and Physiological Arousal? Examination in a Sample of Children With Co-Occurring Tic and Anxiety Disorders. Behav. Modif. 2014, 38, 217–234.
  26. Buse, J.; Enghardt, S.; Kirschbaum, C.; Ehrlich, S.; Roessner, V. Tic Frequency Decreases during Short-term Psychosocial Stress—An Experimental Study on Children with Tic Disorders. Front. Psychiatry 2016, 7, 84.
  27. Conelea, C.A.; Woods, D.W.; Brandt, B.C. The impact of a stress induction task on tic frequencies in youth with Tourette Syndrome. Behav. Res. Ther. 2011, 49, 492–497.
  28. Bergin, A.; Waranch, H.R.; Brown, J.; Carson, K.; Singer, H.S. Relaxation therapy in Tourette syndrome: A pilot study. Pediatr. Neurol. 1998, 18, 136–142.
  29. Findley, D.B.; Leckman, J.F.; Katsovich, L.; Lin, H.; Zhang, H.; Grantz, H.; Otka, J.; Lombroso, P.J.; King, R.A. Development of the Yale Children’s Global Stress Index (YCGSI) and its application in children and adolescents ith Tourette’s syndrome and obsessive-compulsive disorder. J. Am. Acad. Child Adolesc. Psychiatry 2003, 42, 450–457.
  30. Hoekstra, P.J.; Steenhuis, M.P.; Kallenberg, C.G.; Minderaa, R.B. Association of small life events with self reports of tic severity in pediatric and adult tic disorder patients: A prospective longitudinal study. J. Clin. Psychiatry 2004, 65, 426–431.
  31. Lin, H.; Katsovich, L.; Ghebremichael, M.; Findley, D.B.; Grantz, H.; Lombroso, P.J.; King, R.A.; Zhang, H.; Leckman, J.F. Psychosocial stress predicts future symptom severities in children and adolescents with Tourette syndrome and/or obsessive-compulsive disorder. J. Child Psychol. Psychiatry 2007, 48, 157–166.
  32. Steinberg, T.; Shmuel-Baruch, S.; Horesh, N.; Apter, A. Life events and Tourette syndrome. Compr. Psychiatry 2013, 54, 467–473.
  33. Woods, D.W.; Himle, M.B. Creating tic suppression: Comparing the effects of verbal instruction to differential reinforcement. J. Appl. Behav. Anal. 2004, 37, 417–420.
  34. Conelea, C.A.; Wellen, B.; Woods, D.W.; Greene, D.J.; Black, K.J.; Specht, M.; Himle, M.B.; Lee, H.J.; Capriotti, M. Patterns and Predictors of Tic Suppressibility in Youth with Tic Disorders. Front. Psychiatry 2018, 9, 188.
  35. Capriotti, M.R.; Brandt, B.C.; Turkel, J.E.; Lee, H.J.; Woods, D.W. Negative Reinforcement and Premonitory Urges in Youth With Tourette Syndrome: An Experimental Evaluation. Behav. Modif. 2014, 38, 276–296.
  36. Capriotti, M.R.; Turkel, J.E.; Johnson, R.A.; Espil, F.M.; Woods, D.W. Comparing fixed-amount and progressive-amount DRO Schedules for tic suppression in youth with chronic tic disorders. J. Appl. Behav. Anal. 2017, 50, 106–120.
  37. Conelea, C.A.; Woods, D.W. Examining the impact of distraction on tic suppression in children and adolescents with Tourette syndrome. Behav. Res. Ther. 2008, 46, 1193–1200.
  38. Greene, D.J.; Koller, J.M.; Robichaux-Viehoever, A.; Bihun, E.C.; Schlaggar, B.L.; Black, K.J. Reward enhances tic suppression in children within months of tic disorder onset. Dev. Cogn. Neurosci. 2015, 11, 65–74.
  39. Specht, M.W.; Woods, D.W.; Nicotra, C.M.; Kelly, L.M.; Ricketts, E.J.; Conelea, C.A.; Grados, M.A.; Ostrander, R.S.; Walkup, J.T. Effects of tic suppression: Ability to suppress, rebound, negative reinforcement, and habituation to the premonitory urge. Behav. Res. Ther. 2013, 51, 24–30.
  40. Woods, D.W.; Himle, M.B.; Miltenberger, R.G.; Carr, J.E.; Osmon, D.C.; Karsten, A.M.; Jostad, C.; Bosch, A. Durability, negative impact, and neuropsychological predictors of tic suppression in children with chronic tic disorder. J. Abnorm. Child Psychol. 2008, 36, 237–245.
  41. Capriotti, M.R.; Brandt, B.C.; Ricketts, E.J.; Espil, F.M.; Woods, D.W. Comparing the effects of differential reinforcement of other behavior and response-cost contingencies on tics in youth with Tourette syndrome. J. Appl. Behav. Anal. 2012, 45, 251–263.
  42. Conelea, C.; Frank, M.; Frank, H.; Wiecki, T.; Hana, L.; Pei, R. Role of reinforcement learning in tic expression: Integrating methods from behavioral psychology and computational neuroscience. In Behavioral Research in Tourette Syndrome: Standing on the Shoulders of Neuroscience, Psychiatry, and Neurology, Proceedings of the Annual Association for Behavioral and Cognitive Therapies Conference, Philadelphia, PA, USA, 20–23 November 2014; ABCT: New York, NY, USA, 2014.
  43. Ueda, K.; Kim, S.; Greene, D.J.; Black, K.J. Correlates and clinical implications of tic suppressibility. Curr. Dev. Disord. Rep. 2021, 8, 112–120.
  44. Lyon, G.J.; Samar, S.M.; Conelea, C.; Trujillo, M.R.; Lipinski, C.M.; Bauer, C.C.; Brandt, B.C.; Kemp, J.J.; Lawrence, Z.E.; Howard, J.; et al. Testing tic suppression: Comparing the effects of dexmethylphenidate to no medication in children and adolescents with attention-deficit/hyperactivity disorder and Tourette’s disorder. J. Child Adolesc. Psychopharmacol. 2010, 20, 283–289.
  45. Himle, M.B.; Woods, D.W.; Bunaciu, L. Evaluating the role of contingency in differentially reinforced tic suppression. J. Appl. Behav. Anal. 2008, 41, 285–289.
  46. Woods, D.W.; Walther, M.R.; Bauer, C.C.; Kemp, J.J.; Conelea, C.A. The development of stimulus control over tics: A potential explanation for contextually-based variability in the symptoms of Tourette syndrome. Behav. Res. Ther. 2009, 47, 41–47.
  47. Piacentini, J.; Woods, D.W.; Scahill, L.; Wilhelm, S.; Peterson, A.L.; Chang, S.; Ginsburg, G.S.; Deckersbach, T.; Dziura, J.; Levi-Pearl, S.; et al. Behavior therapy for children with Tourette disorder: A randomized controlled trial. JAMA 2010, 303, 1929–1937.
  48. Bennett, S.M.; Capriotti, M.; Bauer, C.; Chang, S.; Keller, A.E.; Walkup, J.; Woods, D.; Piacentini, J. Development and Open Trial of a Psychosocial Intervention for Young Children With Chronic Tics: The CBIT-JR Study. Behav. Ther. 2020, 51, 659–669.
  49. Wilhelm, S.; Peterson, A.L.; Piacentini, J.; Woods, D.W.; Deckersbach, T.; Sukhodolsky, D.G.; Chang, S.; Liu, H.; Dziura, J.; Walkup, J.T.; et al. Randomized trial of behavior therapy for adults with Tourette syndrome. Arch. Gen. Psychiatry 2012, 69, 795–803.
  50. Woods, D.W.; Watson, T.S.; Wolfe, E.; Twohig, M.P.; Friman, P.C. Analyzing the influence of tic-related talk on vocal and motor tics in children with Tourette’s syndrome. J. Appl. Behav. Anal. 2001, 34, 353–356.
  51. Brandt, V.C.; Lynn, M.T.; Obst, M.; Brass, M.; Munchau, A. Visual feedback of own tics increases tic frequency in patients with Tourette’s syndrome. Cogn. Neurosci. 2015, 6, 1–7.
  52. Misirlisoy, E.; Brandt, V.; Ganos, C.; Tubing, J.; Munchau, A.; Haggard, P. The relation between attention and tic generation in Tourette syndrome. Neuropsychology 2015, 29, 658–665.
  53. Herrmann, K.; Sprenger, A.; Baumung, L.; Alvarez-Fischer, D.; Munchau, A.; Brandt, V. Help or hurt? How attention modulates tics under different conditions. Cortex 2019, 120, 471–482.
  54. Goetz, C.G.; Leurgans, S.; Chmura, T.A. Home alone: Methods to maximize tic expression for objective videotape assessments in Gilles de la Tourette syndrome. Mov. Disord. 2001, 16, 693–697.
  55. Piacentini, J.; Himle, M.B.; Chang, S.; Baruch, D.E.; Buzzella, B.A.; Pearlman, A.; Woods, D.W. Reactivity of tic observation procedures to situation and setting. J. Abnorm. Child Psychol. 2006, 34, 649–658.
  56. Olvera, C.; Stebbins, G.T.; Goetz, C.G.; Kompoliti, K. TikTok Tics: A Pandemic Within a Pandemic. Mov. Disord. Clin. Pract. 2021, 8, 1200–1205.
  57. Paulus, T.; Baumer, T.; Verrel, J.; Weissbach, A.; Roessner, V.; Beste, C.; Munchau, A. Pandemic Tic-like Behaviors Following Social Media Consumption. Mov. Disord. 2021, 36, 2932–2935.
  58. Hull, M.; Parnes, M. Tics and TikTok: Functional Tics Spread Through Social Media. Mov. Disord. Clin. Pract. 2021, 8, 1248–1252.
  59. Zea Vera, A.; Bruce, A.; Garris, J.; Tochen, L.; Bhatia, P.; Lehman, R.K.; Lopez, W.; Wu, S.W.; Gilbert, D.L. The Phenomenology of Tics and Tic-Like Behavior in TikTok. Pediatr. Neurol. 2022, 130, 14–20.
  60. Malaty, I.A.C.; Anderson, S.; Bennett, S.M.; Budman, C.L.; Coffey, B.J.; Coffman, K.A.; Greenberg, E.; McGuire, J.F.; Müller-Vahl, K.R.; Okun, M.S.; et al. Diagnosis and management of functional tic-like phenomena. OSF Preprints 2022.
  61. Caurin, B.; Serrano, M.; Fernandez-Alvarez, E.; Campistol, J.; Perez-Duenas, B. Environmental circumstances influencing tic expression in children. Eur. J. Paediatr. Neurol. 2014, 18, 157–162.
  62. Pile, V.; Robinson, S.; Topor, M.; Hedderly, T.; Lau, J.Y.F. Attention bias for social threat in youth with tic disorders: Links with tic severity and social anxiety. Child Neuropsychol. 2019, 25, 394–409.
  63. Brown, W.C. Influence of Musical Engagement on Symptoms of Tourette’s Disorder. Ph.D. Thesis, University of South Florida, Tampa, FL, USA, 2016.
  64. Bodeck, S.; Lappe, C.; Evers, S. Tic-reducing effects of music in patients with Tourette’s syndrome: Self-reported and objective analysis. J. Neurol. Sci. 2015, 352, 41–47.
  65. Nixon, E.; Glazebrook, C.; Hollis, C.; Jackson, G.M. Reduced Tic Symptomatology in Tourette Syndrome After an Acute Bout of Exercise: An Observational Study. Behav. Modif. 2014, 38, 235–263.
  66. Pringsheim, T.; Nosratmirshekarlou, E.; Doja, A.; Martino, D. Physical activity, sleep and neuropsychiatric symptom severity in children with tourette syndrome. Eur. Child Adolesc. Psychiatry 2021, 30, 711–719.
  67. Muller-Vahl, K.R.; Buddensiek, N.; Geomelas, M.; Emrich, H.M. The influence of different food and drink on tics in Tourette syndrome. Acta Paediatr. 2008, 97, 442–446.
  68. Wu, C.C.; Wong, L.C.; Hsu, C.J.; Yang, C.W.; Tsai, Y.C.; Cheng, F.S.; Hu, H.Y.; Lee, W.T. Randomized Controlled Trial of Probiotic PS128 in Children with Tourette Syndrome. Nutrients 2021, 13, 3698.
  69. Bloch, M.H.; Panza, K.E.; Yaffa, A.; Alvarenga, P.G.; Jakubovski, E.; Mulqueen, J.M.; Landeros-Weisenberger, A.; Leckman, J.F. N-Acetylcysteine in the Treatment of Pediatric Tourette Syndrome: Randomized, Double-Blind, Placebo-Controlled Add-On Trial. J. Child Adolesc. Psychopharmacol. 2016, 26, 327–334.
  70. Gabbay, V.; Babb, J.S.; Klein, R.G.; Panzer, A.M.; Katz, Y.; Alonso, C.M.; Petkova, E.; Wang, J.; Coffey, B.J. A double-blind, placebo-controlled trial of omega-3 fatty acids in Tourette’s disorder. Pediatrics 2012, 129, e1493–e1500.
  71. Rizzo, R.; Prato, A.; Scerbo, M.; Saia, F.; Barone, R.; Curatolo, P. Use of Nutritional Supplements Based on L-Theanine and Vitamin B6 in Children with Tourette Syndrome, with Anxiety Disorders: A Pilot Study. Nutrients 2022, 14, 852.
  72. Garcia-Lopez, R.; Romero-Gonzalez, J.; Perea-Milla, E.; Ruiz-Garcia, C.; Rivas-Ruiz, F.; de Las Mulas Bejar, M. An open study evaluating the efficacy and security of magnesium and vitamin B(6) as a treatment of Tourette syndrome in children. Med. Clin. (Barc.) 2008, 131, 689–691.
More
© Text is available under the terms and conditions of the Creative Commons Attribution (CC BY) license; additional terms may apply. By using this site, you agree to the Terms and Conditions and Privacy Policy.
Upload a video for this entry
Information
Subjects: Psychiatry; Clinical Neurology
Contributors MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register :
Ann M. Iverson
,
Kevin J. Black
View Times: 795
Revisions: 2 times (View History)
Update Date: 12 Oct 2022
Table of Contents
    1000/1000
    Hot Most Recent
    Feedback