**2. Neuropsychiatric presentation of brain tumour**

Unsurprisingly, a child with a brain tumour rarely presents to a psychiatrist at the manifestation of illness. Nevertheless, neuropsychiatric presentations in children with brain tumours can, and do, come to the attention of psychiatrists, albeit infrequently. The psychiatric and behavioural presenting symptoms of CNS tumours and/or subsequent iatrogenic sequelae include internalising presentations (mood and anxiety disorders), mutism, pseudobulbar symptoms, somatic problems, externalising presentations (such as aggression), eating disorders, psychosis, and hyperkinetic disorders. The clinical course is multi-faceted: the symptoms may appear early as the presenting complaint; later, following a confirmed (tumour ) diagnosis; as a complication of anti-neoplastic therapy; or as an 'adjustment disorder'. Nevertheless, there is a relative paucity of studies that describe the neuropsychiatric symptoms associated with this cohort of patients [26].A literature review was conducted by Zyrianova et al. [26] to address childhood CNS tumour presentations of a 'neuropsychiatric' nature; the many possible combinations of symptoms—from psychiatric to physical/neurological—largely depended on the location and extent of the tumour [26]. Interestingly, the location of the lesion strongly correlated to neuropsychiatric prognosis. Supratentorial, right-sided cerebellar and vermal lesions all demonstrated the poorest outcomes [31–34]. Specifically, lesions of the vermis were associated with dysregulation of affect [33].

In certain cases, neurobehavioural disorders are known to increase the risk of developing a childhood brain tumour. For example, children with Autism Spectrum Disorder are more likely than the general paediatric population to develop a CNS malignancy [34]. Furthermore, mere behavioural (and 'mental') symptoms existed pre-morbidly in a quarter of children with a subsequent diagnosis of thalamic tumours in a case series [35]. A retrospective case note review of 200 children with brain tumours demonstrated that neurological symptoms (present in 88% of patients) were only twice as common as 'educational or behavioural problems'; moreover, the latter represented the initial presentation in 10% of cases [36].

#### **2.1. Case series**

There are no large-scale studies that specifically assess the presenting symptoms of childhood brain tumours in a psychiatric context. Nevertheless, several case reports/small case series have highlighted specific psychiatric symptoms that heralded a brain cancer, as follows:

• An intracranial germinoma presented in an adolescent male as a first episode psychosis. This followed a 3-month history of negative symptoms, daytime somnolence, 'distorted thought processes' and memory loss; the only positive symptoms were 'sporadic visual sensations' at the edge of the visual field [37].


#### **2.2. Posterior fossa syndromes**

hypointense on T1-W MRI and T2-W MR [29] usually demonstrating homogeneous enhance-

Unsurprisingly, a child with a brain tumour rarely presents to a psychiatrist at the manifestation of illness. Nevertheless, neuropsychiatric presentations in children with brain tumours can, and do, come to the attention of psychiatrists, albeit infrequently. The psychiatric and behavioural presenting symptoms of CNS tumours and/or subsequent iatrogenic sequelae include internalising presentations (mood and anxiety disorders), mutism, pseudobulbar symptoms, somatic problems, externalising presentations (such as aggression), eating disorders, psychosis, and hyperkinetic disorders. The clinical course is multi-faceted: the symptoms may appear early as the presenting complaint; later, following a confirmed (tumour ) diagnosis; as a complication of anti-neoplastic therapy; or as an 'adjustment disorder'. Nevertheless, there is a relative paucity of studies that describe the neuropsychiatric symptoms associated with this cohort of patients [26].A literature review was conducted by Zyrianova et al. [26] to address childhood CNS tumour presentations of a 'neuropsychiatric' nature; the many possible combinations of symptoms—from psychiatric to physical/neurological—largely depended on the location and extent of the tumour [26]. Interestingly, the location of the lesion strongly correlated to neuropsychiatric prognosis. Supratentorial, right-sided cerebellar and vermal lesions all demonstrated the poorest outcomes [31–34]. Specifically, lesions of

In certain cases, neurobehavioural disorders are known to increase the risk of developing a childhood brain tumour. For example, children with Autism Spectrum Disorder are more likely than the general paediatric population to develop a CNS malignancy [34]. Furthermore, mere behavioural (and 'mental') symptoms existed pre-morbidly in a quarter of children with a subsequent diagnosis of thalamic tumours in a case series [35]. A retrospective case note review of 200 children with brain tumours demonstrated that neurological symptoms (present in 88% of patients) were only twice as common as 'educational or behavioural problems'; moreover, the latter represented the initial presentation

There are no large-scale studies that specifically assess the presenting symptoms of childhood brain tumours in a psychiatric context. Nevertheless, several case reports/small case series have highlighted specific psychiatric symptoms that heralded a brain cancer, as follows:

• An intracranial germinoma presented in an adolescent male as a first episode psychosis. This followed a 3-month history of negative symptoms, daytime somnolence, 'distorted thought processes' and memory loss; the only positive symptoms were 'sporadic visual

ment with gadolinium administration [30].

174 Brain Tumors - An Update

**2. Neuropsychiatric presentation of brain tumour**

the vermis were associated with dysregulation of affect [33].

sensations' at the edge of the visual field [37].

in 10% of cases [36].

**2.1. Case series**

Of particular relevance to neuropsychiatrists are lesions within the posterior fossa (PF), a portion of the intracranial cavity that contains the cerebellum and brainstem. Over half of childhood tumours are located in the PF [42]. These lesions account for the largest number of cancer deaths in children and may initially present with neuropsychiatric signs and symptoms [43]. Within the PF, in addition to the co-ordination of balance and motor functions, the cerebellum has a role in functions such as cognition, emotion and language [44]. Indeed, the independent role of the cerebellum in higher order brain function is expansive: internal architecture and wide connectivity co-ordinate and integrate this crucial regulation of neuropsychiatric functions. Such orchestration is only possible due to the cerebellum's connections to prefrontal cortex, subcortical limbic structures, and catecholamine-containing brainstem nuclei [45]. Similarly, the brainstem—once almost exclusively known for its involvement in vital functions (breathing, heart rate, sleeping)—is increasingly recognised for affective and cognitive functioning. A recent critical review of the literature published (between 1950 and 2012) on the affective and cognitive symptoms that follow brainstem lesion has revealed neuropsychiatric symptoms in almost half the cases: apathy, emotional lability, irritability, mania, executive dysfunction, memory impairment, and inattention were among the symptoms listed; moreover, the authors hypothesised that the brainstem constitutes an inherent part of the cerebello-cerebral network that subserves cognition and affect. Therefore, isolated brainstem damage can cause symptoms that resemble the cerebellar cognitive affective syndrome (CCAS) [46]. Furthermore, children with midline tumours with brainstem invasion are at increased risk of posterior fossa syndrome (PFS) [47].

The reader is also informed that in 2016 a new definition, 'Post-operative pediatric CMS' (POP-CMS), was devised by experts ('Iceland Delphi group') in the feld: "Post-operative pediatric cerebellar mutism syndrome is characterized by delayed onset mutism/*reduced speech* and emotional lability after cerebellar or 4th ventricle tumour surgery in children. Additional common features include hypotonia and oropharyngeal dysfunction/dysphagia. It may frequently be accompanied by the *cerebellar motor syndrome, cerebellar cognitive affective syndrome* and brain stem dysfunction including long tract signs and cranial neuropathies. The mutism is always transient, but recovery from CMS may be prolonged. Speech and language may not return to

Neuropsychiatry: Aspects of Childhood Cranial Tumours http://dx.doi.org/10.5772/intechopen.75679 177

normal, and other deficits of cognitive, affective and motor function often persist"[49].

short sentences that can only be elicited after vigorous stimulation".

ing dysprosodia, agrammatism and mild anomia".

are frequently observed in this patient population" [48].

definition:

and tremor".

CM below).

literature.

**2.3. Cerebellar mutism**

The Posterior Fossa Society has provided further guidance for clinicians when following this

1. *Reduced speech*: "speech production that is severely reduced and limited to single words or

2. *Cerebellar motor syndrome*: "impairment of gait (ataxia), extremity coordination (dysmetria), disordered eye movements, poor articulation (dysarthria), impaired swallowing (dysphagia)

3. *Cerebellar cognitive affective syndrome*: "a pattern of behavioural abnormalities that includes impairments of executive function (planning, set-shifting, abstract reasoning, verbal fluency, working memory), often with perseveration, distractibility or inattention; visual-spatial disorganization and impaired visual-spatial memory; personality change with blunting of affect or disinhibited and inappropriate behaviour; and difficulties with language production includ-

4. *Long tract signs*: "symptoms such as urinary retention/incontinence and hemiparesis, which

Of note, like many of its predecessors, the hallmark of POP-CMS is CM (see discussion on

POP-CMS as a definition represents the foundation for more consistent research. However, its validity requires more testing and it may be subject to further revision. Therefore, for the remainder of the chapter, we will use the terms which are more established in the

The term 'cerebellar mutism' refers to a muteness which results from lesions of the cerebellum as opposed to the cerebrum or lower cranial nerves. A severe dysregulation of volitional motor functions of speech creates a recognizable clinical signature: an absence of speech (verbal mutism) is seen, rather than an absence of non-verbal sounds (i.e. whining, laughter, crying) [49]. Although most commonly seen after resection of posterior fossa tumours, there are reports of non-surgical cases of paediatric CM, including trauma, vascular incidents, infections and inflammatory syndromes [48, 50, 51]. CM has been reported to resolve after as little as 6 days or as long as 52 months [52]. Indeed, a hallmark of CM is its

Of note, CCAS consists of neuropsychological and lingusitic deficits but does not include verbal mutism or neurological/motor symptoms. Conversely, posterior fossa syndrome (PFS) is a sprawling spectrum of neuropsychological, neurological and lingusitic symptoms [47]. Thus, lesions in the brainstem, but mostly those involving the fourth ventricle and cerebellum – or their surgical removal – can engender a variety of clinical outcomes. Confusingly, the literature has a formidable tapestry of definitions. Excluding both CCAS and 'Cerebellar Syndrome' (i.e. isolated cereballar signs), it is 'Cerellar Mutism' (a verbal mutism also known as 'Transient Cerebellar Mutism' or TCM) that is the defining hallmark of the relevant post-operative syndromes: (the aforementioned) Posterior Fossa Syndrome (PFS); the less expanisive 'Cerebellar Mutism Syndrome' (CMS) – which is limited to mutism, ataxia, hypophonia and irritability; and finally, the self-explanatory 'Mutism and Subsequent Dysarthri'a (MSD). Importantly all of the aforementioned syndromes (i.e. CM or TCM, CMS, CCAS, MSD and Cerebellar syndrome) are subsumed by the term Posterior Fossa Syndrome, i.e. they can be a presentation of PFS (**Figure 3**) [48].

**Figure 3.** Symptomatic spectrum and relationship between the PFS, CCAS and related conditions. Adapted with permission from the Posterior Fossa Society [48]. Entire Figure = PFS, Left Half (Excluding CM) = CCAS, Inner Circle (Light Grey) = CMS, Dotted Area = MSD, Core (Dark Grey) = CM or TCM, Stripped Area = Cerebellar Signs or Cerebellar Syndrome.

The reader is also informed that in 2016 a new definition, 'Post-operative pediatric CMS' (POP-CMS), was devised by experts ('Iceland Delphi group') in the feld: "Post-operative pediatric cerebellar mutism syndrome is characterized by delayed onset mutism/*reduced speech* and emotional lability after cerebellar or 4th ventricle tumour surgery in children. Additional common features include hypotonia and oropharyngeal dysfunction/dysphagia. It may frequently be accompanied by the *cerebellar motor syndrome, cerebellar cognitive affective syndrome* and brain stem dysfunction including long tract signs and cranial neuropathies. The mutism is always transient, but recovery from CMS may be prolonged. Speech and language may not return to normal, and other deficits of cognitive, affective and motor function often persist"[49].

The Posterior Fossa Society has provided further guidance for clinicians when following this definition:

1. *Reduced speech*: "speech production that is severely reduced and limited to single words or short sentences that can only be elicited after vigorous stimulation".

2. *Cerebellar motor syndrome*: "impairment of gait (ataxia), extremity coordination (dysmetria), disordered eye movements, poor articulation (dysarthria), impaired swallowing (dysphagia) and tremor".

3. *Cerebellar cognitive affective syndrome*: "a pattern of behavioural abnormalities that includes impairments of executive function (planning, set-shifting, abstract reasoning, verbal fluency, working memory), often with perseveration, distractibility or inattention; visual-spatial disorganization and impaired visual-spatial memory; personality change with blunting of affect or disinhibited and inappropriate behaviour; and difficulties with language production including dysprosodia, agrammatism and mild anomia".

4. *Long tract signs*: "symptoms such as urinary retention/incontinence and hemiparesis, which are frequently observed in this patient population" [48].

Of note, like many of its predecessors, the hallmark of POP-CMS is CM (see discussion on CM below).

POP-CMS as a definition represents the foundation for more consistent research. However, its validity requires more testing and it may be subject to further revision. Therefore, for the remainder of the chapter, we will use the terms which are more established in the literature.

#### **2.3. Cerebellar mutism**

listed; moreover, the authors hypothesised that the brainstem constitutes an inherent part of the cerebello-cerebral network that subserves cognition and affect. Therefore, isolated brainstem damage can cause symptoms that resemble the cerebellar cognitive affective syndrome (CCAS) [46]. Furthermore, children with midline tumours with brainstem invasion are at

Of note, CCAS consists of neuropsychological and lingusitic deficits but does not include verbal mutism or neurological/motor symptoms. Conversely, posterior fossa syndrome (PFS) is a sprawling spectrum of neuropsychological, neurological and lingusitic symptoms [47]. Thus, lesions in the brainstem, but mostly those involving the fourth ventricle and cerebellum – or their surgical removal – can engender a variety of clinical outcomes. Confusingly, the literature has a formidable tapestry of definitions. Excluding both CCAS and 'Cerebellar Syndrome' (i.e. isolated cereballar signs), it is 'Cerellar Mutism' (a verbal mutism also known as 'Transient Cerebellar Mutism' or TCM) that is the defining hallmark of the relevant post-operative syndromes: (the aforementioned) Posterior Fossa Syndrome (PFS); the less expanisive 'Cerebellar Mutism Syndrome' (CMS) – which is limited to mutism, ataxia, hypophonia and irritability; and finally, the self-explanatory 'Mutism and Subsequent Dysarthri'a (MSD). Importantly all of the aforementioned syndromes (i.e. CM or TCM, CMS, CCAS, MSD and Cerebellar syndrome) are subsumed by the term Posterior Fossa Syndrome, i.e. they can

**Figure 3.** Symptomatic spectrum and relationship between the PFS, CCAS and related conditions. Adapted with permission from the Posterior Fossa Society [48]. Entire Figure = PFS, Left Half (Excluding CM) = CCAS, Inner Circle (Light Grey) = CMS, Dotted Area = MSD, Core (Dark Grey) = CM or TCM, Stripped Area = Cerebellar Signs or Cerebellar

increased risk of posterior fossa syndrome (PFS) [47].

176 Brain Tumors - An Update

be a presentation of PFS (**Figure 3**) [48].

Syndrome.

The term 'cerebellar mutism' refers to a muteness which results from lesions of the cerebellum as opposed to the cerebrum or lower cranial nerves. A severe dysregulation of volitional motor functions of speech creates a recognizable clinical signature: an absence of speech (verbal mutism) is seen, rather than an absence of non-verbal sounds (i.e. whining, laughter, crying) [49]. Although most commonly seen after resection of posterior fossa tumours, there are reports of non-surgical cases of paediatric CM, including trauma, vascular incidents, infections and inflammatory syndromes [48, 50, 51]. CM has been reported to resolve after as little as 6 days or as long as 52 months [52]. Indeed, a hallmark of CM is its idiosyncratic temporality: the onset is typically delayed, often emerging 24–48 hours postoperatively. The duration is variable, albeit self-limiting and usually resolving in weeks; the resolution often occurs rapidly, i.e. over days. However, many patients experience dysarthria throughout the recovery period and then suffer long-term speech and language dysfunction; this includes ataxic dysarthria, dysfluency and slowed speech rate [26]. Crucially, the duration of CM (i.e., whether 4 weeks or 4 months) will correlate with the functional prognosis. An absence of speech after PF tumour surgery was first described as "akinetic mutism" (AM) by Daly and Love in 1958 following the removal of a cerebellar tumour in a child [53]. However, a 1985 case series reporting on six children with cerebellar lesions is credited for the first reports of CM [54]. A complete absence of speech and up to 3 months of dysarthria was described following each posterior fossa craniectomy ('or a complication thereof'). The authors concluded that 'transient muteness may result from acute bilateral cerebellar injury' [55].

Since then, over 400 cases of CM have been reported in the literature. Law et al. [52] compared three groups of children—PF tumours with CM, PF tumours without CM, and healthy controls—to examine the clinical and neuroanatomical predictors of CM. The results of this study concluded that there was a statistically significant positive correlation between tumour size and the likelihood of developing CM. It also found that a greater proportion of children with CM were left-handed, compared to those without CM. However, medulloblastoma and/ or brainstem invasion appear to pose the greatest risk of CM, while cerebellar hemisphere involvement is associated with highest risk of permanent motor and non-motor-speech related deficits [54]

system required for initiating voluntary movement and higher cognitive functions, including speech [54]. A literature review by Gudrunardottir et al. [54] highlights evidence that bilateral lesions of the dentate nuclei and their connections (i.e., a bilateral interruption of the DTC

LH = left hemisphere, RH = right hemisphere. Reprinted with permission from Gudrunardottir et al. [54].

**Figure 4.** The topographic arrangement of functions in and around the vermis, dentate and fastigial nuclei. Language is lateralised to the right cerebellar hemisphere, executive functions and spatial processing to the left hemisphere and limbic/emotional functions to the vermis. Lesions of the anterior lobe result in truncal ataxia and hypotonia, while lesion of the posterior lobe result in appendicular ataxia, hypotonia and tremor. DN = dentate nucleus, FN = fastigial nucleus,

Neuropsychiatry: Aspects of Childhood Cranial Tumours http://dx.doi.org/10.5772/intechopen.75679 179

Under normal circumstances, the cerebral cortex and cerebellum are in circuit via afferent and efferent signalling. Impulses originating within the cerebral cortex travel along axons via the cortico-ponto-cerebellar pathway to deliver input to the cerebellum, i.e., ultimately synapsing on the Purkinje cell layer of the cerebellum. Axons from these neurons form inhibitory synapses on the deep cerebellar nuclei, from which excitatory projections carry efferent signals travel throughout the CNS—to the spinal cord, brainstem and cerebral cortex—i.e., areas known for co-ordination of movement. The efferent pathway which finally communicates with the cerebral cortex is the DTC pathway. The tract is comprised of axons originating within the dentate nuclei (DN). The DN act as relay stations and send efferent signals back to the cerebral cortex via the DTC pathway; this tract travels through the ipsilateral superior cerebellar peduncle, and after decussation in the midbrain tegmentum, synapses within the contralateral ventrolateral nucleus of the thalamus. From the thalamus, second order axons terminate in the primary motor cortex as well as secondary and tertiary association areas within the frontal and parietal lobes. Thus, via the DTC pathway/tract, cognition and behaviour are likely modulated, a theory supported by the cognitive, linguistic and behavioural-affective impairments

Indeed, it is this vulnerable (i.e., peri-operatively) efferent white matter DTC tract that, if damaged, may be responsible for CM: therefore, any direct (i.e., trauma) or indirect (i.e., oedema)

seen with an injury of the cerebellum and/or proximal DTC tract [63, 64].

pathway) are the principal causes of CM [59–62].

In 2011, Di Rocco et al. [56] carried out a study on 34 children with PF tumours with the aim of determining whether there was a correlation between pre-operative language impairment (PLI) and post-operative development of CM. In their study, 11 out of 34 children had PLI; all 11 of these patients were among the subjects that ultimately developed CM (20.6%). Other pre-operative findings in this study included behavioural disorders (sleep, hyperkinetic and somatic complaints). As well as a number of neuropsychological deficits [56]. The children with pre-operative behavioural problems continued to experience these difficulties post-operatively. The primary status of CM as a neuro-surgical sequela is thought to be due to bilateral perturbation of the dentate nuclei and their efferent pathway. As we will discuss, the pathophysiological mechanisms of delayed onset and resolution of CM are hypothesised to be due to axonal damage, oedema, perfusional defects and metabolic disturbances [54].

In 1994, Crutchfield et al. [57] were the first to appreciate the role of the dentato-thalamo-cortical (DTC) pathway as an anatomical substrate in CM. They illustrated a phenomenon called bilateral crossed cerebello-cerebral diaschisis (BCCCD): a cerebellar lesion causes a lack of excitatory impulses from the cerebellum and hypoperfusion, decreased oxygen consumption, hypometabolism and functional inhibition subsequently occur in anatomically connected supratentorial structures [58].

Essentially, symmetrical dentate nuclei that are located in the paravermal regions of lobules VI and VII of the cerebellum give rise to a cerebello-cerebral connection (see **Figure 4**), a complex

idiosyncratic temporality: the onset is typically delayed, often emerging 24–48 hours postoperatively. The duration is variable, albeit self-limiting and usually resolving in weeks; the resolution often occurs rapidly, i.e. over days. However, many patients experience dysarthria throughout the recovery period and then suffer long-term speech and language dysfunction; this includes ataxic dysarthria, dysfluency and slowed speech rate [26]. Crucially, the duration of CM (i.e., whether 4 weeks or 4 months) will correlate with the functional prognosis. An absence of speech after PF tumour surgery was first described as "akinetic mutism" (AM) by Daly and Love in 1958 following the removal of a cerebellar tumour in a child [53]. However, a 1985 case series reporting on six children with cerebellar lesions is credited for the first reports of CM [54]. A complete absence of speech and up to 3 months of dysarthria was described following each posterior fossa craniectomy ('or a complication thereof'). The authors concluded that 'transient muteness may result from acute bilateral

Since then, over 400 cases of CM have been reported in the literature. Law et al. [52] compared three groups of children—PF tumours with CM, PF tumours without CM, and healthy controls—to examine the clinical and neuroanatomical predictors of CM. The results of this study concluded that there was a statistically significant positive correlation between tumour size and the likelihood of developing CM. It also found that a greater proportion of children with CM were left-handed, compared to those without CM. However, medulloblastoma and/ or brainstem invasion appear to pose the greatest risk of CM, while cerebellar hemisphere involvement is associated with highest risk of permanent motor and non-motor-speech

In 2011, Di Rocco et al. [56] carried out a study on 34 children with PF tumours with the aim of determining whether there was a correlation between pre-operative language impairment (PLI) and post-operative development of CM. In their study, 11 out of 34 children had PLI; all 11 of these patients were among the subjects that ultimately developed CM (20.6%). Other pre-operative findings in this study included behavioural disorders (sleep, hyperkinetic and somatic complaints). As well as a number of neuropsychological deficits [56]. The children with pre-operative behavioural problems continued to experience these difficulties post-operatively. The primary status of CM as a neuro-surgical sequela is thought to be due to bilateral perturbation of the dentate nuclei and their efferent pathway. As we will discuss, the pathophysiological mechanisms of delayed onset and resolution of CM are hypothesised to be due to axonal damage, oedema, perfusional defects and metabolic disturbances [54].

In 1994, Crutchfield et al. [57] were the first to appreciate the role of the dentato-thalamo-cortical (DTC) pathway as an anatomical substrate in CM. They illustrated a phenomenon called bilateral crossed cerebello-cerebral diaschisis (BCCCD): a cerebellar lesion causes a lack of excitatory impulses from the cerebellum and hypoperfusion, decreased oxygen consumption, hypometabolism and functional inhibition subsequently occur in anatomically connected

Essentially, symmetrical dentate nuclei that are located in the paravermal regions of lobules VI and VII of the cerebellum give rise to a cerebello-cerebral connection (see **Figure 4**), a complex

cerebellar injury' [55].

178 Brain Tumors - An Update

related deficits [54]

supratentorial structures [58].

**Figure 4.** The topographic arrangement of functions in and around the vermis, dentate and fastigial nuclei. Language is lateralised to the right cerebellar hemisphere, executive functions and spatial processing to the left hemisphere and limbic/emotional functions to the vermis. Lesions of the anterior lobe result in truncal ataxia and hypotonia, while lesion of the posterior lobe result in appendicular ataxia, hypotonia and tremor. DN = dentate nucleus, FN = fastigial nucleus, LH = left hemisphere, RH = right hemisphere. Reprinted with permission from Gudrunardottir et al. [54].

system required for initiating voluntary movement and higher cognitive functions, including speech [54]. A literature review by Gudrunardottir et al. [54] highlights evidence that bilateral lesions of the dentate nuclei and their connections (i.e., a bilateral interruption of the DTC pathway) are the principal causes of CM [59–62].

Under normal circumstances, the cerebral cortex and cerebellum are in circuit via afferent and efferent signalling. Impulses originating within the cerebral cortex travel along axons via the cortico-ponto-cerebellar pathway to deliver input to the cerebellum, i.e., ultimately synapsing on the Purkinje cell layer of the cerebellum. Axons from these neurons form inhibitory synapses on the deep cerebellar nuclei, from which excitatory projections carry efferent signals travel throughout the CNS—to the spinal cord, brainstem and cerebral cortex—i.e., areas known for co-ordination of movement. The efferent pathway which finally communicates with the cerebral cortex is the DTC pathway. The tract is comprised of axons originating within the dentate nuclei (DN). The DN act as relay stations and send efferent signals back to the cerebral cortex via the DTC pathway; this tract travels through the ipsilateral superior cerebellar peduncle, and after decussation in the midbrain tegmentum, synapses within the contralateral ventrolateral nucleus of the thalamus. From the thalamus, second order axons terminate in the primary motor cortex as well as secondary and tertiary association areas within the frontal and parietal lobes. Thus, via the DTC pathway/tract, cognition and behaviour are likely modulated, a theory supported by the cognitive, linguistic and behavioural-affective impairments seen with an injury of the cerebellum and/or proximal DTC tract [63, 64].

Indeed, it is this vulnerable (i.e., peri-operatively) efferent white matter DTC tract that, if damaged, may be responsible for CM: therefore, any direct (i.e., trauma) or indirect (i.e., oedema) circulatory disturbance may cause hypoperfusion and metabolic related hypofunction in both cerebellar hemispheres, and a loss of function (diaschisis) in the areas mediated by the DTP [65]. CM thus results from a lesion anywhere along this path: bilateral thalamotomies; SMA lesions; bilateral oedema in the brachium pontis; and finally, superior cerebellar peduncles are also potential lesions. Nevertheless, bilateral injury to the dentate nuclei is the most frequently implicated cause [54].

neurotransmitter release has been postulated by Siffert et al. [74] in their concept that the cerebellum and its connections are tantamount to a 'modulatory system', controlling motor and non-motor functions. Finally, imaging studies imply that pathogenesis of CM could be from surgical manipulation, traction and release of tumour compression, resulting in axonal

Neuropsychiatry: Aspects of Childhood Cranial Tumours http://dx.doi.org/10.5772/intechopen.75679 181

CM risk is increased by several tumour-related factors: brainstem involvement [76]; (iatrogenic) brainstem compression; and midline (vermal and fourth ventricle) location [77]—i.e., MB is by far the most common cause of CM in the paediatric population. To illustrate this, two large studies found that the incidence of CM in children with medulloblastoma was 24% [78], and 44% if brainstem was involved [76]. Radical tumour removal [77] and young age at diagnosis [76] have inconsistent evidence [78], although some reports these as risk factors for CM [79]. Conversely, theories such as hydrocephalus, post-operative CNS infection (like meningitis), gender, length of vermal incision, type of neurosurgeon (paediatric vs. adult) and

The prognosis and course of recovery in CM is variable, albeit largely unfavourable, even in spite of the resolution of mutism: two-thirds of patients will still suffer motor-speech deficits even after 12 months [81]; one-third will have persistent dysarthria; the remainder show a residual phonological impairment (including adynamic spontaneous speech production, impaired verbal fluency, word-finding difficulties and grammatical disturbances) [58]. Dysarthric features are more protracted and less amenable to recovery in children with associated combined proce-

With regards preventing CM, surgical mitigation is a possibility: piecemeal removal (to protect the vermis) [82]; sparing of (cognitively significant) right cerebellar hemisphere [69], and finally, using a specific (telovelar) approach to access the fourth ventricle and avoid splitting the vermis [83]. In support of this approach, a series of telovelar cases showed no incidence of mutism; splitting the vermis reduced rates in one hospital and at another site similar surgical practices (e.g., less aggressive retraction) resulted in fewer

Once regarded as an isolated deficit, CM is now well recognised as the predominant feature of the more expansive 'posterior fossa syndrome' (PFS; see below). Although CM and PFS appear to have separate anatomical substrates, topographical proximity ensures posterior

In the relevant literature, across almost four decades, CM has been confused with other terms, including TCM, CMS [86] and MSD [87]. Furthermore, some authors use two or more of these

The essence of PFS is the constellation of four core symptoms: mutism, ataxia, behavioural disturbance and emotional lability; they occur in about 25% of children after the surgical

distortion and/or injury [63, 75].

cases of CM [84, 85].

**2.4. Posterior fossa syndrome**

oedema/swelling have been refuted over recent years [80].

dural memory and defective neurocognitive functions present at diagnosis.

fossa surgery can result in any combination of the shared phenomena.

terms interchangeably, including CM and PFS [48].

resection of a posterior fossa tumour (**Figure 5**).

Clinically, anatomical correlates of cerebellar lesions are relatively distinct: anterior lesions cause ataxia and hypotonia; while those in the posterior induce appendicular ataxia, hypotonia and tremor [66] (see **Figure 4**). The origin of the hemiparesis and lower cranial nerve dysfunction seen in the PFS is not known, although brainstem injury and/or damage to the dentate nuclei/DTC pathway are hypothesised [54]. In addition to its role in balance and co-ordination, the cerebellum is integral to higher cognitive processses (the cerebellar hemispheres) and regulation of affect (the vermis) [66]. The left cerebellar hemisphere is designated spatial and executive responsibility, and the right is tasked with language [64, 67]. The disruption between the right cerebellum and left frontal cortex likely contributes to the linguistic difficulties observed in CM. Interestingly, a study also found that all left-handed patients with MB had a 100% risk of developing CM post-operatively. It is possible that such correlates will pave the way for pre-op clinical profiles to inform post-operative rehabilitation, across the allied health spectrum [68]. As discussed, the dentate nuclei, the vermis, and the right cerebellar hemisphere are all important in cognitive performance; accordingly, damage to these structures, informed by MRI, can be used to predict the degree of post-operative neurological and neuropsychological impairment in children following PF tumour resection [69].

Of note, mutism that occurs immediately after surgery is indicative of bulbar dysfuction from damage to cranial nerve nuclei in the nuclie, rather than CM [70]. However, in typical CM, 'secondary processes' initiated by the tumour resection, are the likely underlying pathophysiological mechanism, and four have been described in literature: (1) dynamic perfusional disturbances, (2) oedema, (3) transient disturbances in neurotransmitter release, and (4) axonal injury.

First, dynamic perfusional disturbances in the cerebellum and the cerebrum are suspected causes of CM due to the delayed onset (i.e., possible vasospasms), type of disturbance (i.e., transient ischemia) and resolution (i.e., normalisation of blood flow). Surgical manipulation of the cerebellum [71], intra-operative coagulation of perforating vessels [72] and arterial embolic occlusion [73] are the suspected catalysts of such disturbances; cerebello-cerebral diaschisis is implicated when the proximal DTC pathway is damaged [54]. In fact, two small single proton emission computed tomography (SPECT) studies demonstrated a cerebellar hypoperfusion in mute patients which resolved as speech returned [72, 73]. Two other possible mechanisms of recovery are neuronal plasticity and reassignment of speech function within the cortical processing network.

Secondly, the latency of CM reflects post-operative swelling, with imaging studies (CT, MRI and DTI) demonstrating mutism occurring with bilateral oedema in the superior cerebellar peduncles and/or the pons or mesencephalon after PF tumour resection. Indeed, corticosteroids may prove useful in the context of this mechanism. Thirdly, dysregulation of neurotransmitter release has been postulated by Siffert et al. [74] in their concept that the cerebellum and its connections are tantamount to a 'modulatory system', controlling motor and non-motor functions. Finally, imaging studies imply that pathogenesis of CM could be from surgical manipulation, traction and release of tumour compression, resulting in axonal distortion and/or injury [63, 75].

CM risk is increased by several tumour-related factors: brainstem involvement [76]; (iatrogenic) brainstem compression; and midline (vermal and fourth ventricle) location [77]—i.e., MB is by far the most common cause of CM in the paediatric population. To illustrate this, two large studies found that the incidence of CM in children with medulloblastoma was 24% [78], and 44% if brainstem was involved [76]. Radical tumour removal [77] and young age at diagnosis [76] have inconsistent evidence [78], although some reports these as risk factors for CM [79]. Conversely, theories such as hydrocephalus, post-operative CNS infection (like meningitis), gender, length of vermal incision, type of neurosurgeon (paediatric vs. adult) and oedema/swelling have been refuted over recent years [80].

The prognosis and course of recovery in CM is variable, albeit largely unfavourable, even in spite of the resolution of mutism: two-thirds of patients will still suffer motor-speech deficits even after 12 months [81]; one-third will have persistent dysarthria; the remainder show a residual phonological impairment (including adynamic spontaneous speech production, impaired verbal fluency, word-finding difficulties and grammatical disturbances) [58]. Dysarthric features are more protracted and less amenable to recovery in children with associated combined procedural memory and defective neurocognitive functions present at diagnosis.

With regards preventing CM, surgical mitigation is a possibility: piecemeal removal (to protect the vermis) [82]; sparing of (cognitively significant) right cerebellar hemisphere [69], and finally, using a specific (telovelar) approach to access the fourth ventricle and avoid splitting the vermis [83]. In support of this approach, a series of telovelar cases showed no incidence of mutism; splitting the vermis reduced rates in one hospital and at another site similar surgical practices (e.g., less aggressive retraction) resulted in fewer cases of CM [84, 85].

#### **2.4. Posterior fossa syndrome**

circulatory disturbance may cause hypoperfusion and metabolic related hypofunction in both cerebellar hemispheres, and a loss of function (diaschisis) in the areas mediated by the DTP [65]. CM thus results from a lesion anywhere along this path: bilateral thalamotomies; SMA lesions; bilateral oedema in the brachium pontis; and finally, superior cerebellar peduncles are also potential lesions. Nevertheless, bilateral injury to the dentate nuclei is the most fre-

Clinically, anatomical correlates of cerebellar lesions are relatively distinct: anterior lesions cause ataxia and hypotonia; while those in the posterior induce appendicular ataxia, hypotonia and tremor [66] (see **Figure 4**). The origin of the hemiparesis and lower cranial nerve dysfunction seen in the PFS is not known, although brainstem injury and/or damage to the dentate nuclei/DTC pathway are hypothesised [54]. In addition to its role in balance and co-ordination, the cerebellum is integral to higher cognitive processses (the cerebellar hemispheres) and regulation of affect (the vermis) [66]. The left cerebellar hemisphere is designated spatial and executive responsibility, and the right is tasked with language [64, 67]. The disruption between the right cerebellum and left frontal cortex likely contributes to the linguistic difficulties observed in CM. Interestingly, a study also found that all left-handed patients with MB had a 100% risk of developing CM post-operatively. It is possible that such correlates will pave the way for pre-op clinical profiles to inform post-operative rehabilitation, across the allied health spectrum [68]. As discussed, the dentate nuclei, the vermis, and the right cerebellar hemisphere are all important in cognitive performance; accordingly, damage to these structures, informed by MRI, can be used to predict the degree of post-operative neurological

and neuropsychological impairment in children following PF tumour resection [69].

Of note, mutism that occurs immediately after surgery is indicative of bulbar dysfuction from damage to cranial nerve nuclei in the nuclie, rather than CM [70]. However, in typical CM, 'secondary processes' initiated by the tumour resection, are the likely underlying pathophysiological mechanism, and four have been described in literature: (1) dynamic perfusional disturbances, (2) oedema, (3) transient disturbances in neurotransmitter release, and (4) axonal injury. First, dynamic perfusional disturbances in the cerebellum and the cerebrum are suspected causes of CM due to the delayed onset (i.e., possible vasospasms), type of disturbance (i.e., transient ischemia) and resolution (i.e., normalisation of blood flow). Surgical manipulation of the cerebellum [71], intra-operative coagulation of perforating vessels [72] and arterial embolic occlusion [73] are the suspected catalysts of such disturbances; cerebello-cerebral diaschisis is implicated when the proximal DTC pathway is damaged [54]. In fact, two small single proton emission computed tomography (SPECT) studies demonstrated a cerebellar hypoperfusion in mute patients which resolved as speech returned [72, 73]. Two other possible mechanisms of recovery are neuronal plasticity and reassignment of speech function

Secondly, the latency of CM reflects post-operative swelling, with imaging studies (CT, MRI and DTI) demonstrating mutism occurring with bilateral oedema in the superior cerebellar peduncles and/or the pons or mesencephalon after PF tumour resection. Indeed, corticosteroids may prove useful in the context of this mechanism. Thirdly, dysregulation of

quently implicated cause [54].

180 Brain Tumors - An Update

within the cortical processing network.

Once regarded as an isolated deficit, CM is now well recognised as the predominant feature of the more expansive 'posterior fossa syndrome' (PFS; see below). Although CM and PFS appear to have separate anatomical substrates, topographical proximity ensures posterior fossa surgery can result in any combination of the shared phenomena.

In the relevant literature, across almost four decades, CM has been confused with other terms, including TCM, CMS [86] and MSD [87]. Furthermore, some authors use two or more of these terms interchangeably, including CM and PFS [48].

The essence of PFS is the constellation of four core symptoms: mutism, ataxia, behavioural disturbance and emotional lability; they occur in about 25% of children after the surgical resection of a posterior fossa tumour (**Figure 5**).

In 1995, Pollack et al. [89] described a case series of children with open resection of infratentorial tumours. Following review of case records, 12 of these patients manifested with post-operative mutism. There was considerable variation between the clinical presentation, (i.e., pseudobulbar, neurobehavioural symptoms); however, a "stereotypical response" was observed in 11 cases; these patients were "curled up in bed and whining inconsolably, without actually uttering intelligible speech". All the children achieved full recovery within 4 months of surgery, bar one exception with persistent mild dysarthria. This finding is supported by a case series of children with cerebellar astrocytoma and vermal lesions who were surgically treated for their respective PF tumours [90]. Positive findings were seen in a number of the children with vermal lesions: post-operative mutism in six; behavioural disturbances in five, e.g., irritability, avoidance of others; and severe autistic behaviours in one. Similar to the study by Pollack et al. [89], almost all subjects achieved full or almost full

Neuropsychiatry: Aspects of Childhood Cranial Tumours http://dx.doi.org/10.5772/intechopen.75679 183

Another syndrome, cerebellar cognitive affective syndrome (CCAS), has been reported following acquired cerebellar lesions, such as infarction and inflammation [91, 92]. Some authors consider PFS to represent the acute manifestation of CCAS [92]. CCAS is primarily characterised by a deficit in emotional regulation that causes personality change; thus, a flattening or blunting of affect, and disinhibited/inappropriate behaviour are commonly seen. The syndrome also manifests as impairment of executive function (planning, set-shifting, verbal fluency, abstract reasoning and working memory difficulties) and visuospatial cognition. Finally, language deficits, including agrammatism and dysprosody are recognised features. This syndrome, described originally by Schmahmann et al. [93], is neurobiologically underpinned by the cerebellar organisation of higher order function, and more specifically, the associated modulatory role in mental and social function, operative early in childhood [26]. Hopyan et al. [91] compared cognitive control of emotions in cerebellar tumours against healthy matched controls. In their study, they tested the ability to identify happy and sad emotions in music. Contrary to their hypothesis, this study demonstrated largely normal emotional identification in both groups, but the control group performed better at emotional regulation tasks. The fact that in the study, childhood acquired cerebellar tumours disrupted cognitive control of emotion, rather than identification of emotion, provides support for a hypothesis of CCAS as a disorder not so much of emotion, but more so the regulation of emotion by cognition. A case series of 19 patients with cerebellar lesions also succeeded in illustrating cases of emotional dyscontrol in cerebellar tumours: an acute syndrome of inattention, dysphoria and emotional

A case series by Hargrave et al. [94] described a slightly different manifestation of emotional dyscontrol in paediatric patients (aged 3–11) with pontine glioma. In 36% of the cases, outbursts of inappropriate laughter (i.e., "pathological laughter") were observed in wakefulness and sleep. Of note, symptoms improved in all cases following treatment but often returned in cases of tumour recurrence. Beckwitt-Turkel et al. [95] compared PFS symptoms before and after paediatric PF surgery in a naturalistic study. PFS was associated

recovery within a month.

**2.6. Cerebellar cognitive affective syndrome**

distress followed surgery of midline PF [92].

**Figure 5.** Posterior fossa syndrome. Reprinted with permission from Lanier et al. [84].

#### **2.5. Posterior fossa syndrome cases**

In a review of PFS, Lanier and Abrahams [88] summarised proposed theories/risk facors for PFS: 1. involvement of the vermis, 2. brainstem involvement, 3. bilateral edema within the cerebellar peduncles post surgery, 4.aggressive surgery of the cerebellum, 5. transient impairment of the DTC pathways, 6. midline location of the tumor, 7. focal vasospasms, 8. neurotransmitter dysfunction and 9. hydrocephalus. As expected, most overlap with those already discussed with regards to CM. These authors also presented a case series of PFS from their own institution, the Massachussetts General Hospital for Children. Three cases of resected medulloblastoma are described with regards boys aged 7–13 years. Post-operatively, two of the four cases suffered from mutism and another two cases had paucity of speech (e.g. monosyllabic) and dysarthria, respectively. All four cases had evidence of ataxia, emotional lability and behavioural symptoms. Of the mutism cases, both fully resolved with complete return of speech and good emotional stability; however, both had ongoing ataxia and one later died of a tumour recurrence. The third case (post-op paucity of speech) had screaming episodes with "screeching" and subsequently developed depression. At follow-up 5 years later, although in school he continued to have social and emotional difficulties. The final case (post-op dysarthria) initially had serious emotional dyscontrol with self-harming behaviour; this resolved with low dose risperidone. At her 5 year follow-up, she had no speech or behavioural issues, although balance remained problematic. Of note, three of these cases required psychotropic medication (low dose risperidone or lorazepam) to manage the emotional lability and behavioural issues.

In 1995, Pollack et al. [89] described a case series of children with open resection of infratentorial tumours. Following review of case records, 12 of these patients manifested with post-operative mutism. There was considerable variation between the clinical presentation, (i.e., pseudobulbar, neurobehavioural symptoms); however, a "stereotypical response" was observed in 11 cases; these patients were "curled up in bed and whining inconsolably, without actually uttering intelligible speech". All the children achieved full recovery within 4 months of surgery, bar one exception with persistent mild dysarthria. This finding is supported by a case series of children with cerebellar astrocytoma and vermal lesions who were surgically treated for their respective PF tumours [90]. Positive findings were seen in a number of the children with vermal lesions: post-operative mutism in six; behavioural disturbances in five, e.g., irritability, avoidance of others; and severe autistic behaviours in one. Similar to the study by Pollack et al. [89], almost all subjects achieved full or almost full recovery within a month.

#### **2.6. Cerebellar cognitive affective syndrome**

**2.5. Posterior fossa syndrome cases**

182 Brain Tumors - An Update

In a review of PFS, Lanier and Abrahams [88] summarised proposed theories/risk facors for PFS: 1. involvement of the vermis, 2. brainstem involvement, 3. bilateral edema within the cerebellar peduncles post surgery, 4.aggressive surgery of the cerebellum, 5. transient impairment of the DTC pathways, 6. midline location of the tumor, 7. focal vasospasms, 8. neurotransmitter dysfunction and 9. hydrocephalus. As expected, most overlap with those already discussed with regards to CM. These authors also presented a case series of PFS from their own institution, the Massachussetts General Hospital for Children. Three cases of resected medulloblastoma are described with regards boys aged 7–13 years. Post-operatively, two of the four cases suffered from mutism and another two cases had paucity of speech (e.g. monosyllabic) and dysarthria, respectively. All four cases had evidence of ataxia, emotional lability and behavioural symptoms. Of the mutism cases, both fully resolved with complete return of speech and good emotional stability; however, both had ongoing ataxia and one later died of a tumour recurrence. The third case (post-op paucity of speech) had screaming episodes with "screeching" and subsequently developed depression. At follow-up 5 years later, although in school he continued to have social and emotional difficulties. The final case (post-op dysarthria) initially had serious emotional dyscontrol with self-harming behaviour; this resolved with low dose risperidone. At her 5 year follow-up, she had no speech or behavioural issues, although balance remained problematic. Of note, three of these cases required psychotropic medication (low dose risperidone or lorazepam) to manage the emotional lability and behavioural issues.

**Figure 5.** Posterior fossa syndrome. Reprinted with permission from Lanier et al. [84].

Another syndrome, cerebellar cognitive affective syndrome (CCAS), has been reported following acquired cerebellar lesions, such as infarction and inflammation [91, 92]. Some authors consider PFS to represent the acute manifestation of CCAS [92]. CCAS is primarily characterised by a deficit in emotional regulation that causes personality change; thus, a flattening or blunting of affect, and disinhibited/inappropriate behaviour are commonly seen. The syndrome also manifests as impairment of executive function (planning, set-shifting, verbal fluency, abstract reasoning and working memory difficulties) and visuospatial cognition. Finally, language deficits, including agrammatism and dysprosody are recognised features. This syndrome, described originally by Schmahmann et al. [93], is neurobiologically underpinned by the cerebellar organisation of higher order function, and more specifically, the associated modulatory role in mental and social function, operative early in childhood [26]. Hopyan et al. [91] compared cognitive control of emotions in cerebellar tumours against healthy matched controls. In their study, they tested the ability to identify happy and sad emotions in music. Contrary to their hypothesis, this study demonstrated largely normal emotional identification in both groups, but the control group performed better at emotional regulation tasks. The fact that in the study, childhood acquired cerebellar tumours disrupted cognitive control of emotion, rather than identification of emotion, provides support for a hypothesis of CCAS as a disorder not so much of emotion, but more so the regulation of emotion by cognition. A case series of 19 patients with cerebellar lesions also succeeded in illustrating cases of emotional dyscontrol in cerebellar tumours: an acute syndrome of inattention, dysphoria and emotional distress followed surgery of midline PF [92].

A case series by Hargrave et al. [94] described a slightly different manifestation of emotional dyscontrol in paediatric patients (aged 3–11) with pontine glioma. In 36% of the cases, outbursts of inappropriate laughter (i.e., "pathological laughter") were observed in wakefulness and sleep. Of note, symptoms improved in all cases following treatment but often returned in cases of tumour recurrence. Beckwitt-Turkel et al. [95] compared PFS symptoms before and after paediatric PF surgery in a naturalistic study. PFS was associated with midline and vermis involvement (and not lateral involvement) and was characterised by mutism, apathy and dysphoria. These symptoms presented early post-operatively, although affective and behavioural disturbances appeared at a later stage, with all symptoms, bar depression, resolving over time. In 2010, Larysz et al. [96] looked at a group of 34 children (mean age 12.3 years) with PF tumours (14 cerebellar, 20 extracerebellar) to establish whether neuropsychological deficits related to tumour location: neoplasms in the brainstem and vermis had a better outcome than those in the cerebellum. This finding was consistent with Riva et al. [97] whose sample showed an association between non-vermal tumours with language dysfunction; in the same sample, vermal tumours were more likely to present with neurobehavioural changes (emotional lability, irritability, weepiness, impulsiveness and shyness).

behaviour, as well as neuropsychological deficits, social maladjustment and poor school performance [23]. Finally, a study of paediatric and adult survivors of childhood brain tumours in 2013 revealed that more than 1 in 10 had reported suicidal ideation on at least one occasion, as documented in their medical records. The older patients, with greater co-morbidities (i.e.,

Neuropsychiatry: Aspects of Childhood Cranial Tumours http://dx.doi.org/10.5772/intechopen.75679 185

Around 9000 new primary brain and CNS tumours (CNST) are diagnosed every year in the UK, suggesting that a GP will diagnose a case every 3–5 years. Presenting complaints range from well recognised symptoms (i.e., headaches, new-onset seizures) to the more insidious, such as personality change. A combined retrospective and prospective study of 104 consecutive paediatric patients with brain tumours found that the median time from symptom onset to diagnosis was 3 months. However, diagnosis of CNST (whether primary or secondary) can be performed with the GP retaining clinical responsibility, i.e., ordering necessary diagnostic

'NICE alert symptoms' (e.g., neurological, headache, fatigue, back pain, bruising, lymphadenopathy, lump/mass/swelling, urinary symptoms, hepatosplenomegaly) and any new pattern of recurrent attendances to the GP are ominous warning signs for childhood CNST [102]. Ansell et al. [103] advised that 'the key to identifying the one child among many who merits prompt investigation is recognition of unusual symptoms, or specific symptom patterns'; these included head tilt, odd head movements, odd posture, back or neck stiffness and unsteadiness without obvious cause [103]. In concert with clinical acumen and intuition, the GP must respect the value of a parent's instinct that their child 'is not right', regardless of a

The 2015 NICE guidelines, entitled 'Suspected Cancer: Recognition and Referral', features a section on 'Brain and CNS cancer' that informs clinicians about which specific symptoms in children and adolescents require investigation and/or neuro-oncological referral. Based on these symptoms, the positive predictive values (PPV) of having CNST varied in range: from <0.013% (for vomiting or headache, with loss of appetite) to 0.15 (for vomiting, in combination with unsteadiness) for patients aged 0–14 years old; and, from 0% (for primary headache) to 0.03% (for undifferentiated headache) for patients aged 5–17 years; and from 0.0029% (for

Adult referral was recommended for those symptoms with a PPV of 3% or above, i.e., the advantages of a suspected CNST pathway referral outweighed any disadvantages. However, in childhood cancer, such a threshold was deemed too stringent for the following reasons: (1) the high levels of treatability of these cancers, (2) early diagnosis can reduce mortality and

Referral at lower levels of risk than 3% is therefore permitted in children and adolescents. Accordingly, GPs/physicians/psychiatrists 'should consider a very urgent referral (for an appointment within 48 h) for a suspected brain or central nervous system cancer in children

pain) to 0.0238% (for seizure) for patients aged 15–24 years [101].

morbidity, and (3) the number of life-years gained.

seizure disorder) were at highest risk [24].

**2.8. Clinical guidelines**

neuro-imaging tests [101].

specific problem *per se* [104].

#### **2.7. Psychological and adjustment disorder**

In 2013, an article published by Pastore et al. [98] compared the neuropsychological profiles and behavioural symptoms in pre-school children with brain lesions: 18 of the 55 patients were brain tumour survivors and the remainder had traumatic, vascular or infectious lesions. The brain tumour group had high levels of internalising problems (77.8%); specifically, a combination of anxiety and/or depression and/or somatic symptoms and withdrawal were present in about half of the sample. However, the group with traumatic brain injury and non-cancerous brain lesions presented with externalising behaviours and aggression. These findings are consistent with those from a study of paediatric brain tumour survivors, in which the child behaviour checklist indicated that internalising behaviours (depression/ anxiety) were the most common (48.4%) psychological disorder, while externalising behaviours were present in just 11.8%. Furthermore, those aged 7–13 were most predisposed to psychological problems, whereas social maladjustment was more frequent in those older than 13. These findings were relevant as they indicated the long-term psychosocial outcome of these individuals [99].

Campen et al. [100] found a high rate of depression and adjustment disorders (30.4%) in 56 children treated for MB, particularly if they were older and male. Importantly, the multimodal therapy in MB—which is generally a protracted process—influences the neurodevelopmental maturation that is implicated in the pathogenesis of depression. Therefore, their low mood is not just explainable as an expected psychological burden; rather, it is also engendered by neurobiological mechanisms such as a disruption of hippocampal cell formation and the saturation of the limbic system. Therefore, Campen et al. found a significant difference in age at diagnosis between those who developed depression, anxiety and adjustment disorder (median 9.5 years) and those who did not (median 5.9 years), with a median time to first psychiatric symptom of 7 months. Similarly, a study of children treated for craniopharyngioma highlighted a high rate of psychiatric morbidity in the study population; 100% of subjects experienced depression; 75% suffered poor frustration tolerance and 40% had anger dyscontrol [22]. Likewise, a case series of 20 subjects described poor neurobehavioural outcomes in post-operative paediatric craniopharyngioma: 85% of subjects had some degree of internalising (apathy, poor motivation) and externalising (irritability, hyperactivity, aggression) behaviour, as well as neuropsychological deficits, social maladjustment and poor school performance [23]. Finally, a study of paediatric and adult survivors of childhood brain tumours in 2013 revealed that more than 1 in 10 had reported suicidal ideation on at least one occasion, as documented in their medical records. The older patients, with greater co-morbidities (i.e., seizure disorder) were at highest risk [24].
