Opinion statement
The assessment of autism spectrum disorder (ASD) is complex and remains clinical, despite advances in basic research. In this chapter, we review new and updated clinical tools, such as screening and diagnostic tests, and discuss the DSM-5 criteria introduced in 2013. We provide an algorithm to guide clinical evaluation and referrals. We also review non-behavioral treatments and summarize recent research. Current conventional treatment of ASD in children includes intensive behavioral interventions (known as applied behavioral analysis or ABA), rehabilitative services such as speech therapy, occupational therapy, physical therapy, social skills training, and counseling. We present new validated information and provide clinical guidance for the evaluation and treatment of young children and youth with ASD.
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Introduction
Autism spectrum disorder (ASD) is defined as delayed social communication skills and restricted, repetitive behaviors (RRB) [1]. The assessment of ASD is complex and remains clinical. In this chapter, we review new and updated tools and discuss DSM-5 criteria introduced in 2013 [1]. We also review non-behavioral treatments and summarize recent research.
The practice parameters introduced by Filipek et al. in 2001 [2••] and the recommendations from the American Academy of Pediatrics (AAP) [3••] continue to provide the basis for the assessment of ASD. The diagnosis of ASD continues to be made close to 4 years of age on average [4]. There are even greater delays in the identification of children from different cultural and ethnic backgrounds and low socio-economic status (SES). Children with ASD whose care is compliant with AAP guidelines [5•] are diagnosed earlier than children who receive no well-child care.
New assessments in ASD
Level-1 or universal ASD screening tests
The Modified Checklist for Autism in Toddlers (MCHAT) was updated in 2014 (MCHAT-R) [6] and now includes 20 questions. A score of 3–7 requires a follow-up interview to specify the risk category (www.mchatscreen.com). The cutoff score of 2 provides good sensitivity and specificity (Table 1), and a positive predictive value (PPV) for developmental delays of 98% (but only 54% for ASD). The Childhood Autism Spectrum Test (CAST; previously Childhood Asperger’s Syndrome Test) can be used for those older than 3 years [7].
Level 2 ASD screening measures
These can be helpful in informing clinicians. See table 1 for a list of measures and their properties, and note that it is not comprehensive. The Social Communication Questionnaire (SCQ) [8] includes questions based on the Autism Diagnostic Interview-Revised (ADI-R) [9], a 90-min structured interview for research about autism signs and symptoms that requires special training, has low psychometric strength for children younger than 55 months, and requires a mental age above 2 years, as does the SCQ. The Social Responsiveness Scale (SRS-2) [10] has been updated and seems to show better correlation with the ADI-R. The Childhood Autism Rating Scale (CARS-2) has been found to show good correlation with the DSM-5 [11]. The Gilliam Autism Rating Scale (GARS/GARS 2) has low sensitivity and specificity [12]. The GARS 3 is reported to have improved properties, though no studies are yet available on its performance in clinical settings.
Interactive level 2 ASD test
This is preferred to a questionnaire in younger children and provides a better observational context. In addition to the Screening Tool for Autism in Toddlers and Young Children (STAT) [13], the Rapid Interactive Screening Test for Autism in Toddlers (RITA-T) [14] is a new interactive level 2 screening test for 18–36-month-olds. The STAT requires training and 20 min for administration and scoring; it has good sensitivity and specificity for those 2–3-year-olds with autism. The RITA-T is administered and scored in less than 10 min, and its training is 3 h long. At a cutoff score of >14, it has good sensitivity (1), specificity (0, 84), and PPV (0, 88).
DSM-5
The DSM-5 groups ASD criteria into two domains (social communication and restricted, repetitive behaviors or RRB), compared to the three domains in the DSM-IV (social deficits, language deficits, repetitive stereotypic behaviors) [15]. DSM-5 criteria eliminate diagnostic subtypes within ASD that were present under DSM IV (Pervasive Developmental Disorder, Not Otherwise Specified or PDD-NOS, Asperger’s Syndrome, Childhood Disintegrative Disorder (CDD), and Autism). It also deletes age-of-onset criteria and adds specifiers (neurobiological disorders, risk factors, or genetic factors) and modifiers such as language, cognitive and learning levels, and ADHD.
Although the DSM-5 criteria provide structure and guidelines to inform diagnosis, they have limitations as well, especially for children younger than 5 years of age, in whom specificity appears low [16]. In addition, there are concerns about individuals with PDD-NOS meeting criteria on the DSM-IV who would not meet criteria on the DSM-5. Children younger than 5 years may have insufficient symptoms on the RRB category of the DSM-5: for example, the repetitive use of objects, hand-finger mannerisms, and unusual sensory interests occur commonly in younger children with autism or developmental delays, whereas compulsions, rituals, and resistance to change are less commonly endorsed in young children as these features tend to increase with age [17••]. Development is important in assessing social communication and RRB [18••].
The DSM-5 introduces a new category: Social Communication Disorder (SCD), for those who do not meet the criteria for RRB but have a significant social pragmatic impairment. It is unclear yet how school programs and services will be provided to this group of children.
In conclusion, the DSM-5 criteria can provide structure to inform assessment of ASD at all ages, though it is problematic in younger children. Further studies are needed to clarify the SCD diagnosis and impact of ASD as defined by DSM-5.
Autism Diagnostic Observation Schedule
The Autism Diagnostic Observation Schedule (ADOS) is a semi-structured observational diagnostic interview that assesses the social communication skills and RRB of children suspected to have ASD [19]. It has been updated to be consistent with the DSM-5, and a new toddler module has been developed (ADOS-T) [20]. The ADOS requires extensive training, time to administer, and is costly. However, it provides a structured setting to inform diagnosis and continues to be the gold standard measure in clinics that evaluate children for autism [21].
Evaluation of sensory processing difficulties
The evaluation and treatment of sensory behaviors have been foremost concerns since they were included in the DSM-5 criteria for ASD. It is important to assess the sensory difficulties that some children have (with sounds, touch, food) but recognize that these behaviors can be present in disorders other than ASD and to become familiar with measures to evaluate them [22], such as the Sensory Processing Measure (SPM) and the Sensory Profile [23, 24]. Some interventions can be beneficial, and the AAP has developed recommendations to monitor treatment and discuss options with families [25••].
Regression of language and social skills
Regression of language and social skills in ASD is reported to occur in 32.1% [26, 27]; it is described as an abrupt or gradual loss of previously acquired skills in children with ASD after apparently normal development for the first 1–2 years of life [26]. No specific causes or underlying mechanisms have been found, and there have been mixed results regarding prognosis and long-term outcomes of children with regression. When evaluating a child with a history of regression, it is crucial to tease out the developmental trajectory, investigate underlying pathophysiology such as seizure disorders and metabolic and genetic causes, and complete a clinical workup.
ASD assessment
ASD assessment needs to include a medical and developmental history with developmental trajectory and history of regression, as well as direct observation of behaviors. One can use validated measures to gather information from parents, teachers, or early intervention providers (such as the Vineland Adaptive Behavior Scales [28], or the Vanderbilt Questionnaires; Table 1). The evaluation of developmental and cognitive levels, educational and language testing, and ADHD evaluation are important [29] as well as assessments of other co-morbid conditions such as anxiety and mood disorders. It is also very important to consider cultural factors when evaluating children for ASD or other developmental delays. Please refer to useful recommendations developed by the Massachusetts Act Early State team (www.maactearly.org).
New research updates in ASD
Important recent studies on EEG, functional and structural MRI, eye tracking, autonomic functions, transcranial magnetic stimulation (TMS), noninvasive positron emission tomography (PET), and single photon emission computed tomography (SPECT) have investigated the underlying pathophysiology and identified potential biological markers for ASD [30]. These techniques are research tools at this point. Genetic research has greatly expanded our understanding of ASD (see below).
Eye tracking and pupillometry
Aberrant eye gaze mechanisms have been implicated in ASD such as diminished eye gaze and eye movements and can be studied using eye tracking technology [31•]. Pupillary constriction is a reliable measure of autonomic nervous system function, which is poorly modulated and correlates to sensory behaviors in ASD [31•]. Eye tracking and pupillometry have been combined in a novel study of social and emotional calibration in response to a standard stimulus. While eye tracking was similar to controls, children with ASD had less pupillary dilatation than controls, which correlated to the severity of ASD [32].
Autonomic nervous system
Respiratory and autonomic nervous system dysfunction in ASD show atypical respiratory patterns (Biot’s and Cheyne-Stokes) and cardiac vagal hypofunction using precise measures [33••]. Gastrointestinal dysfunction, anxiety, and history of developmental regression correlated to decreased cardiac vagal tone in ASD [34]. The findings implicate low parasympathetic activity in ASD and are consistent with chronic sensory hyperarousal.
Transcranial magnetic stimulation
Noninvasive repetitive transcranial magnetic stimulation (TMS) is a promising approach to the diagnosis and treatment of ASD. When it was applied in 12 weekly sessions over the dorsolateral prefrontal cortex in children with ASD, autonomic functions improved, along with behavioral measures [35]. TMS lends itself to research for understanding, as well as potential treatment, of altered synaptic plasticity in ASD [36]. TMS appears to be safe, but further research and clinical trials are needed [37•].
PET and SPECT
Several studies looking at different neurotransmitters, glucose metabolism, or cerebral blood flow in ASD are available; however, results are inconsistent. Anomalies have been reported in cerebral blood flow in the temporal lobes and speech areas and in glucose metabolism in the thalamus and putamen [38]. Serotonin is the most commonly investigated neurotransmitter in ASD [39] with reports of disruption of serotonergic innervation during development. PET and SPECT are research tools with no clinical indications at this point, and further studies are needed to identify biological mechanisms underlying ASD.
MRI/fMRI
Abnormalities of early brain growth have been reported; however, no consistent pathology has been identified on MRI. The size of the brain stem, posterior fossa, and corpus callosum and the volumes of the amygdala and hippocampus have been studied; abnormalities of the white matter have been reported [40•]. With diffusion tensor imaging (DTI), reduced fractional anisotropy and axial diffusivity were reported in ASD in numerous white matter tracts, including the corpus callosum and thalamocortical fibers [41]. Children with ASD exhibited atypical asymmetry in language-related white matter structure [42].
At this time, this is an area of research that has limitations as patient groups need to be well characterized clinically, and most studies lack longitudinal follow-up. The clinical indications for brain imaging (MRI) continue to be: focal neurological findings, epilepsy, or a focally abnormal EEG, and MRI is not recommended as a routine test.
Electroencephalography and magnetoencephalography
Electroencephalography (EEG) and magnetoencephalography (MEG) offer novel insights to brain function in ASD through research, as well as practical approaches to clinical evaluation. Abnormal findings on traditional EEG, such as focal slowing and paroxysmal discharges (even in the absence of clinical seizures), have been associated with ASD, especially in patients with developmental regression, macrocephaly, and temporal lobe localization [43]. Resting state EEG in children with ASD compared to controls, with quantitative methods, demonstrates reduced power in the alpha frequency range (8–14 Hz), as well as reduced network connectivity, which may reflect abnormal patterns of maturation and provide quantitative diagnostic biomarkers [44]. Despite advances, there are many complex variables involved in quantitative EEG that require further research [45•].
MEG is superior to EEG with respect to spatial resolution and does not depend on the electrical conductivity of brain tissue. When combined with MRI, one can precisely localize sources and strength of electrical activity as well as network connectivity. Although not yet widely available, resting state MEG, by itself, has shown atypical reduced connectivity and coherence between areas that correlate to low sociality in young children with ASD. These are becoming useful biomarkers for diagnosis and follow-up in clinical treatment trials [46]. When combined with functional connectivity MRI, hypoconnectivity between many sources of low or high gamma activity (30–60 Hz) becomes evident in patterns that differ in ASD compared to controls [47]. Gamma activity, measured by MEG, combined with magnetic resonance spectroscopy (MRS) to measure gamma-amino butyric acid (GABA) concentrations, has shown decreased GABA (the major inhibitory neurotransmitter) and atypical development of gamma-band coherence in children and adolescents with ASD [48••]. This approach will lend itself to understanding delayed maturation of excitatory: inhibitory balance in ASD, and to potential treatments, such as bumetanide, which increases GABA and may restore the normal maturational trajectory [49•].
Genetics
Genetic research has greatly expanded our understanding that the extreme clinical heterogeneity of ASD is connected to convergent biochemical pathways by identifying more than 100 specific genes and genomic regions and over 800 genes that are involved more generally [50]. In up to 40% of patients, ASD can now be associated with specific genetic abnormalities, up to 10% by copy number variations on chromosomal microarrays (most of which occur de novo), and 30% by whole exome or genome sequencing. Numerous genes and pathways have been identified in genome-wide association studies (GWAS) and gene sequencing technology that affect neurite outgrowth, synaptic functions, wnt signaling, and chromatin remodeling [51, 52]. Along with similar advances in related fields, it is now apparent that similar genetic findings blur the clinical boundaries between ASD and schizophrenia, ADHD, intellectual disability, and epilepsy, which suggests that common phenotypes are different, though overlapping, forms of developmental brain dysfunction that share common disease mechanisms [53, 54•]. Analysis of transcriptomes of postmortem ASD brain confirms convergent molecular pathology and suggests that dysregulation of transcription and splicing may lead to neuronal and synaptic dysfunction in ASD [55].
Clinical genetics in the evaluation of ASD requires a tiered approach that should be tailored to the individual patient and family [56]. After the diagnosis of ASD, initial medical evaluation should be followed by a careful 3-generation family history. If a syndromic diagnosis is suspected, specific testing may be done (e.g., fragile X, Rett) [57]. A chromosomal microarray for de novo copy number variations (CNVs) will be appropriate for most patients, as well as fragile X testing for male patients. Metabolic testing may be indicated by developmental regression associated with illness or fever, cyclic vomiting, gastrointestinal dysfunction, microcephaly, and seizures. A second tier of evaluation may include whole exome or genome sequencing, MRI, and MR spectroscopy. At each step, genetic counseling is indicated, whether or not a genetic etiology is identified [53]. Given continued experience with common and rare genetic variants, along with delineation of phenotypic data, new genetic causes of ASD are accumulating at an increasing rate [58••, 59]. It is therefore important to periodically update genetic evaluation and testing for patients for whom the etiology of ASD remains unknown.
New treatments in ASD
Current conventional treatment
Current conventional treatment of ASD in children includes intensive behavioral interventions (known as applied behavioral analysis or ABA), rehabilitative services such as speech therapy, occupational therapy, physical therapy, social skills training, and counseling. Please refer to the flow chart (Fig. 1) for recommended treatments by age. Below, we do not review new behavioral or developmental approaches, but rather non-behavioral interventions.
Traditional pharmaceuticals are commonly used to treat autistic symptoms, but do not affect the core symptoms of ASD [60••]. Despite their limitations and narrow range of effects, a number of agents can alleviate features of ASD, in different degrees and with side effects that vary among individual patients. The selection of agents requires careful consideration of individual symptoms and needs, with regular follow-up and monitoring for efficacy and side effects.
Most agents are used off-label; two atypical antipsychotic medications (risperidone and aripiprazole) are currently the only FDA-approved medications for the treatment of aggression and irritability in ASD [61]. Both are dopamine D2 and serotonin 2A receptor antagonists, and their efficacy has been confirmed in clinical trials. Side effects include sedation, increased appetite and weight gain, and potential for extrapyramidal symptoms and paradoxical restlessness, among others. Other “atypicals” include quetiapine, ziprasidone, and olanzapine. Despite their side effects, they are preferable to the sedation and risk of extrapyramidal syndrome associated with the “typical” agents, including chlorpromazine and haloperidol.
Methylphenidate and other stimulant medications are dopamine reuptake inhibitors that are usually effective for treatment of ADHD. In patients with autism, they may also be effective for symptoms of ADHD but may induce irritability, even if they improve attention and reduce hyperactivity [62•]. Guanfacine and clonidine are α2-adrenergic receptor agonists that provide alternative treatments for symptoms of ADHD, and clonidine is useful for sleep onset, though not maintenance [63]. Atomoxetine, a norepinephrine reuptake inhibitor, has demonstrated efficacy for ADHD symptoms in children with ASD, and its effects may be enhanced by parent training [64•].
Selective serotonin reuptake inhibitors (SSRIs; fluoxetine, citalopram) have not shown consistent benefits for improving repetitive behaviors in children and adolescents 5–17 years of age [65, 66]. A recent trial of buspirone (a 5HT1A partial agonist) in young children (2 to 6 years) with ASD demonstrated improvements in restricted and repetitive behaviors, consistent with the known trophic effects of serotonin in early brain development [67•]. Caution is advised because irritability, hyperactivity, and insomnia may result from stimulating serotonin in young children, and SSRIs can exacerbate mania in individuals with latent bipolar disorder (a frequent feature in the family histories of patients with ASD).
For sleep, a common problem in ASD, melatonin, and α-agonists (e.g., clonidine) have been helpful for inducing sleep onset. The benefits of melatonin reflect atypical metabolism and low production of the hormone in ASD [68]. However, its short half life means that it often does not maintain sleep and may be combined with, or replaced by, a controlled release form of melatonin [69]. Other agents used for sleep (e.g., iron supplements, antihistamines, atypical antipsychotics, antidepressants, benzodiazepines, gabapentin, and anticonvulsants) have variable responses and side effects and have not been well studied in ASD [70•].
Gastrointestinal problems occur commonly in ASD and are evaluated following general pediatric guidelines [71]. Treatments for gastroesophageal reflux disease, chronic abdominal pain, constipation and diarrhea may ameliorate concurrent abnormal sleep and behavior. Differences in the microbiome in ASD compared to typically developing children raise the possibility that current research may lead to fecal transplants as well as new probiotics and medications [72•]. .
Mitochondrial dysfunction and oxidative stress are likely to occur in 20% or more of children with ASD and may be treatable but difficult to diagnose [73•]. Various deficits in electron transport or Krebs cycle intermediates during development may prevent optimal immune and metabolic responses under stress and may become less evident as development proceeds. Screening for mitochondrial functions may lead to trials of antioxidants or cofactors (e.g., coenzyme Q10, carnitine, vitamin B1), even though their efficacy has not been established in systematic studies [74].
Novel compounds
Novel compounds (Table 2) for treatment of ASD are so designated because they have credible postulated mechanisms of action in ASD, but are not advocated by many practitioners because their safety or efficacy is based on limited evidence. For each compound listed, a reliable reference discusses the rationale for its use, safety, and suggested dosing regimen. The reader is encouraged to review the references cited as well as others from reliable sources in considering recommendations for treatment. Note that although many of these agents appear to be innocuous, they are largely untested and may have unforeseen interactions with other medications. Pending further research and clinical experience, the reader is cautioned that apparently benign “supplements” can act as “drugs,” even if they are not so classified. The following compounds are grouped according to their effects on neurotransmitter systems, as neurohormones, folate-dependent one-carbon metabolism, antioxidants and anti-inflammatories, and food-derived compounds that affect cellular metabolism.
Compounds that facilitate GABA activity take advantage of its deficiency in ASD. Failure of the normal conversion of GABA from being excitatory to inhibitory early in development in ASD may account for an imbalance between inhibition and excitation and the frequently paradoxical effects of GABAergic compounds (e.g. benzodiazepines). Arbaclofen, a modified form of baclofen, is a GABA(B) receptor agonist that has shown promise for improved social behavior but overall negative early clinical trial results [75]. Bumetanide, a loop diuretic, chloride importer antagonist, and antihypertensive, increases GABA inhibition by reducing intracellular chloride in cortical neurons. Clinical trials of bumetanide have demonstrated relative safety and efficacy in ASD in global ratings as well as facial and emotional processing [49•]. Based on decreased GABA activity and therefore increased ratio of excitatory to inhibitory activity in ASD, memantine, a glutamate receptor antagonist used for treatment of Alzheimer disease, was reported to show improved social interaction and communication in open-label trials, but no benefits in a large placebo-controlled trial [76].
Acetylcholine receptors, both muscarinic and nicotinic, are decreased, especially in the basal forebrain and cortex in ASD, which have provided the rationale for trials of acetylcholinesterase inhibitors. Seven trials of Donepizil have shown improvements in behavior and REM sleep in some, but not others, with mostly mild side effects [77]. Galantamine was effective in several trials and when used with risperidone, in reducing irritability and social withdrawal, and was well tolerated [78]. Rivastigmine improved expressive speech and autistic behaviors in a single open-label study [79].
Adrenergic receptors, both β1 and β2, are nonselectively antagonized by propranolol, which readily crosses the blood–brain barrier. Single doses of propranolol have led to improved conversational reciprocity in a study in young adults with ASD, possibly acting as an anxiolytic and improving nonverbal communication [80•]. Side effects from its repeated or long term use (e.g., fatigue, depression, autonomic changes) may limit its usefulness.
Serotonergic compounds may have different effects in early, compared to later, brain development. As noted above, a recent trial of buspirone was effective in 2 to 6-year-old children with ASD [67•]. In children and adolescents with ASD, buspirone at low doses was superior to placebo when given with risperidone for treating irritability [81].
The neuropeptide oxytocin generates great interest due to its involvement in social cognition and eye gaze, both of which have improved in clinical trials and neuroimaging studies in ASD [82•]. However, its short duration of action (usually by intranasal administration) and uncertain effects of long-term use require larger and more extensive clinical trials. Recent evidence for important interaction between oxytocin and serotonin signaling may lead to simultaneous treatment of both systems [83]. Insulin-like growth factor-1 (IGF-1) is a commercially available polypeptide hormone with important roles during brain development and in synaptic connectivity. Positive effects in preclinical models of ASD and early results of a clinical trial in Phelan-McDermid syndrome (a genetically defined form of ASD) suggest that it may be beneficial for social impairment and repetitive behaviors [84].
We now recognize that folate-dependent one-carbon metabolism is central to several critical and interwoven pathways in which individuals with ASD differ from controls with respect to their cellular folate, methylation, glutathione, and tetrahydrobiopterin metabolism [85]. Genetic polymorphisms within these pathways, antibodies to folate receptors, nutritional deficiency, certain toxins, and environmental factors may lead to different effects on oxidation-reduction (redox) balance that damage cellular DNA, protein, and lipids through oxidative stress. Folinic acid, a reduced form of folic acid, crosses the blood–brain barrier and can treat symptoms of ASD in cerebral folate deficiency, as well as ASD with folate-receptor antibodies [86]. In a recent clinical trial, high-dose folinic acid improved verbal communication in children with ASD [87••]. Vitamin B12 (Methyl B12), an important cofactor for methylation, improved clinician-rated symptoms of ASD as well as biochemical measures of methylation capacity [88].
Tetrahydrobiopterin (BH4) is essential for the production of monoamine neurotransmitters and nitric oxide, which are affected in ASD, and low levels have been reported in the CNS. Treatment with BH4 may reduce core symptoms of ASD [89].
N-Acetylcysteine (NAC), an antioxidant and glutamate modulator, is in use as a mucolytic and to treat acetaminophen overdose. NAC increases intracellular glutathione by providing its cysteine precursor, and several neuropsychiatric disorders, including ASD, have responded to NAC in clinical trials [90]. There is evidence for its safety, as well as efficacy, for irritabilty in ASD; however, a recent study found no effects on social impairment [91].
Nutraceuticals (plant-derived compounds) hold promise as treatments for ASD, for both their safety and efficacy, although some research studies have been limited by small sample sizes and study designs [92]. Curcumin is a phenol derivative of turmeric (Asian spice and medicinal herb). It has anti-inflammatory and antioxidant properties and inhibits activation of microglia in vitro but has poor oral bioavailability [93]. Curcumin was effective orally, using both behavioral and biochemical measures, in a propanoic acid rodent model of ASD [94]. Despite its potential, curcumin has not been approved for therapeutic use in humans; clinical trials are needed to assess its safety and efficacy. Luteolin, a flavonoid plant pigment, is a multifunctional antioxidant and anti-inflammatory that inhibits mast cell degranulation and microglial activation. Combined with quercetin (another flavonoid), luteolin improved adaptive functioning and ASD symptoms in an open-label trial [95•]. Sulforaphane, an isothiocyanate derived from broccoli, has been studied widely in cancer and recently showed efficacy in improving sociability and aberrant behaviors in a placebo-controlled trial in young men with ASD [96•]. The rationale for its use in ASD is based on its effects on several cellular processes, such as redox metabolism, mitochondrial function, immune dysregulation, and synaptic function [97]. A similar clinical trial of sulforaphane is currently underway in children with ASD (NCT02561481).
No matter how safe some of these novel, as well as the traditional, compounds for the treatment of ASD may appear, most are not FDA-approved and any of them may have as yet unforeseen side effects or interactions with dietary factors, other essential medications, or environmental factors that cannot be predicted from the limited research and experience available. Only the continuing efforts of the families, researchers, and autism support organizations will provide the information necessary to assure their safety and efficacy for persons with ASD.
In conclusion, these assessments and treatments offer a new and expanded array of possible approaches to ASD. The lists are not exhaustive and do not include complementary and alternative medical assessments, assays and treatments, and diets [98•]. Not included is the emerging research on immunology, microbiome, metabolomics, and metabolic testing, as well as the assessment of ASD in adults. However, we have attempted to include new validated information and provide clinical guidance for the evaluation and treatment of young children and youth with ASD.
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Acknowledgments
We wish to acknowledge the capable editorial assistance of Kanwaljit Singh, MD, MPH, UMass Department of Pediatrics.
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Roula N. Choueiri reports that she is the principal author on a paper referenced in the review (A New Interactive Autism Screening test in Toddlers). It is a test she is currently developing; however, she receives no royalties and there are no financial benefits from it. It is copyrighted to Tufts Medical Center and University of Massachusetts Medical School both hold intellectual property. Andrew W. Zimmerman reports that he has a patent on the use of sulforaphane for treatment of autism spectrum disorder issued to Johns Hopkins University and is a co-author on reference #96 (Singh K et al., PNAS 2014), a clinical trial of sulforaphane in treatment of ASD.
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Choueiri, R.N., Zimmerman, A.W. New Assessments and Treatments in ASD. Curr Treat Options Neurol 19, 6 (2017). https://doi.org/10.1007/s11940-017-0443-8
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DOI: https://doi.org/10.1007/s11940-017-0443-8