Ginkgo biloba for ADHD: A natural herbal treatment alternative?

A few weeks ago, I discussed the merits of ginseng for treating ADHD. What I did not mention is the fact that this special herb often works even better in tandem with another important "brain herb", Ginkgo biloba. It's benefits also extend beyond the nervous system, and the Ginkgo has been used to treat everything from increasing blood flow to Alzheimer's to glaucoma to hormone replacement to protection against neuronal degradation. While somewhat wary (personally) of using generalized "brain booster" nutrients for ADHD (it is a highly variable disorder of complex etiology and treatment methods), I am interested whenever new research publications arise on the topic. Just this week, a new paper came out on the merits of Ginkgo biloba as an ADHD treatment option.

Here are some of the major points of the publication:

• Irritability is an often overlooked side effect of ADHD. Medications, especially over-prescription with stimulants such as methylphenidate and amphetamines can increase this unwanted side effect. However, Ginkgo exhibited a positive mollifying effect on irritability for the individuals in the study.
  
  
• While one of the knocks against Ginkgo biloba is that it can sometimes result in sedative effects, the study found these to be extremely mild. However, to go along with the irritability-reducing benefits above, Ginkgo was able to improve the individuals' tolerance for frustration (to the degree that this behavior could be measured).
  
  
• We have seen previously that oppositional defiant behaviors are often comorbid to ADHD (which can often manifest themselves alongside seemingly unrelated disorders such as auditory processing disorders or even bedwetting). One of the strongest suits of Ginkgo biloba may actually be in curbing these oppositional behaviors. This suggests that Ginkgo may be effective for the more Hyperactive/Impulsive or Combined Subtypes of ADHD, where comorbid oppositional behaviors are more often seen (as opposed to the predominantly inattentive subtype of the Disorder).
  
  
• Nevertheless, Ginkgo biloba appeared to boost symptoms of attention and working memory as well. This may suggest Ginkgo's versatility, and that it could be used universally across the ADHD "spectrum", including for the 3 classic or traditional subtypes of the disorder.
  
  
• The study highlights the relative success for co-treatment with methylphenidate and clonidine for individuals with ADHD and comorbid anxiety disorders. The authors suggest a functional comparison between Ginkgo and clonidine, and hint at its use as an alternative to clonidine/methylphenidate treatment (of course, it is also possible that Ginkgo may be used alongside lower doses of stimulant medications, which could be very useful in reducing unwanted side effects, which are often mild for low doses of stimulants, but typically begin to appear with greater frequency when stimulant dosing is increased). Thus, Ginkgo could possibly act as a side-effect-saving alternative to higher doses of medication.
  
  
• As a precautionary measure, due, in part to some of its anti-clotting properties, there is some concern about Ginkgo triggering internal cerebral bleeding. Indeed, other studies have also addressed this possible concern, highlighting issues such as haemmorrhage risks, as well as herb-drug interactions with Ginkgo and anti-coagulant medications.
  
  
• Keep in mind the extremely small nature of the study (only 6 individuals) should be met with healthy skepticism. However, the results were still notable. Statistically significant reductions in some of the trademark ADHD symptoms (fidgeting, restlessness, inattention, etc.) upon Ginkgo biloba treatment definitely highlight its potential as a more "natural" alternative treatment method for ADHD.
  

Why the Menstrual Cycle may affect ADHD Medication Dosing Levels

Do hormonal fluctuations result in variable ADHD medication dosage levels across the menstrual cycle?

We have investigated the impact of gender on ADHD in a number of earlier posts. We have covered topics such as:

• Gender Based Metabolic Differences in ADHD brains

• Gender Dependent ADHD Genes, including MAOA, SLC6A2, SLC6A4 and COMT

• ADHD subtypes and Comorbid Disorders

Clearly, there are a number of boy/girl differences in the root causes, diagnoses and treatment methods for the disorder.

However, we need to investigate whether intra-individual differences are also an important factor, especially where medication treatment and medication dosing levels are concerned. Based on a number of studies, it appears that women may actually require different medication dosing levels depending on where they are in their menstrual cycle. Additionally, post-menopausal drugs such as estradiol patches may also alter the drug effects of certain ADHD medications such as amphetamines. The main culprits are most likely fluctuating levels of estrogen and progesterone.

Here are brief summaries on some of the relevant studies and their findings. Wherever possible, I will include a link to the original studies:

• The link between Estradiol treatment and amphetamine medications: This study focused on whether pretreatment with estradiol played any role in the reaction to amphetamines. The drug used in this study was D-Amphetamine, which would correspond to the medication Dexedrine, however, this is also the predominantly active compound in medications such as Adderall or Vyvanse (once this "pro-drug" is metabolized). It is unclear at the moment whether chemical "cousins" to amphetamines, such as methylphenidate (Ritalin, Concerta, Daytrana, Metadate), also exhibit these fluctuations when combined with estradiol-releasing drugs.
  
  The study found that for females who took estradiol-supplementing treatments during the early follicular phase (pre-ovulation) of the menstrual cycle experienced an overall greater "stimulating" effect of the amphetamine medication (taken as 10 mg of amphetamine). This may suggest that a slightly lower dosage during this stage of the menstrual cycle might be warranted, and (as this blogger's personal hypothesis) may actually affect the addiction potential of ADHD stimulant drugs such as amphetamines.
  
  
• Another study by the same group found that estrogen may be responsible for some of the heightened euphoric effect felt from amphetamine-based drugs. However, the hormone progesterone may actually counteract some of this euphoria. During the luteal phase of the menstrual cycle (after ovulation), high levels of both estrogen and progesterone are seen (although levels of both of these taper off going into menstruation), so the effects of estrogen may be curbed. During the late follicular phase, where progesterone levels are low and estrogen levels begin to spike, the "high" may be at its peak, especially if stimulants are involved.
  
  
• A case study found that an increase in inattentive symptoms coincided cyclically with the menstrual cycle for a patient who was undergoing treatment for newly-diagnosed ADHD with a twice-daily dosing regimen of the stimulant medication Concerta.
  
  
• The findings from these two studies suggest the possibility that a slightly smaller dosing schedule with amphetamine-based ADHD medications (such as Adderall, Vyvanse or Dexedrine) may be warranted during the follicular phase. However, during the luteal phase, when progesterone levels are higher, the amphetamine-based effects are less pronounced. This may correlate to a slightly higher dosing regimen for amphetamine-based treatment for ADHD and related disorders.
  
  
• While there is a relatively good theoretical basis for this assertion above, practical consideration measures must also be considered. Based on the relative scarcity of studies (besides the 2 mentioned above) on the amphetamine-menstrual cycle interactions, it is unclear as to how pronounced the medication change should be.
  
  For instance, should someone taking 10 mg of Adderall during the follicular phase boost up to 15 mg for the luteal phase? 20 mg? 30 mg? Additionally, hormonal fluctuations vary during the phases themselves, such as the estrogen spike during the late follicular phase. Questions abound, especially when dealing with the brief ovulatory phase as well.
  
  

This blog post hopefully introduces what may be a new consideration to women who have ADHD and are currently taking stimulant-based medication treatments. Perhaps this posting simply confirms what you have already experienced.

Nevertheless, given the fact that administering variable levels of medication based on cyclical patterns such as time of day (like ramping up methylphenidate concentrations via controlled release formulations to offset "acute tolerance" based effects), and the fact that individuals with ADHD may experience seasonal variations in symptoms, at least suggests, that variable dosing of medications across the near-monthly period of the menstrual cycle may prove to be beneficial treatment strategy for females with ADHD.

Long Wave Infrared Imaging: A new detection method for ADHD?

Detecting ADHD using the long-wave infrared spectrum:

I always enjoy covering new breakthroughs in the diagnosis and treatment methods in the medical field. A new study just came out which may have a number of potential applications to aid in the diagnostic process of ADHD, which I believe is worth sharing. Called Long-Wave Infrared Imaging, this method utilizes the infrared spectrum to detect biological activity (namely bloodflow patterns) via the differences in radiation emitted by these activities. The study, titled Sensitivity and Specificity of Longwave Infrared Imaging for Attention-Deficit/Hyperactivity Disorder, found that this method may be a surprisingly powerful way of separating ADHD from other related disorders, aiding in the always-difficult process of differential diagnosis.

The basics of Long-Wave Infrared Imaging:

The term "long-wave" is a relative term, of course, referring to wavelengths of approximately 10 nanometers (or only one one-hundred millionth of a meter). Differential bloodflow patterns can result in temperature differences by a full degree (Celsius), making this technology useful in tracking bloodflow disorders. A recent publication in the Journal of Medical Physics by Bagathaviappan and coworkers suggests describes how this long-wave infrared imaging can detect areas in the circulatory system where bloodflow activity is sluggish or reduced. Typically, these areas appear "cooler" on the spectrum, due to the lack of a new, replenishing blood supply.

Applications for ADHD:

A number of studies have confirmed the hypothesis that individuals with ADHD have reduced bloodflow levels marking a recuction of activity to multiple key brain regions. Additionally, while several disorders have a number of overlapping symptoms (which can make the diagnostic process more complicated, especially if multiple comorbid disorders are present), differential blood flow patterns to the brain may be able to help make these distinctions. For example, blood flow patters to the brains of ADHD and OCD (Obsessive Compulsive Disorders) can show pronounced differences, which can aid the diagnostic process between these two disorders (while ADHD and OCD are often considered to be on "opposite" ends of the spectrum with regards to neuro-chemical signaling levels, these two disorders can often exhibit similar symptoms, such as a severe impairment in the response to verbal directions. This is especially true in younger children).

This technology may even be extended to measuring or predicting which medications may work for an individual diagnosed with ADHD, based on blood flow in specific localized brain regions. Cerebral blood flow patterns may help predict the response to common ADHD drugs such as methylphenidate (Ritalin, Concerta, Metadate, Daytrana). For example, a study by Cho and coworkers found increased blood flow in at least three different brain regions for individuals who showed poor response to methylphenidate treatment compared to their peers who did show improvements under the drug.

While the medication response study was done utilizing a different type of brain imaging device known as SPECT, which utilizes gamma rays and radioactive tracers to detect brain activity in 3-dimensional patterns. While SPECT has proven to be an extremely powerful and effectively safe method of detection (the radioactive isotope used in this method is relatively non-invasive and breaks down quickly, and the gamma rays are carefully controlled), concerned parents may still have an inherent fear of the terms "radioactivity" and "gamma rays" tend to shy away from this powerful detection method on their kids.

While this blogger personally has a very high opinion about the use of SPECT as a diagnostic tool for ADHD and related disorders, it is at least worth mentioning the possibility that long-wave infrared imaging methods may be a viable alternative method in at least some of these imaging cases (SPECT technology has been around for over 30 years, but the recent advances in computational power resurrected this technology in the very recent past, similar possibilities may abound by this infrared technology, which has been around even longer).

Keep in mind that the studies utilizing this range of infrared imaging technologies for detecting and differentiation disorders such as ADHD are still relatively scarce. Nevertheless, long-wave infrared imaging appears (at least in this blogger's personal opinion) to be a powerful diagnostic tool for ADHD and related disorders in the near future.

ADHD and Seasonal Affective Disorder

ADHD and Seasonal Affective Disorder (SAD): Are they Linked?

Is it possible that ADHD is a seasonally fluctuating disorder? It sounds intriguing, but remember, for diagnostic purposes, classic ADHD symptoms such as hyperactivity, impulsiveness and inattentive behaviors (beyond the normal range of age-appropriate behavior) must persist for a set period of time (the typical cutoff is 6 months for most cases). Nevertheless, it is worth investigating whether there is any sort of seasonal pattern to the disorder. If there is, there could be far-reaching implications such as medication dosages (if diagnosed or initially treated during a "high ADHD symptom" period may result in effects of over-medication for the rest of the year, while initial dosing during a "low-tide" season of ADHD symptoms may prove inadequate in the later months).

Intuitively, we would probably assume that ADHD symptoms would be worst during the dark winter months, but is there any data to support this hypothesis? As it turns out, there may be. Here are the results of a few relevant studies on the apparent connection between ADHD and seasonal related psychological disorders:

• Seasonal Affective Disorder (SAD) symptoms overlap and co-exist at higher rates in those with ADHD: A study by Levitan and coworkers on seasonal affective symptoms in adults with ADHD found that the prevalence of seasonal affective disorders was higher in the ADHD population than in the general population. This study accounted for some of the obvious factors such as geography (someone in Seattle would be more prone to seasonal related disorders than, say, someone in San Diego).
  
  Perhaps not surprisingly, the rate of appearance of seasonal affective symptoms was higher in women with ADHD (in general, depressive-like disorders such as SAD are more common in women in general). However, other interesting comparisons were seen, such as the prevalence of seasonal affective symptoms in the inattentive subtype of ADHD (as opposed to the hyperactive/impulsive or "combined" subtypes of the disorder). While this subtype connection may be interesting, it is important to remember that comorbid depression is often seen more in the inattentive-dominant forms of ADHD than the hyperactive-impulsive forms of the disorder.
  
  
• Overlap in medication treatments for ADHD and SAD: While we should be careful not to simply lump a bunch of disorders together just because they share similar treatment methods, the relationship between SAD, ADHD and medications such as buproprion (Wellbutrin) may be worth noting. Bupropion has shown to be clinically effective in the treatment of a whole spectrum of disorders including seasonal affective disorders.
  
  Additionally, this medication has shown its far-ranging capabilities, due, in part to its success as both an anti-depressant and "pseudo-stimulant" (of course there is a heated debate among professionals as far as whether "Wellbutrin" should even be mentioned in the same sentence as "stimulant", but its unusual, and relatively unknown mode of action keep it from an exclusive anti-depressant label, at least in the classical sense).
  
  The reason I personally use the term "pseudo-stimulant" is that bupropion can function as a dopamine reuptake inhibitor (which is one of the major modes of action of several ADHD stimulant medications and is typically uncharacteristic of most anti-depressants which often predominantly target the brain chemical serotonin). This may be evidenced by bupropion's relative effectiveness in treating ADHD (please note that bupropion or Wellbutrin is still extensively used in ADHD treatment in place of a stimulant if there is some type of depressive related disorder, however, findings such as the one in this previous study seem to indicated that buproprion may be effective for treating free-standing ADHD without comorbid depression).
  
  While again, I should reiterate that similar treatment methods does not necessarily equate to similar disorders or conditions, the relative effectiveness of this medication for treating both disorders at least leaves the door open for the possibility that there exist similar underlying modes of action between ADHD and SAD.
  
  
• The connection between ADHD and circadian rhythms: While SAD, by definition is a seasonal (as opposed to daily) issue of cyclical patterns of time, it is worth mentioning that new research is being done with regards to differences in the chronological patterns in the bodies of individuals with ADHD. In other words, there may be an actual scientific explanation behind the reasons why your ADHD child likes to stay up until three in the morning on a consistent basis.
  
  There also appears to be an affiliation with daily rhythms and ADHD subtype. For example, while impulsivity is often more associated as a "morning" behavior, the inattentive subcomponent of ADHD appears to be more affiliated with the evening. This may factor into the differences in sleep patterns and prevalence of sleep disorders in ADHD children, and may even highlight the daily schedule differences between the ADHD subtypes.
  
  If the hypothesis that individuals with ADHD are at least partially predisposed to different patterns of circadian rhythms compared to the general population, it may stand to reason that these same individuals may also be more susceptible to seasonal fluctuations. Some studies confirm this possible "double" association of ADHD to both seasonal fluctuations and circadian rhythms.
  
  
• Overlapping treatment strategy of Light Therapy for ADHD and SAD?: There has been a recent surge of evidence that light therapy, when administered at the correct wavelengths, is an effective treatment for seasonal affective disorder (and often with measurable levels of success), may now be useful for treatment in the ADHD population.
  
  As an interesting aside, there may be some unusual side effects of ADHD stimulant medications with regards to light therapy. A case study of a single child noted that there may be a possible connection between methylphenidate and photophobia (photophobia referring to fear of or excessive sensitivity to the light). Of course this observation was limited to just one patient, but the correlation of the symptoms with methylphenidate treatment at least suggests the possibility that this is a possible (albeit) rare side effect of one of the most popular stimulant medications for ADHD currently on the market.
  
  Blogger's side note: it is also worth mentioning that this case report was also published by the same individual who brought us the interesting case study which became the topic of an earlier post in this blog: excessive talking as a potential side effect of methylphenidate treatment. I will refrain from making any comments or conclusions about this, but on a personal note, I actually enjoy reading about some of these unique side effect case studies of the popular drug, and wonder if this will result in an increased level of vigilance with regards to monitoring odd side effects of common ADHD stimulant medications in both clinical studies and individual prescriptions.
  
  
• Omega 3 (n-3) fatty acid deficiency: A common underlying factor for both ADHD and seasonal affective disorders? I saved what is perhaps the best explanation for last. It consistently has been shown that individuals with ADHD are often deficient in omega-3 fatty acids. We have even discussed the theory behind omega-3 fatty acid supplementation for ADHD in earlier bloggings. Now it appears that omega-3 deficiencies may disrupt circadian rhythms as well, possibly due to an impairment in melatonin production (melatonin is a hormone which is tightly associated with the sleep-wake cycle and hence has implications on the circadian rhythm patterns in a particular individual).
  
  This may suggest that omega-3 fatty acid deficiencies may either help cause, or exacerbate the severity of both ADHD and circadian rhythm impairments. Interestingly, there is some evidence that omega-3 supplementation may be beneficial in treating seasonal affective disorders as well. In fact, diets rich in omega-3's may be an underlying reason why seasonal affective disorders are relatively uncommon in Iceland, which, due to its far-northern location, experiences exceptionally long, dark winters.
  

While I admit that the evidence for the link between ADHD and Seasonal Affective Disorders is nowhere near as strong as for other ADHD comorbid issues (such as Tourette's, anxiety, conduct disorders, and learning disabilities), I still wanted to pass on some of the information out there supporting a possible link between the two disorders. Given the close associations both between depression and seasonal affective disorders, including the argument that SAD should be labeled as a specific subtype of depression, and the high rate of comorbidity between ADHD and depressive disorders, there is certainly a possibility that the magnitude of overlap between ADHD and SAD is greater than we might imagine.

Methylphenidate, Anxiety and ADHD: How do they fit together?

Effects of Comorbid Anxiety on Methylphenidate Treatment in the ADHD Child:

Medication with stimulants such as methylphenidate has consistently proven to be a popular and relatively effective mode of treatment for the ADHD child. However, questions arise regarding its side effects. In particular, the effectiveness of methylphenidate (Ritalin, Concerta, Daytrana, Metadate) can be jeopardized if the child with ADHD also has some type of comorbid disorder (such as depression, obsessive compulsive behaviors, Tourette's and a host of other common associate disorders) which may be negatively impacted by the ADHD treatment. Anxiety-related disorders are seen in up to 35% of ADHD individuals, according to some studies.

Typically, treatment is met with some type of adjunctive medication to treat the comorbid disorder (which can be quite tricky, as it introduces the problem of potential drug-drug interactions, as well as a possible impairment in the effectiveness of the ADHD treatment medication), a non-stimulant method of treatment such as Strattera (atomoxetine), or non-drug alternatives (behavior therapy, EEG, nutrition and dietary strategies, etc.). While isolated behavioral therapy has limitations for treating ADHD (especially in cases of "refractory" ADHD), it has proven to be a beneficial mode of treatment for childhood anxiety disorders.

In the case of anxiety disorders alongside ADHD, treatment with stimulant medications such as methylphenidate can also be tricky. However, recent findings seem to indicate that methylphenidate is a safe mode of treatment for ADHD with comorbid anxiety. However, a new publication notes that there may be a significant distinction between the effects of anxiety on methylphenidate's effectiveness from a behavioral standpoint vs. a cognitive standpoint. Let me explain further.

When attempting to determine whether a child should be diagnosed and treated as having ADHD, the supervising physician often gives out rating forms to both parents and teachers of the child in question. Numerical rating scales with regards to classic ADHD symptoms (i.e. impulsivity, hyperactivity, inattentiveness, etc.) comprise the majority of the rating forms, and these results are tabulated and typically used in the diagnostic process. Additionally, these rating forms are often administered after a specific period of time following treatment (with medication, nutritional therapies, counseling or ADHD coaching programs, etc.) to assess the effectiveness of these treatments.

While the level of agreement between parent and teacher rating forms is generally high, significant differences may often be seen. In other words, how a child's perceived behavior in the home may be notably different than his or her behavior in the classroom. While there are an array of possible factors and explanations for this, the presence of comorbid anxiety may be an important but often overlooked reason for this discrepancy.

In the study titled: Predicting Response of ADHD Symptoms to Methylphenidate Treatment Based on Comorbid Anxiety, the researchers found that the behavioral improvements in children with ADHD were similar regardless of whether the child also had an accompanying anxiety disorder. In other words, a notable decrease in symptoms of hyperactivity, impulsiveness and behavioral annoyances was frequently seen. Since these symptoms are often more of the obvious tell-tale signs of the disorder, it would be easy to conclude (especially from a parent's standpoint) that all is well again.

However, on the opposite side of the coin, the side dealing with the cognitive deficits of ADHD (which, not surprisingly have immense academic implications), may tell a different story. The study found that for the ADHD children without an accompanying anxiety disorder, methylphenidate treatment often contributed to vast improvements in their cognitive function (and subsequent academic achievement potential). However, if the ADHD child did have an accompanying anxiety disorder, the methylphenidate treatment was significantly less effective (and possibly even counter-effective). This may serve as a possible explanation for at least some of the variability between parent and teacher evaluations of the same ADHD child.

This leads to the question: does comorbid anxiety affect the cognitive ability-enhancing effects in all academic areas or just in some of the sub-fields of academic-related cognitive functioning?

The study investigated this by administering a Weschler Intelligence Test (WISC III) to the children and examined the effects of comorbid anxiety and methylphenidate medication on three subcomponents of the test: Coding, Arithmetic and Symbol Search. An explanation of the results in these three subcategories with regards to what they measure, possible implications of these subcategories, and the effects of anxiety and methylphenidate treatment are summarized below:

• Arithmetic: This is a timed test in which arithmetic questions are orally presented to the children and the responses are measured, assessing both speed and accuracy. Methylphenidate treatment produced a slight improvement in the ADHD children without comorbid anxiety. However, for the children with comorbid anxiety, the use of methylphenidate was ineffective (in fact, a slight decrease in performance was seen, but this was exceedingly small. It should be concluded that methylphenidate treatment had no reasonable positive effect for the ADHD children with comorbid anxiety for this particular subcategory).
  
  This should lead to an array of questions, including ones such as "does anxiety hamper one's performance in math, if one is ADHD (or even if one is not ADHD)?". Intuitively, we would expect the answer to be "yes", as evidenced by the huge number of children (and adults) who have self-reported "mathphobia". However, some well-reputed studies seem to indicate that methylphenidate treatment can actually help with mathematical abilities. Is there something else going on here?
  
  One potential explanation (not mentioned in the study) may reside in the possible presence of a third comorbid factor, such as an underlying comorbid auditory processing disorder. Auditory processing disorders are relatively common in individuals with ADHD, however, since the two disorders often exhibit symptomal overlap, comorbid auditory processing disorders are often missed in ADHD children.
  
  Interestingly, some recent evidence has come out that there may be a connection between auditory processing issues and anxiety disorders. This possible link between anxiety and auditory processing disorders has been addressed previously in another section of this blog. Note that the arithmetic subsection is administered orally in the WISC III test.
  
  If the theory that auditory processing difficulties are seen alongside anxiety disorders, it is entirely possible that the discrepancies in the ADHD with comorbid anxiety performances me be largely due to the nature of how the arithmetic portion of the test is administered. It would be interesting to see if any improvements were seen in the arithmetic scores were improved in the anxiety subgroup if the questions were presented in a written, non-auditory format.

• Coding: This section of the WISC III test measures skills involving visual-spatial coordination, speed and concentration. The individual (for those over 8 years old) is instructed to copy a line of code substituting a number for a symbol (this would involve something along the lines of writing, say, a "1" where a star is presented, "2" for a "circle", "3" for a smiley face, etc.). A high performance in this section has implications for advanced academic tasks that involve utilizing tables and formulas (think of solving chemistry problems using data from a periodic table at the top of the page, etc.).
  
  In addition, a strong visual-spatial aptitude may have implications for things such as note taking skills and the like. As a result, a strength in this area may be particularly useful in upper-level courses involving the sciences, foreign languages and anything that requires an individual to "decode" and translate new information quickly. With regards to the anxiety vs. non-anxiety ADHD groups, both showed some degree of improvement with methylphenidate treatment for this subsection.
  
  However, the non-anxiety group showed a significantly greater positive response (around twice as big of an increase in scores for this subsection following methylphenidate treatment as the comorbid anxiety group) to the methylphenidate treatment, suggesting that comorbid anxiety was a relative impediment to methylphenidate-mediated improvements in this area as well.

• Symbol search: This subsection involves picking out or identifying whether a particular symbol is present in a row of symbols. It has direct implications on one's ability to pay attention to detail as well as the ability to quickly scan through information to find what is relevant. Both the anxiety and non-anxiety groups showed slight improvements following methylphenidate treatment, however, once again, the improvements in post-methylphenidate scores were about twice as large for the non-anxiety group of ADHD children.

Of the 3 subtests, methylphenidate treatment helped the most in the coding section, had minimal effects in the symbol search section and little (for the non-anxiety group) to no or negative (for the anxiety group) effects for the arithmetic section.

Other studies have also investigated the effects of comorbid anxiety on cognitive task performance in ADHD children. By and large, it appears that memory-based tasks are the hardest hit by an accompanying anxiety disorder when methylphenidate is administered as an ADHD treatment. Other studies have confirmed this finding on anxiety disorders impeding memory enhancement via methylphenidate treatment. This seems to agree with the data on the coding section, which involves a type of working memory for the symbol deciphering process.

Based on what we have covered here, it would be reasonable to scrutinize significant differences between parent and teacher ratings and behavioral and attentive improvements for the possibility of an accompanying anxiety disorder to go along with an ADHD diagnosis in a child. While anti-anxiety medications can be useful, and co-administered with ADHD stimulant drugs under the watchful eye of a carefully trained physician, there is also evidence that

These findings suggest that comorbid anxiety can be a serious handicap to achieving cognitive and academic-related improvements in response to stimulants such as methylphenidate. However, please note that, based on the main study of our discussion on ADHD, anxiety and methylphenidate, notable behavioral improvements were seen from methylphenidate treatment in both the ADHD + anxiety and the ADHD minus anxiety groups.

The implications of this discrepancy can be noteworthy. To the parent who is only marginally involved with their child's academic progress, and is simply concerned with getting more manageable behavior out of their ADHD child, the sharp reduction of negative behavioral symptoms may lull the parent into a false sense of security that all is well on the home front. This stratified response to the methylphenidate medication may be lost to the unassuming parent.

However, it may be possible that an accompanying anxiety disorder (and maybe even an auditory processing disorder) may be lying there dormant to the oblivious parent. For the teacher, however, an improvement in classroom behavior due to medication, but a lack of improvement in academic work (especially in memory-related tasks) may be a tip-off that an undiagnosed accompanying anxiety disorder may be in place in this ADHD child. Thus this discrepancy in medication-derived improvements may actually serve as a potentially powerful diagnostic tool for detecting an accompanying anxiety disorder in a child being treated for ADHD.