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    Scott Adams
    Traditionally, gluten is defined as a cohesive, elastic protein that is left behind after starch is washed away from a wheat flour dough. Only wheat is considered to have true gluten. Gluten is actually made up of many different proteins.
    There are two main groups of proteins in gluten, called the gliadins and the glutenins. Upon digestion, the gluten proteins break down into smaller units, called peptides (also, polypeptides or peptide chains) that are made up of strings of amino acids--almost like beads on a string. The parent proteins have polypeptide chains that include hundreds of amino acids. One particular peptide has been shown to be harmful to celiac patients when instilled directly into the small intestine of several patients. This peptide includes 19 amino acids strung together in a specific sequence. Although the likelihood that this particular peptide is harmful is strong, other peptides may be harmful, as well, including some derived from the glutenin fraction.
    It is certain that there are polypeptide chains in rye and barley proteins that are similar to the ones found in wheat. Oat proteins have similar, but slightly different polypeptide chains and may or may not be harmful to celiac patients. There is scientific evidence supporting both possibilities.
    When celiac patients talk about "gluten-free" or a "gluten-free diet," they are actually talking about food or a diet free of the harmful peptides from wheat, rye, barley, and (possibly) oats. This means eliminating virtually all foods made from these grains (e. g., food starch when it is prepared from wheat, and malt when it comes from barley) regardless of whether these foods contain gluten in the very strict sense. Thus, "gluten-free" has become shorthand for "foods that dont harm celiacs."
    In recent years, especially among non-celiacs, the term gluten has been stretched to include corn proteins (corn gluten) and there is a glutinous rice, although in the latter case, glutinous refers to the stickiness of the rice rather than to its containing gluten. As far as we know, neither corn nor glutinous rice cause any harm to celiacs.

    Scott Adams
    Vijay Kumar, M.D., Research Associate Professor at the University of Buffalo and President and Director of IMMCO Diagnostics: If the tests are performed using well standardized tests with known positive and negative predictive values then you can make the statement that if the serological tests are negative celiac disease can virtually be ruled out. The problem is that some of these assays, especially the gliadin, can give you false positive results. In our laboratory we rarely see positive AGA results in the absence of EMA and ARA antibodies.

    Scott Adams
    Karoly Horvath, M.D., Ph.D., Associate Professor of Pediatrics; Director, Peds GI & Nutrition Laboratory; University of Maryland at Baltimore: The biopsy is a small piece of tissue, such as from the inside lining of the intestine, that has been removed to look for diseases. The biopsy itself is not painful, because there are no pain-sensitive nerves inside the small intestine. An intestinal biopsy can be done in either of two ways depending on the age of the children and the tradition of the institution. Sometimes a blind biopsy procedure is performed by a biopsy capsule. This is thin flexible tube with a capsule at the tip, which has a hole and a tiny knife inside the capsule. This capsule is introduced into the intestine under fluoroscopy (X-ray) control. Alternatively, with an endoscopy the doctor can see inside the digestive tract without using an x-ray to obtain biopsies. The biopsy specimens are processed and viewed under the microscope to identify or exclude celiac disease. An important basic rule is that the biopsy should be performed safely. For a safe procedure children (and adults) should be sedated. There are two methods of sedation: unconscious (general anesthesia) and conscious sedation. During both kinds of sedation the vital parameters (heart rate, blood pressure, oxygen saturation) of patients are continuously monitored. The method of choice depends on the child.
    Conscious sedation is performed with two different intravenous medications. One of them is a sedative medication (e.g. Versed), which causes amnesia in 80-90% of children, and even older children do not recall the procedure. The second medication is a pain-killer type medication (e.g. Fentanyl), which further reduces the discomfort associated with the procedure. In addition, the throat is sprayed with a local anesthetic in older children, which makes the throat numb and prevents retching at the introduction of the endoscope.
    During general anesthesia the anesthesiologist uses sleep-gases (e.g. halothan) and intravenous medications and then places a tube into the trachea. Children are completely unconscious. This is a safer way to perform endoscopy, because the patients are fully relaxed and their airway is protected. However, the anesthesia itself has certain complications.

    Scott Adams
    Very few celiacs are likely to have any reaction to topical gluten contact. In order for a gut reaction to occur, it is likely that direct contact with the gut lumen is required. Many people with celiac disease have everyday contact with gluten (for instance, bakers with celiac disease who have contact everyday with wheat flour), and do not have any reaction to it. However, there are, on rare occasion, people who have had an anaphylactoid response to gluten, and these people should avoid gluten in all forms. Also, topical gluten breathed into the upper airways may cause symptoms of allergic rhetinitis in rare instances. If there is a simple alternative to a shampoo, cosmetic, etc., you may want to use the non gluten containing product.

  • Recent Articles

    Jefferson Adams
    Celiac.com 06/18/2018 - Celiac disease has been mainly associated with Caucasian populations in Northern Europe, and their descendants in other countries, but new scientific evidence is beginning to challenge that view. Still, the exact global prevalence of celiac disease remains unknown.  To get better data on that issue, a team of researchers recently conducted a comprehensive review and meta-analysis to get a reasonably accurate estimate the global prevalence of celiac disease. 
    The research team included P Singh, A Arora, TA Strand, DA Leffler, C Catassi, PH Green, CP Kelly, V Ahuja, and GK Makharia. They are variously affiliated with the Division of Gastroenterology and Hepatology, Beth Israel Deaconess Medical Center, Boston, Massachusetts; Lady Hardinge Medical College, New Delhi, India; Innlandet Hospital Trust, Lillehammer, Norway; Centre for International Health, University of Bergen, Bergen, Norway; Division of Gastroenterology and Hepatology, Beth Israel Deaconess Medical Center, Boston, Massachusetts; Gastroenterology Research and Development, Takeda Pharmaceuticals Inc, Cambridge, MA; Department of Pediatrics, Università Politecnica delle Marche, Ancona, Italy; Department of Medicine, Columbia University Medical Center, New York, New York; USA Celiac Disease Center, Columbia University Medical Center, New York, New York; and the Department of Gastroenterology and Human Nutrition, All India Institute of Medical Sciences, New Delhi, India.
    For their review, the team searched Medline, PubMed, and EMBASE for the keywords ‘celiac disease,’ ‘celiac,’ ‘tissue transglutaminase antibody,’ ‘anti-endomysium antibody,’ ‘endomysial antibody,’ and ‘prevalence’ for studies published from January 1991 through March 2016. 
    The team cross-referenced each article with the words ‘Asia,’ ‘Europe,’ ‘Africa,’ ‘South America,’ ‘North America,’ and ‘Australia.’ They defined celiac diagnosis based on European Society of Pediatric Gastroenterology, Hepatology, and Nutrition guidelines. The team used 96 articles of 3,843 articles in their final analysis.
    Overall global prevalence of celiac disease was 1.4% in 275,818 individuals, based on positive blood tests for anti-tissue transglutaminase and/or anti-endomysial antibodies. The pooled global prevalence of biopsy-confirmed celiac disease was 0.7% in 138,792 individuals. That means that numerous people with celiac disease potentially remain undiagnosed.
    Rates of celiac disease were 0.4% in South America, 0.5% in Africa and North America, 0.6% in Asia, and 0.8% in Europe and Oceania; the prevalence was 0.6% in female vs 0.4% males. Celiac disease was significantly more common in children than adults.
    This systematic review and meta-analysis showed celiac disease to be reported worldwide. Blood test data shows celiac disease rate of 1.4%, while biopsy data shows 0.7%. The prevalence of celiac disease varies with sex, age, and location. 
    This review demonstrates a need for more comprehensive population-based studies of celiac disease in numerous countries.  The 1.4% rate indicates that there are 91.2 million people worldwide with celiac disease, and 3.9 million are in the U.S.A.
    Source:
    Clin Gastroenterol Hepatol. 2018 Jun;16(6):823-836.e2. doi: 10.1016/j.cgh.2017.06.037.

    Jefferson Adams
    Celiac.com 06/16/2018 - Summer is the time for chips and salsa. This fresh salsa recipe relies on cabbage, yes, cabbage, as a secret ingredient. The cabbage brings a delicious flavor and helps the salsa hold together nicely for scooping with your favorite chips. The result is a fresh, tasty salsa that goes great with guacamole.
    Ingredients:
    3 cups ripe fresh tomatoes, diced 1 cup shredded green cabbage ½ cup diced yellow onion ¼ cup chopped fresh cilantro 1 jalapeno, seeded 1 Serrano pepper, seeded 2 tablespoons lemon juice 2 tablespoons red wine vinegar 2 garlic cloves, minced salt to taste black pepper, to taste Directions:
    Purée all ingredients together in a blender.
    Cover and refrigerate for at least 1 hour. 
    Adjust seasoning with salt and pepper, as desired. 
    Serve is a bowl with tortilla chips and guacamole.

    Dr. Ron Hoggan, Ed.D.
    Celiac.com 06/15/2018 - There seems to be widespread agreement in the published medical research reports that stuttering is driven by abnormalities in the brain. Sometimes these are the result of brain injuries resulting from a stroke. Other types of brain injuries can also result in stuttering. Patients with Parkinson’s disease who were treated with stimulation of the subthalamic nucleus, an area of the brain that regulates some motor functions, experienced a return or worsening of stuttering that improved when the stimulation was turned off (1). Similarly, stroke has also been reported in association with acquired stuttering (2). While there are some reports of psychological mechanisms underlying stuttering, a majority of reports seem to favor altered brain morphology and/or function as the root of stuttering (3). Reports of structural differences between the brain hemispheres that are absent in those who do not stutter are also common (4). About 5% of children stutter, beginning sometime around age 3, during the phase of speech acquisition. However, about 75% of these cases resolve without intervention, before reaching their teens (5). Some cases of aphasia, a loss of speech production or understanding, have been reported in association with damage or changes to one or more of the language centers of the brain (6). Stuttering may sometimes arise from changes or damage to these same language centers (7). Thus, many stutterers have abnormalities in the same regions of the brain similar to those seen in aphasia.
    So how, you may ask, is all this related to gluten? As a starting point, one report from the medical literature identifies a patient who developed aphasia after admission for severe diarrhea. By the time celiac disease was diagnosed, he had completely lost his faculty of speech. However, his speech and normal bowel function gradually returned after beginning a gluten free diet (8). This finding was so controversial at the time of publication (1988) that the authors chose to remain anonymous. Nonetheless, it is a valuable clue that suggests gluten as a factor in compromised speech production. At about the same time (late 1980’s) reports of connections between untreated celiac disease and seizures/epilepsy were emerging in the medical literature (9).
    With the advent of the Internet a whole new field of anecdotal information was emerging, connecting a variety of neurological symptoms to celiac disease. While many medical practitioners and researchers were casting aspersions on these assertions, a select few chose to explore such claims using scientific research designs and methods. While connections between stuttering and gluten consumption seem to have been overlooked by the medical research community, there is a rich literature on the Internet that cries out for more structured investigation of this connection. Conversely, perhaps a publication bias of the peer review process excludes work that explores this connection.
    Whatever the reason that stuttering has not been reported in the medical literature in association with gluten ingestion, a number of personal disclosures and comments suggesting a connection between gluten and stuttering can be found on the Internet. Abid Hussain, in an article about food allergy and stuttering said: “The most common food allergy prevalent in stutterers is that of gluten which has been found to aggravate the stutter” (10). Similarly, Craig Forsythe posted an article that includes five cases of self-reporting individuals who believe that their stuttering is or was connected to gluten, one of whom also experiences stuttering from foods containing yeast (11). The same site contains one report of a stutterer who has had no relief despite following a gluten free diet for 20 years (11). Another stutterer, Jay88, reports the complete disappearance of her/his stammer on a gluten free diet (12). Doubtless there are many more such anecdotes to be found on the Internet* but we have to question them, exercising more skepticism than we might when reading similar claims in a peer reviewed scientific or medical journal.
    There are many reports in such journals connecting brain and neurological ailments with gluten, so it is not much of a stretch, on that basis alone, to suspect that stuttering may be a symptom of the gluten syndrome. Rodney Ford has even characterized celiac disease as an ailment that may begin through gluten-induced neurological damage (13) and Marios Hadjivassiliou and his group of neurologists and neurological investigators have devoted considerable time and effort to research that reveals gluten as an important factor in a majority of neurological diseases of unknown origin (14) which, as I have pointed out previously, includes most neurological ailments.
    My own experience with stuttering is limited. I stuttered as a child when I became nervous, upset, or self-conscious. Although I have been gluten free for many years, I haven’t noticed any impact on my inclination to stutter when upset. I don’t know if they are related, but I have also had challenges with speaking when distressed and I have noticed a substantial improvement in this area since removing gluten from my diet. Nonetheless, I have long wondered if there is a connection between gluten consumption and stuttering. Having done the research for this article, I would now encourage stutterers to try a gluten free diet for six months to see if it will reduce or eliminate their stutter. Meanwhile, I hope that some investigator out there will research this matter, publish her findings, and start the ball rolling toward getting some definitive answers to this question.
    Sources:
    1. Toft M, Dietrichs E. Aggravated stuttering following subthalamic deep brain stimulation in Parkinson’s disease--two cases. BMC Neurol. 2011 Apr 8;11:44.
    2. Tani T, Sakai Y. Stuttering after right cerebellar infarction: a case study. J Fluency Disord. 2010 Jun;35(2):141-5. Epub 2010 Mar 15.
    3. Lundgren K, Helm-Estabrooks N, Klein R. Stuttering Following Acquired Brain Damage: A Review of the Literature. J Neurolinguistics. 2010 Sep 1;23(5):447-454.
    4. Jäncke L, Hänggi J, Steinmetz H. Morphological brain differences between adult stutterers and non-stutterers. BMC Neurol. 2004 Dec 10;4(1):23.
    5. Kell CA, Neumann K, von Kriegstein K, Posenenske C, von Gudenberg AW, Euler H, Giraud AL. How the brain repairs stuttering. Brain. 2009 Oct;132(Pt 10):2747-60. Epub 2009 Aug 26.
    6. Galantucci S, Tartaglia MC, Wilson SM, Henry ML, Filippi M, Agosta F, Dronkers NF, Henry RG, Ogar JM, Miller BL, Gorno-Tempini ML. White matter damage in primary progressive aphasias: a diffusion tensor tractography study. Brain. 2011 Jun 11.
    7. Lundgren K, Helm-Estabrooks N, Klein R. Stuttering Following Acquired Brain Damage: A Review of the Literature. J Neurolinguistics. 2010 Sep 1;23(5):447-454.
    8. [No authors listed] Case records of the Massachusetts General Hospital. Weekly clinicopathological exercises. Case 43-1988. A 52-year-old man with persistent watery diarrhea and aphasia. N Engl J Med. 1988 Oct 27;319(17):1139-48
    9. Molteni N, Bardella MT, Baldassarri AR, Bianchi PA. Celiac disease associated with epilepsy and intracranial calcifications: report of two patients. Am J Gastroenterol. 1988 Sep;83(9):992-4.
    10. http://ezinearticles.com/?Food-Allergy-and-Stuttering-Link&id=1235725 
    11. http://www.craig.copperleife.com/health/stuttering_allergies.htm 
    12. https://www.celiac.com/forums/topic/73362-any-help-is-appreciated/
    13. Ford RP. The gluten syndrome: a neurological disease. Med Hypotheses. 2009 Sep;73(3):438-40. Epub 2009 Apr 29.
    14. Hadjivassiliou M, Gibson A, Davies-Jones GA, Lobo AJ, Stephenson TJ, Milford-Ward A. Does cryptic gluten sensitivity play a part in neurological illness? Lancet. 1996 Feb 10;347(8998):369-71.

    Jefferson Adams
    Celiac.com 06/14/2018 - Refractory celiac disease type II (RCDII) is a rare complication of celiac disease that has high death rates. To diagnose RCDII, doctors identify a clonal population of phenotypically aberrant intraepithelial lymphocytes (IELs). 
    However, researchers really don’t have much data regarding the frequency and significance of clonal T cell receptor (TCR) gene rearrangements (TCR-GRs) in small bowel (SB) biopsies of patients without RCDII. Such data could provide useful comparison information for patients with RCDII, among other things.
    To that end, a research team recently set out to try to get some information about the frequency and importance of clonal T cell receptor (TCR) gene rearrangements (TCR-GRs) in small bowel (SB) biopsies of patients without RCDII. The research team included Shafinaz Hussein, Tatyana Gindin, Stephen M Lagana, Carolina Arguelles-Grande, Suneeta Krishnareddy, Bachir Alobeid, Suzanne K Lewis, Mahesh M Mansukhani, Peter H R Green, and Govind Bhagat.
    They are variously affiliated with the Department of Pathology and Cell Biology, and the Department of Medicine at the Celiac Disease Center, New York Presbyterian Hospital/Columbia University Medical Center, New York, USA. Their team analyzed results of TCR-GR analyses performed on SB biopsies at our institution over a 3-year period, which were obtained from eight active celiac disease, 172 celiac disease on gluten-free diet, 33 RCDI, and three RCDII patients and 14 patients without celiac disease. 
    Clonal TCR-GRs are not infrequent in cases lacking features of RCDII, while PCPs are frequent in all disease phases. TCR-GR results should be assessed in conjunction with immunophenotypic, histological and clinical findings for appropriate diagnosis and classification of RCD.
    The team divided the TCR-GR patterns into clonal, polyclonal and prominent clonal peaks (PCPs), and correlated these patterns with clinical and pathological features. In all, they detected clonal TCR-GR products in biopsies from 67% of patients with RCDII, 17% of patients with RCDI and 6% of patients with gluten-free diet. They found PCPs in all disease phases, but saw no significant difference in the TCR-GR patterns between the non-RCDII disease categories (p=0.39). 
    They also noted a higher frequency of surface CD3(−) IELs in cases with clonal TCR-GR, but the PCP pattern showed no associations with any clinical or pathological feature. 
    Repeat biopsy showed that the clonal or PCP pattern persisted for up to 2 years with no evidence of RCDII. The study indicates that better understanding of clonal T cell receptor gene rearrangements may help researchers improve refractory celiac diagnosis. 
    Source:
    Journal of Clinical Pathologyhttp://dx.doi.org/10.1136/jclinpath-2018-205023

    Jefferson Adams
    Celiac.com 06/13/2018 - There have been numerous reports that olmesartan, aka Benicar, seems to trigger sprue‐like enteropathy in many patients, but so far, studies have produced mixed results, and there really hasn’t been a rigorous study of the issue. A team of researchers recently set out to assess whether olmesartan is associated with a higher rate of enteropathy compared with other angiotensin II receptor blockers (ARBs).
    The research team included Y.‐H. Dong; Y. Jin; TN Tsacogianis; M He; PH Hsieh; and JJ Gagne. They are variously affiliated with the Division of Pharmacoepidemiology and Pharmacoeconomics, Department of Medicine, Brigham and Women's Hospital and Harvard Medical School in Boston, MA, USA; the Faculty of Pharmacy, School of Pharmaceutical Science at National Yang‐Ming University in Taipei, Taiwan; and the Department of Hepato‐Gastroenterology, Chi Mei Medical Center in Tainan, Taiwan.
    To get solid data on the issue, the team conducted a cohort study among ARB initiators in 5 US claims databases covering numerous health insurers. They used Cox regression models to estimate hazard ratios (HRs) and 95% confidence intervals (CIs) for enteropathy‐related outcomes, including celiac disease, malabsorption, concomitant diagnoses of diarrhea and weight loss, and non‐infectious enteropathy. In all, they found nearly two million eligible patients. 
    They then assessed those patients and compared the results for olmesartan initiators to initiators of other ARBs after propensity score (PS) matching. They found unadjusted incidence rates of 0.82, 1.41, 1.66 and 29.20 per 1,000 person‐years for celiac disease, malabsorption, concomitant diagnoses of diarrhea and weight loss, and non‐infectious enteropathy respectively. 
    After PS matching comparing olmesartan to other ARBs, hazard ratios were 1.21 (95% CI, 1.05‐1.40), 1.00 (95% CI, 0.88‐1.13), 1.22 (95% CI, 1.10‐1.36) and 1.04 (95% CI, 1.01‐1.07) for each outcome. Patients aged 65 years and older showed greater hazard ratios for celiac disease, as did patients receiving treatment for more than 1 year, and patients receiving higher cumulative olmesartan doses.
    This is the first comprehensive multi‐database study to document a higher rate of enteropathy in olmesartan initiators as compared to initiators of other ARBs, though absolute rates were low for both groups.
    Source:
    Alimentary Pharmacology & Therapeutics