Sublingual Immunotherapy Appears Viable in Treating Peanut Allergies in Kids

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Peanut sublingual immunotherapy (SLIT) achieved clinically significant desensitization to peanut allergens in the majority of children in an open-label, prospective study.

Among 47 kids who completed therapy and the 48-month double-blind, placebo-controlled food challenge, 70% achieved clinically significant desensitization (successfully consumed dose [SCD] >800 mg), and 36% achieved full desensitization (SCD 5,000 mg), reported Edwin H. Kim, MD, MS, of the University of North Carolina School of Medicine in Chapel Hill, and co-authors.

The mean SCD of peanut protein during the food challenge increased from 48.4 mg at baseline to 2,723 mg after 48 months (P<0.0001), and desensitization lasted more than 17 weeks following treatment discontinuation, they noted in the Journal of Allergy and Clinical Immunology

opens in a new tab or window.As of 2021, it has been estimated

opens in a new tab or window that about 4.6 million adults in the U.S. have some form of peanut allergy, with 800,000 having developed the allergy during adulthood. Approximately 200,000 people in the U.S.opens in a new tab or window are sent to the emergency department following a food-related allergic reaction each year.

"The typical approach of strict allergen avoidance has been shown to greatly reduce the frequency of allergic reactions; however, over time most patients experience accidental ingestions with unpredictable and sometimes severe symptoms," Kim and team wrote. "Furthermore, strict allergen avoidance has led to the unintended consequence of a significant decrease in quality of life driven by factors such as anxiety, social isolation, restricted daily activities, and financial burden. Immunotherapy has been the best studied approach to treatment with numerous positive studies of oral immunotherapy (OIT) leading to the recent regulatory approval of the first product for peanut OIT."

In the study, peanut skin prick testing for the per-protocol population was significantly decreased by 12 months of treatment and remained this way over the course of treatment, from a mean wheal size of 16.5 mm at baseline to 9.1 mm after 48 months (P<0.0001).

Peanut-specific immunoglobulin E levels had significantly decreased by 24 months and through the duration of treatment, from a mean baseline level of 213.0 kU_A/L to 60.7 kU_A/L after 48 months (P<0.0001), following an initial increase from baseline to 6 months. Peanut-specific immunoglobulin G4, however, increased from an average of 0.8 mg/L at baseline to an average of 20.6 mg/L after 48 months (P<0.0001).

Mean percentage of CD63+ basophils decreased from baseline at both the 10 ng/mL dilution, which was significant throughout the 48 months, and the 1 ng/mL dilution, which was significant at the 24- and 48-month time points.

T_H2 cytokine levels after peanut stimulation also decreased over time, with average IL-4, IL-5, IL-13, and IFN-gamma levels significantly reduced over 48 months.

"With the goal of peanut allergy treatment increasingly focused on protection from accidental ingestions of peanut, our data for peanut SLIT supports a treatment response in the majority of patients that importantly appears to be able to withstand lapses in therapy of up to several weeks," Kim and colleagues wrote.

"When considering that tolerance does not appear likely with food immunotherapy and that treatment is likely to be required long-term if not indefinitely, these results demonstrating the feasibility and safety of keeping up the daily peanut SLIT regimen for multiple years take on particular importance," they added.

For this study, 54 peanut-allergic children ages 1 to 11 years (mean age 7.1, 63% boys, 90.7% white) were treated with open-label 4-mg peanut SLIT for 48 months, and 47 completed therapy. At baseline, 70.4% of children reported atopic dermatitis, 59.3% reported allergic rhinitis, 40.7% reported asthma, and 27.8% reported other food allergies. Dosing compliance was high, with 97.6% of doses administered.

Desensitization after SLIT was assessed by a 5,000-mg double-blind, placebo-controlled food challenge. A randomly assigned avoidance period between 1-17 weeks was followed by a food challenge. Skin prick testing, immunoglobulins, basophil activation testing, TH1, TH2, and IL-10 cytokines were measured longitudinally. Safety was assessed through patient-reported diaries.

Symptoms were reported after 4% of home-administered doses. Lip swelling and oropharyngeal itching were the most common symptoms, occurring with 3.7% of doses. Belly pain, vomiting, diarrhea, and skin symptoms were reported with 0.1% of doses. Three participants withdrew as the result of abdominal reactions or food aversion. While 0.14% of the administered doses required the use of antihistamines, epinephrine was not given at any point during the course of the study.

Kim and team noted that there was no blinding of the treatment or avoidance phases of the study, which was a limitation. Children can also "spontaneously outgrow" a peanut allergy, though the authors said this was unlikely in their cohort.

International Conference on Pediatrics, Perinatology and Child Health

14th Edition of Pediatrics | 24-26 April 2023 | London, United Kingdom (Hybrid)

visit: https://pediatrics-conferences.pencis.com/

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Tablet-based game can assess pediatric visual motor skills in autism

 A tablet-based game is feasible for assessing visual motor skills in neurotypical children and those with autism spectrum disorder, according to a study published online Feb. 3 in npj Digital Medicine.

       Sam Perochon, from Duke University in Durham, North Carolina, and colleagues examined the use of a bubble-popping game administered on a tablet as an assessment of visual-motor abilities in young children. Participants included 233 children aged 1.5 to 10 years: 147 neurotypical and 86 diagnosed with autism spectrum disorder, 32 of whom had co-occurring attention-deficit/hyperactivity disorder (autistic+ADHD). Game-based touch features were compared across autistic, autistic+ADHD, and neurotypical participants.

   The researchers found that younger children with autism (aged 1.5 to 3 years) popped the bubbles at a lower rate, and their ability to touch the center of the bubble was less accurate than that of neurotypical children. In addition, their finger lingered for a longer period when they popped a bubble and there was more variability in their performance. For older children (3 to 10 years), greater motor impairment was seen in association with the presence of co-occurring ADHD, reflected by lower accuracy and more variability in performance. There were correlations seen for several motor features with fine motor and cognitive abilities.

"This simple yet informative tool has the potential of being deployed at scale to enhance detection and assessment of early autism signs and obtain objective and quantitative measures of toddler and school age children's visual motor skills," the authors write.

International Conference on Pediatrics, Perinatology and Child Health

14th Edition of Pediatrics | 24-26 April 2023 | London, United Kingdom (Hybrid)

visit: https://pediatrics-conferences.pencis.com/

#therapy 

 #speechtherapy

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 #radiology

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Congenital heart defects in children

                                                            

Symptoms

Serious congenital heart defects usually are noticed soon after birth or during the first few months of life. Signs and symptoms could include:

• Pale gray or blue lips, tongue or fingernails (cyanosis)
• Rapid breathing
• Swelling in the legs, belly or areas around the eyes
• Shortness of breath during feedings, leading to poor weight gain

Less-serious congenital heart defects may not be diagnosed until later in childhood. Signs and symptoms of congenital heart defects in older children may include:

• Easily becoming short of breath during exercise or activity
• Easily tiring during exercise or activity
• Fainting during exercise or activity
• Swelling in the hands, ankles or feet

causes

• To understand the causes of congenital heart defects, it may be helpful to know how the heart typically works.

• The heart is divided into four chambers, two on the right and two on the left. To pump blood throughout the body, the heart uses its left and right sides for different tasks.

  The right side of the heart moves blood to the lungs through the lung (pulmonary) arteries. In the lungs, blood picks up oxygen then returns to the heart's left side through the pulmonary veins. The left side of the heart then pumps the blood through the body's main artery (aorta) and out to the rest of the body.

  How congenital heart defects develop

  During the first six weeks of pregnancy, the baby's heart begins to form and starts beating. The major blood vessels that run to and from the heart also begin to develop during this critical time.

  It's at this point in a baby's development that congenital heart defects may begin to develop. Researchers aren't sure exactly what causes most of these defects, but they think genetics, certain medical conditions, some medications, and environmental or lifestyle factors, such as smoking, may play a role.

  There are many different types of congenital heart defects. They fall into the general categories described below.

  Altered connections in the heart or blood vessels

  Altered connections allow blood to flow where it usually wouldn't. Holes in the walls between heart chambers are one example of this type of congenital heart defect.

  An altered connection can cause oxygen-poor blood to mix with oxygen-rich blood. This lowers the amount of oxygen sent through the body. The change in blood flow forces the heart and lungs to work harder.

  Types of altered connections in the heart or blood vessels include:

  • Atrial septal defect is a hole between the upper heart chambers (atria).
  • Ventricular septal defect is a hole in the wall between the right and left lower heart chambers (ventricles).
  • Patent ductus arteriosus (PAY-tunt DUK-tus ahr-teer-e-O-sus) is a connection between the lung artery and the body's main artery (aorta). It's open while a baby is growing in the womb, and typically closes a few hours after birth. But in some babies, it stays open, causing incorrect blood flow between the two arteries.
  • Total or partial anomalous pulmonary venous connection occurs when all or some of the blood vessels from the lungs (pulmonary veins) attach to a wrong area or areas of the heart.

  Congenital heart valve problems

  Heart valves are like doorways between the heart chambers and the blood vessels. Heart valves open and close to keep blood moving in the proper direction. If the heart valves can't open and close correctly, blood can't flow smoothly.

  Heart valve problems include valves that are narrowed and don't open completely (stenosis) or valves that don't close completely (regurgitation).

  Examples of congenital heart valve problems include:

  • Aortic stenosis (stuh-NO-sis). A baby may be born with an aortic valve that has one or two valve flaps (cusps) instead of three. This creates a small, narrowed opening for blood to pass through. The heart must work harder to pump blood through the valve. Eventually, this leads to enlarging of the heart and thickening of the heart muscle.
  • Pulmonary stenosis. A defect on or near the pulmonary valve narrows the pulmonary valve opening and slows the blood flow.
  • Ebstein anomaly. The tricuspid valve — which is located between the right upper heart chamber (atrium) and the right lower chamber (ventricle) — is malformed and often leaks.

  Combination of congenital heart defects

  Some infants are born with several congenital heart defects that affect the structure and function of the heart. Very complex heart problems may cause significant changes in blood flow or undeveloped heart chambers.

  For example, tetralogy of Fallot (teh-TRAL-uh-jee of fuh-LOW) is a combination of four congenital heart defects:

  • A hole in the wall between the heart's lower chambers (ventricles)
  • A narrowed passage between the right ventricle and pulmonary artery
  • A shift in the connection of the aorta to the heart
  • Thickened muscle in the right ventricle

  Other examples of complex congenital heart defects are:

  • Pulmonary atresia. The valve that lets blood out of the heart to go to the lungs (pulmonary valve) isn't formed correctly. Blood can't travel its usual route to get oxygen from the lungs.
  • Tricuspid atresia. The tricuspid valve isn't formed. Instead, there's solid tissue between the right upper heart chamber (atrium) and the right lower chamber (ventricle). This congenital heart defect restricts blood flow and causes the right ventricle to be underdeveloped.
  • Transposition of the great arteries. In this serious, rare congenital heart defect, the two main arteries leaving the heart are reversed (transposed). There are two types. Complete transposition of the great arteries is typically noticed during pregnancy or soon after birth. Levo-transposition of the great arteries (L-TGA) is less common. Symptoms may not be noticed right away.
  • Hypoplastic left heart syndrome. A major part of the heart fails to develop properly. In hypoplastic left heart syndrome, the left side of the heart hasn't developed enough to effectively pump enough blood to the body.

  Risk factors

  Most congenital heart defects result from changes that occur early as the baby's heart is developing before birth. The exact cause of most congenital heart defects is unknown, but some risk factors have been identified. Risk factors for congenital heart defects include:

  • Rubella (German measles). Having rubella during pregnancy can cause problems in a baby's heart development. A blood test done before pregnancy can determine if you're immune to rubella. A vaccine is available for those who aren't immune.
  • Diabetes. Careful control of blood sugar before and during pregnancy can reduce the risk of congenital heart defects in the baby. Diabetes that develops during pregnancy (gestational diabetes) generally doesn't increase a baby's risk of heart defects.

  • Medications. Certain medications taken during pregnancy may cause birth defects, including congenital heart defects. Give your health care provider a complete list of medications you take before trying to become pregnant.

    Medications known to increase the risk of congenital heart defects include thalidomide (Thalomid), angiotensin-converting enzyme (ACE) inhibitors, statins, the acne medication isotretinoin (Myorisan, Zenatane, others), some epilepsy drugs and certain anxiety drugs.

  • Drinking alcohol during pregnancy. Drinking alcohol during pregnancy increases the risk of congenital heart defects.
  • Smoking. If you smoke, quit. Smoking during pregnancy increases the risk of a congenital heart defect in the baby.
  • Family history and genetics. Congenital heart defects sometimes run in families (are inherited) and may be associated with a genetic syndrome. Many children with an extra 21st chromosome (Down syndrome) have congenital heart defects. A missing piece (deletion) of genetic material on chromosome 22 also causes heart defects.

  Complications

  Potential complications of a congenital heart defect include:

  • Congestive heart failure. This serious complication may develop in babies who have a significant heart defect. Signs of congestive heart failure include rapid breathing, often with gasping breaths, and poor weight gain.
  • Heart infections. Congenital heart defects can increase the risk of infection of the heart tissue (endocarditis), which can lead to new heart valve problems.
  • Irregular heart rhythms (arrhythmias). A congenital heart defect or scarring from heart surgery may cause changes in the heart's rhythm.
  • Slower growth and development (developmental delays). Children with more-serious congenital heart defects often develop and grow more slowly than do children who don't have heart defects. They may be smaller than other children of the same age. If the nervous system has been affected, a child may learn to walk and talk later than other children.
  • Stroke. Although uncommon, some children with congenital heart defects are at increased risk of stroke due to blood clots traveling through a hole in the heart and on to the brain.
  • Mental health disorders. Some children with congenital heart defects may develop anxiety or stress because of developmental delays, activity restrictions or learning difficulties. Talk to your child's provider if you're concerned about your child's mental health.

  Prevention

  Because the exact cause of most congenital heart defects is unknown, it may not be possible to prevent these conditions. If you have a high risk of giving birth to a child with a congenital heart defect, genetic testing and screening may be done during pregnancy.

  There are some steps you can take to help reduce your child's overall risk of birth defects such as:

  • Get proper prenatal care. Regular checkups with a health care provider during pregnancy can help keep mom and baby healthy.
  • Take a multivitamin with folic acid. Taking 400 micrograms of folic acid daily has been shown to reduce birth defects in the brain and spinal cord. It may help reduce the risk of heart defects as well.
  • Don't drink or smoke. These lifestyle habits can harm a baby's health. Also avoid secondhand smoke.
  • Get a rubella (German measles) vaccine. A rubella infection during pregnancy may affect a baby's heart development. Get vaccinated before trying to get pregnant.
  • Control blood sugar. If you have diabetes, good control of your blood sugar can reduce the risk of congenital heart defects.
  • Manage chronic health conditions. If you have other health conditions, including phenylketonuria, talk to your health care provider about the best way to treat and manage them.
  • Avoid harmful substances. During pregnancy, have someone else do any painting and cleaning with strong-smelling products.
  • Check with your provider before taking any medications. Some medications can cause birth defects. Tell your provider about all the medications you take, including those bought without a prescription.

International Conference on Pediatrics, Perinatology and Child Health

14th Edition of PPCH | 24-26 April 2023 | London, United Kingdom (Hybrid)

Visit: https://pediatrics-conferences.pencis.com/ #PediatricsConferences #Perinatology #childHealth