Использование низкобелковых обогащенных крахмаломучных продуктов в диетотерапии больных фенилкетонурией детей в возрасте старше 1 года

Background. The nutrition of children with phenylketonuria includes specialized starch-based products, the range of which is constantly expanding. Our aim was to study the safety of the composition of starchy flakes enriched with a complex of fat-soluble vitamins, natural fruit and berry additives used in the food of children with phenylketonuria. Methods. The study included children under the age of 14 years who were compliant with the previously conducted hypophenylalanine diet, without acute infectious, severe somatic or neurological diseases. The investigated products (starch-rye, wheat, and wheat fruit flakes with a complex of provitamin A and vitamin E) were prescribed instead of previously used low-protein confectionery products in the amount of 20–25 g/day for children under 6 years, 30–40 g — for children aged 6 years and over. The products were given with the recommendation to use alternately, with a duration of at least 10 days, totally for 30 days of the study. The safety of the products was assessed by phenylalanine concentration in the blood (determined by the fluorimetric method). In addition, we assessed the organoleptic qualities of the products and the dynamics of physical development of children. Results. The study included 15 children, mean age 4.4 ± 1.9 years. The initial concentration of phenylalanine in the blood varied from 1.6 to 3.9 mg%, the median — 2.2 mg% (2.0; 2.8). In 30 days after inclusion of starchy flakes in the diet, the content of phenylalanine in the blood did not change and was 2.5 mg% (2.2; 2.7); p = 0.859. The organoleptic properties of the products were rated «excellent» by all patients and their parents (in children under 6 years, only according to the parents’ assessment). The indicators of physical development did not change. There was no adverse events (allergic reactions, dyspepsia, refusal to take food). Conclusion. Introduction of new functional products — low-protein starchy flakes enriched with a vitamin complex and natural fruit and berry additives — in the diet of children with phenylketonuria allows to maintain the level of phenylalanine in the blood at the level of reference values.Обоснование. В питании детей с фенилкетонурией широко используют специализированные продукты на основе крахмалов, ассортимент которых постоянно расширяется.Цель исследования — изучить безопасность состава хлопьев крахмаломучных, обогащенных комплексом жирорастворимых витаминов, натуральными плодовыми и ягодными добавками, используемых в пище детей с фенилкетонурией.Методы. В исследование включали детей в возрасте до 14 лет, комплаентных к ранее проводимой гипофенилаланиновой диете, без острых инфекционных, тяжелых соматических или неврологических заболеваний. Исследуемые продукты — крахмалоржаные, пшеничные и пшеничные плодово-ягодные хлопья с комплексом провитамина А и витамина Е — назначали взамен применявшихся ранее низкобелковых кондитерских изделий в количестве 20–25 г/сут детям младше 6 лет, по 30–40 г — детям, достигших возраста или старше 6 лет. Продукты выдавали с рекомендацией использовать поочередно, продолжительностью не менее 10 сут, всего на 30 сут исследования. Безопасность продуктов оценивали по концентрации фенилаланина в крови (определяли флюориметрическим методом). Дополнительно оценивали органолептические качества продуктов и динамику физического развития детей.Результаты. В исследование включили 15 детей, средний возраст 4,4±1,9 года. Исходная концентрация фенилаланина в крови варьировала от 1,6 до 3,9 мг%, медиана — 2,2 мг% (2,0; 2,8). Через 30 сут после включения в рацион крахмаломучных хлопьев содержание фенилаланина в крови не изменилось и составило 2,5 мг% (2,2; 2,7); р=0,859. Органолептические свойства продуктов были оценены на «отлично» всеми пациентами и их родителями (у детей в возрасте до 6 лет — только согласно оценке родителей). Показатели физического развития не изменились. Нежелательные явления (аллергические реакции, диспепсии, отказ от приема продуктов) не зафиксированы.Заключение. Введение в рацион детей с фенилкетонурией новых функциональных продуктов — хлопьев крахмаломучных низкобелковых, обогащенных витаминным комплексом и натуральными плодовыми и ягодными добавками, позволяет сохранять уровень фенилаланина в крови на уровне референсных значений.ИСТОЧНИК ФИНАНСИРОВАНИЯ Работа выполнена при поддержке гранта Федерального государственного научного учреждения «Всероссийский научно-исследовательский институт крахмалопродуктов» Федерального агентства научных организаций (Московская область). Для целей исследования использовались продукты, безвозмездно предоставленные производителем (опытное производство ФГНУ «ВНИИК» ФАНО).КОНФЛИКТ ИНТЕРЕСОВ Т.Э. Боровик, Н.Н. Семёнова, О.Л. Лукоянова, Н.Г. Звонкова, Т.В. Бушуева, Т.Н. Степанова, В.А. Скворцова — проведение научно-исследовательских работ при поддержке компаний Heinz, Semper, Хипрока Нутришион Ист Лимитед. И.М. Гусева, Е.А. Рославцева, А.К. Геворкян, С.Т. Быкова, Т.Г. Калинина, С.Г. Калиненкова подтвердили отсутствие конфликта интересов.ВЫРАЖЕНИЕ ПРИЗНАТЕЛЬНОСТИ Выражаем благодарность к.м.н. С.Г. Калиненковой (Московский областной научно-исследовательский клинический институт им. М.Ф. Владимирского) за участие в выполнении лабораторной части данного исследования. 

Comparative Study of Extracellular Vesicles from the Urine of Healthy Individuals and Prostate Cancer Patients.

Recent studies suggest that extracellular vesicles may be the key to timely diagnosis and monitoring of genito-urological malignancies. In this study we investigated the composition and content of extracellular vesicles found in the urine of healthy donors and prostate cancer patients. Urine of 14 PCa patients and 20 healthy volunteers was clarified by low-speed centrifugation and total extracellular vesicles fraction was obtain by high-speed centrifugation. The exosome-enriched fraction was obtained by filtration of total extracellular vesicles through a 0.1 μm pore filter. Transmission electron microscopy showed that cell-free urine in both groups contained vesicles from 20 to 230 nm. Immunogold staining after ultrafiltration demonstrated that 95% and 90% of extracellular vesicles in healthy individuals and cancer patients, respectively, were exosomes. Protein, DNA and RNA concentrations as well as size distribution of extracellular vesicles in both fractions were analyzed. Only 75% of the total protein content of extracellular vesicles was associated with exosomes which amounted to 90-95% of all vesicles. Median DNA concentrations in total extracellular vesicles and exosome-enriched fractions were 18 pg/ml and 2.6 pg/ml urine, correspondingly. Urine extracellular vesicles carried a population of RNA molecules 25 nt to 200 nt in concentration of no more than 290 pg/ml of urine. Additionally, concentrations of miR-19b, miR-25, miR-125b, and miR-205 were quantified by qRT-PCR. MiRNAs were shown to be differently distributed between different fractions of extracellular vesicles. Detection of miR-19b versus miR-16 in total vesicles and exosome-enriched fractions achieved 100%/93% and 95%/79% specificity/sensitivity in distinguishing cancer patients from healthy individuals, respectively, demonstrating the diagnostic value of urine extracellular vesicles

Use of Low-Protein Enriched Starch Products in Diet Therapy of Children With Phenylketonuria Aged Over One Year

Background. The nutrition of children with phenylketonuria includes specialized starch-based products, the range of which is constantly expanding. Our aim was to study the safety of the composition of starchy flakes enriched with a complex of fat-soluble vitamins, natural fruit and berry additives used in the food of children with phenylketonuria. Methods. The study included children under the age of 14 years who were compliant with the previously conducted hypophenylalanine diet, without acute infectious, severe somatic or neurological diseases. The investigated products (starch-rye, wheat, and wheat fruit flakes with a complex of provitamin A and vitamin E) were prescribed instead of previously used low-protein confectionery products in the amount of 20–25 g/day for children under 6 years, 30–40 g — for children aged 6 years and over. The products were given with the recommendation to use alternately, with a duration of at least 10 days, totally for 30 days of the study. The safety of the products was assessed by phenylalanine concentration in the blood (determined by the fluorimetric method). In addition, we assessed the organoleptic qualities of the products and the dynamics of physical development of children. Results. The study included 15 children, mean age 4.4 ± 1.9 years. The initial concentration of phenylalanine in the blood varied from 1.6 to 3.9 mg%, the median — 2.2 mg% (2.0; 2.8). In 30 days after inclusion of starchy flakes in the diet, the content of phenylalanine in the blood did not change and was 2.5 mg% (2.2; 2.7); p = 0.859. The organoleptic properties of the products were rated «excellent» by all patients and their parents (in children under 6 years, only according to the parents’ assessment). The indicators of physical development did not change. There was no adverse events (allergic reactions, dyspepsia, refusal to take food). Conclusion. Introduction of new functional products — low-protein starchy flakes enriched with a vitamin complex and natural fruit and berry additives — in the diet of children with phenylketonuria allows to maintain the level of phenylalanine in the blood at the level of reference values

Total RNA in preparations of urine EVs.

<p>Bioanalyzer traces of total RNA from ERV fraction of the urine of HD (A) and PCa patient (B). The data from Agilent 2100 Bioanalyzer with 25 nt RNA fragment as an internal standard.</p

Example miR-19b correlation plots.

<p>Correlation plots of miR-19b concentration in TEV and ERV fractions of healthy individuals (A) and prostate cancer patients (B). AU—arbitrary units of concentration.</p

Appearance and size of urine EVs.

<p>(A) TEM images of EVs from urine of HD and PCa patients before and after 0.1 μm filtration. (B) Size distribution of EVs before and after 0.1 μm filtration. Mean size with error bars for range. Additional TEM images can be found in <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0157566#pone.0157566.s001" target="_blank">S1 Fig</a>.</p

Protein concentration in urine EVs.

<p>Tukey box plots of concentration of total protein in preparations of EVs isolated from the urine of PCa patients and HD were determined using NanoOrange fluorescent dye and presented as mg per ml of probe (A) or ng per ml of urine (B).</p

Relative miRNA expression in urine EVs.

<p>Tukey box plots of miRNA expression in all fractions of urine. Asterisks (*) indicate statistical significance. *P<0.0001; **P = 0.0150.</p

Overview of the study population.

<p>Overview of the study population.</p

Expression and diagnostic value of miRNA in HD and PCa patients.

<p>Analytical performance ROC analysis and statistical analysis of the results (non-parametric Mann-Whitney test) of miRNA expression in urine.</p