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2. SAT-444 GENOTYPE - PHENOTYPE CORRELATION IN A PEDIATRIC ADPKD COHORT

Author

VAN GIEL, D., primary, De Rechter, S., additional, Breysem, L., additional, Hindryckx, A., additional, Janssens, P., additional, Decuypere, J.P., additional, Bammens, B., additional, Corveleyn, A., additional, Ferec, C., additional, Vennekens, R., additional, Harris, P., additional, Audrézet, M.P., additional, and Mekahli, D., additional

Published
2020
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4. ADPedKD: A Global Online Platform on the Management of Children With

Author

De Rechter, S, Bockenhauer, D, Guay-Woodford, LM, Liu, I, Mallett, AJ, Soliman, NA, Sylvestre, LC, Schaefer, F, Liebau, MC, Mekahli, D, Adamczyk, P, Akinci, N, Alpay, H, Ardelean, C, Ayasreh, N, Aydin, Z, Bael, A, Baudouin, V, Bayrakci, US, Bensman, A, Bialkevich, H, Biebuyck, A, Boyer, O, Bjanid, O, Brylka, A, Caliskan, S, Cambier, A, Camelio, A, Carbone, V, Charbit, M, Chiodini, B, Chirita, A, Cicek, N, Cerkauskiene, R, Collard, L, Conceicao, M, Constantinescu, I, Couderc, A, Crapella, B, Cvetkovic, M, Dima, B, Diomeda, F, Docx, M, Dolan, N, Dossier, C, Drozdz, D, Drube, J, Dunand, O, Dusan, P, Eid, LA, Emma, F, Hernandez, ME, Fila, M, Furlano, M, Gafencu, M, Ghuysen, M, Giani, M, Giordano, M, Girisgen, I, Godefroid, N, Godron-Dubrasquet, A, Gojkovic, I, Gonzalez, E, Gokce, I, Groothoff, JW, Guarino, S, Guffens, A, Hansen, P, Harambat, J, Haumann, S, He, G, Heidet, L, Helmy, R, Hemery, F, Hooman, N, Ilanas, B, Jankauskiene, A, Janssens, P, Karamaria, S, Kazyra, I, Koenig, J, Krid, S, Krug, P, Kwon, V, La Manna, A, Leroy, V, Litwin, M, Lombet, J, Longo, G, Lungu, AC, Mallawaarachchi, A, Marin, A, Marzuillo, P, Massella, L, Mastrangelo, A, McCarthy, H, Miklaszewska, M, Moczulska, A, Montini, G, Morawiec-Knysak, A, Morin, D, Murer, L, Negru, I, Nobili, F, Obrycki, L, Otoukesh, H, Ozcan, S, Pape, L, Papizh, S, Parvex, P, Pawlak-Bratkowska, M, Prikhodina, L, Prytula, A, Quinlan, C, Raes, A, Ranchin, B, Ranguelov, N, Repeckiene, R, Ronit, C, Salomon, R, Santagelo, R, Saygili, SK, Schaefer, S, Schreuder, M, Schurmans, T, Seeman, T, Segers, N, Sinha, M, Snauwaert, E, Spasojevic, B, Stabouli, S, Stoica, C, Stroescu, R, Szczepanik, E, Szczepanska, M, Taranta-Janusz, K, Teixeira, A, Thumfart, J, Tkaczyk, M, Torra, R, Torres, D, Tram, N, Utsch, B, Vande Walle, J, Vieux, R, Vitkevic, R, Wilhelm-Bals, A, Wuhl, E, Yildirim, ZY, Yuksel, S, and Zachwieja, K

Abstract

Background: Autosomal dominant polycystic kidney disease (ADPKD) is the most common monogenic cause of renal failure. For several decades, ADPKD was regarded as an adult-onset disease. In the past decade, it has become more widely appreciated that the disease course begins in childhood. However, evidence-based guidelines on how to manage and approach children diagnosed with or at risk of ADPKD are lacking. Also, scoring systems to stratify patients into risk categories have been established only for adults. Overall, there are insufficient data on the clinical course during childhood. We therefore initiated the global ADPedKD project to establish a large international pediatric ADPKD cohort for deep characterization. Methods: Global ADPedKD is an international multicenter observational study focusing on childhood-diagnosed ADPKD. This collaborative project is based on interoperable Web-based databases, comprising 7 regional and independent but uniformly organized chapters, namely Africa, Asia, Australia, Europe, North America, South America, and the United Kingdom. In the database, a detailed basic data questionnaire, including genetics, is used in combination with data entry from follow-up visits, to provide both retrospective and prospective longitudinal data on clinical, radiologic, and laboratory findings, as well as therapeutic interventions. Discussion: The global ADPedKD initiative aims to characterize in detail the most extensive international pediatric ADPKD cohort reported to date, providing evidence for the development of unified diagnostic, follow-up, and treatment recommendations regarding modifiable disease factors. Moreover, this registry will serve as a platform for the development of clinical and/or biochemical markers predicting the risk of early and progressive disease. C1 [De Rechter, Stephanie; Mekahli, Djalila] Univ Hosp Leuven, Dept Pediat Nephrol, Herestr 49, B-3000 Leuven, Belgium. [De Rechter, Stephanie; Mekahli, Djalila] Katholieke Univ Leuven, Dept Dev & Regenerat, PKD Res Grp, Leuven, Belgium. [Bockenhauer, Detlef] UCL Ctr Nephrol, London, England. [Bockenhauer, Detlef] Great Ormond St Hosp NHS Fdn Trust, London, England. [Guay-Woodford, Lisa M.] Childrens Natl Hlth Syst, Ctr Translat Sci, Washington, DC USA. [Liu, Isaac] Natl Univ Hlth Syst, Khoo Teck Puat Natl Univ, Childrens Med Inst, Singapore, Singapore. [Mallett, Andrew J.] Royal Brisbane & Womens Hosp, Kidney Hlth Serv, Brisbane, Qld, Australia. [Mallett, Andrew J.] Royal Brisbane & Womens Hosp, Conjoint Renal Res Lab, Brisbane, Qld, Australia. [Mallett, Andrew J.] Univ Queensland, Fac Med, Brisbane, Qld, Australia. [Mallett, Andrew J.] Univ Queensland, Inst Mol Biosci, Brisbane, Qld, Australia. [Mallett, Andrew J.] KidGen Collaborat & Australian Genom Hlth Allianc, Melbourne, Vic, Australia. [Soliman, Neveen A.] Cairo Univ, Ctr Pediat Nephrol & Transplantat, Kasr Al Ainy Sch Med, Dept Pediat, Cairo, Egypt. [Sylvestre, Lucimary C.] Hosp Pequeno Principe, Curitiba, Parana, Brazil. [Schaefer, Franz] Heidelberg Univ, Ctr Pediat & Adolescent Med, Div Pediat Nephrol, Med Ctr, Heidelberg, Germany. [Liebau, Max C.] Univ Hosp Cologne, Dept Pediat, Cologne, Germany. [Liebau, Max C.] Univ Hosp Cologne, Ctr Mol Med, Cologne, Germany. [Adamczyk, P.; Bjanid, O.; Brylka, A.; Morawiec-Knysak, A.; Szczepanska, M.] Dept Pediat, Zabrze, Poland. [Akinci, N.] Sariyer SISLI Hamidiye Etfal Res & Educ Hosp, Istanbul, Turkey. [Alpay, H.; Cicek, N.; Gokce, I] Marmara Univ, Sch Med, Div Pediat Nephrol, Istanbul, Turkey. [Ardelean, C.; Chirita, A.; Gafencu, M.; Stroescu, R.] Timisoara Children Hosp, Timisoara, Romania. [Ayasreh, N.; Furlano, M.; Torra, R.] Fundacio Puigvert, Barcelona, Spain. [Aydin, Z.; Bayrakci, U. S.] Ankara Univ Hlth Sci, Child Hlth & Dis, Ankara, Turkey. [Bael, A.; Docx, M.; Segers, N.] Koningin Paola Kinderziekenhuis Antwerpen, Antwerp, Belgium. [Baudouin, V; Cambier, A.; Couderc, A.; Dossier, C.; Kwon, V] Hop Robert Debre, AP HP, Paris, France. [Bensman, A.; Biebuyck, A.; Boyer, O.; Charbit, M.; Heidet, L.; Krid, S.; Krug, P.; Salomon, R.] Pediat Nephrol Necker Hosp, Paris, France. [Bialkevich, H.; Kazyra, I] 2nd City Childrens Clin Hosp, Natl Ctr Pediat Nephrol & RRT, Minsk, BELARUS. [Caliskan, S.; Ozcan, S.; Saygili, S. K.] Istanbul Cerrahpasa Fac Med, Istanbul, Turkey. [Camelio, A.; Nobili, F.; Vieux, R.] CHU Besancon, Besancon, France. [Carbone, V; Diomeda, F.; Torres, D.] Pediat Nephrol Unit Bari, Bari, Italy. [Chiodini, B.] HUDERF, Brussels, Belgium. [Collard, L.] CHR La Citadelle, Liege, Belgium. [Conceicao, M.; Teixeira, A.] Ctr Hosp Porto, Ctr Materno Infantil Norte, Porto, Portugal. [Constantinescu, I; Lungu, A. C.; Marin, A.; Negru, I; Stroescu, R.] Fundeni Clin Inst, Bucharest, Romania. [Crapella, B.; Giani, M.; Mastrangelo, A.; Montini, G.] Fdn IRCCS Ca Granda, Pediat Nephrol Dialysis & Transplant Unit, Milan, Italy. [Cvetkovic, M.; Gojkovic, I] Univ Childrens Hosp, Belgrade, Serbia. [Dima, B.] Clin Europe Hop St Elisabeth, Brussels, Belgium. [Dolan, N.] Our Ladys Childrens Hosp, Dublin, Ireland. [Drozdz, D.; Miklaszewska, M.; Zachwieja, K.] Jagiellonian Univ, Med Coll Cracow, Pediat Nephrol & Hypertens, Krakow, Poland. [Drube, J.; Pape, L.] Hannover Med Sch, Hannover, Germany. [Dunand, O.; Leroy, V] Pediat Nephrol Unit St Denis, St Denis, Reunion, France. [Dusan, P.; Spasojevic, B.; Stabouli, S.] Aristotle Univ Thessaloniki, Dept Pediat, Thessaloniki, Greece. [Eid, L. A.] Dubai Hosp, Pediat Nephrol Dept, Dubai, U Arab Emirates. [Emma, F.; Massella, L.] Bambino Gesu Pediat Hosp, Rome, Italy. [Espino Hernandez, M.] Hosp Infantil 12 Octubre Madrid, Madrid, Spain. [Fila, M.; Hemery, F.; Morin, D.] CHU Arnaud Villeneuve, Montpellier, France. [Ghuysen, Ms] CHU Liege, Liege, Belgium. [Giordano, M.] Pediat Nephrol Unit, Bari, Italy. [Girisgen, I; Yuksel, S.] Pamukkale Univ, Med Fac, Dept Pediat Nephrol, Denizli, Turkey. [Godefroid, N.; Ranguelov, N.] Clin Univ St Luc, Brussels, Belgium. [Godron-Dubrasquet, A.; Harambat, J.; Ilanas, B.] Bordeaux Univ Childrens Hosp, Bordeaux, France. [Gonzalez, E.] Childrens Univ Hosp, Geneva, Switzerland. [Groothoff, J. W.] Emma Childrens Hosp, Amsterdam, Netherlands. [Guarino, S.; La Manna, A.; Marzuillo, P.] Univ Campania Luigi Vanvitelli, Caserta, Italy. [Guffens, A.] CHC Clin Esperence, Montegnee, Belgium. [Hansen, P.] CHU Tivoli, La Louviere, Belgium. [Haumann, S.] Univ Klinikum Koln, Cologne, Germany. [He, G.] Foshan Women & Children Hosp, Foshan, Peoples R China. [Helmy, R.] Cairo Univ, Kasr Al Ainy Sch Med, Cairo, Egypt. [Hooman, N.; Otoukesh, H.] Iran Univ Med Sci, Aliasghar Clin Res Dev Unit, Tehran, Iran. [Janssens, P.] Univ Hosp Brussels, Brussels, Belgium. [Karamaria, S.; Prytula, A.; Raes, A.; Snauwaert, E.; Vande Walle, J.] UZ Gent, Ghent, Belgium. [Koenig, J.] Univ Hosp Muenster, Munster, Germany. [Litwin, M.; Obrycki, L.] Childrens Mem Hlth Inst, Warsaw, Poland. [Lombet, J.] CHR Citadelle, Liege, Belgium. [Longo, G.; Murer, L.] Hosp Univ Padova, Pediat Nephrol Dialysis & Transplant Unit, Padua, Italy. [Mallawaarachchi, A.] Garvan Inst, Darlinghurst, NSW, Australia. [Mallawaarachchi, A.] Royal Prince Alfred Hosp, Camperdown, NSW, Australia. [Mallawaarachchi, A.; McCarthy, H.; Quinlan, C.] KidGen, Sydney, NSW, Australia. [McCarthy, H.] Childrens Hosp Westmead, Westmead, NSW, Australia. [McCarthy, H.] Sydney Childrens Hosp, Sydney, NSW, Australia. [Papizh, S.; Prikhodina, L.] Pirogov Russian Nat Res Med Uni, Res & Clin Inst Pediat, Moscow, Russia. [Parvex, P.; Wilhelm-Bals, A.] Childrens Univ Hosp Geneva, Geneva, Switzerland. [Pawlak-Bratkowska, M.; Szczepanik, E.; Tkaczyk, M.] Polish Mothers Mem Hosp, Res Inst, Lodz, Poland. [Quinlan, C.] RCH Melbourne, Melbourne, Vic, Australia. [Ranchin, B.] Hop Femme Mere Enfant, Bron, France. [Ronit, C.] Ctr Hosp Luxembourg, Clin Pediat, Luxembourg, Luxembourg. [Schaefer, S.; Wuehl, E.] Ctr Pediat & Adolescent, Div Pediat Nephrol, Heidelberg, Germany. [Schreuder, M.] Radboudumc Amalia Childrens Hosp, Nijmegen, Netherlands. [Schurmans, T.; Tram, N.] CHU Charleroi, Charleroi, Belgium. [Seeman, T.] Charles Univ Prague, Prague, Czech Republic. [Seeman, T.] Motol Univ Hosp, Prague, Czech Republic. [Sinha, M.] Evelina London Childrens Hosp, London, England. [Taranta-Janusz, K.] Dept Pediat & Nephrol, Bialystok, Poland. [Thumfart, J.] Berlin Charite Univ Med, Berlin, Germany. [Utsch, B.] Herford Hosp, Dept Paediat, Herford, Germany. [Yildirim, Z. Y.] Istanbul Univ, Fac Med, Pediat Nephrol Dept, Istanbul, Turkey.

Published
2019

5. Is Autosomal Dominant Polycystic Kidney Disease a pediatric disorder? From AdultDPKD to ADPediatricKD : Is autosomaal dominante polycystische nierziekte een pediatrische aandoening?

Author

De Rechter, S, De Smedt, H, Levtchenko, E, and Mekahli, D

Subjects
urologic and male genital diseases
Abstract

In this PhD project, on the eve of broadening the AdultDPKD horizon with ADPediatricKD, we explored the childhood ADPKD phenotype and the challenges concerning its management, in order to urge the need for a standardized and multidisciplinary approach, as many ambiguities still exist. First, we confirmed the existence of the latter, by showing that the clinicians' attitudes and current clinical practice are lacking an agreement regarding testing in asymptomatic offspring and family planning. Indeed, this results in conflicting information given to the families followed up with ADPKD. More specifically, asymptomatic offspring might be undiagnosed until irreversible complications develop. As demonstrated in our survey, health caregivers share a responsibility to inform offspring on their risk, together with the parents. Second, we collected evidence for the care of ADPKD offspring. We demonstrated that children display both cardiovascular and phosphate and bone mineral metabolism alterations in the early disease stages of ADPKD. Concerning the latter, we encountered a significant prevalence of hypertension in ADPKD children and generated evidence that a 24h ABPM should be the preferred modality to monitor blood pressure in this population. Only by this means, the non-dipping, white-coat and masked hypertension phenotypes can be identified. As it has been shown in several reports that blood pressure control has an essential role in long-term cardiovascular outcome, it is important to screen for it in the at risk population. Finally, we generated novel tools to be used in the future to facilitate the establishment of childhood ADPKD management guidelines. We succeeded to initiate a global registry on childhood ADPKD, called 'ADPedKD' (www.ADPedKD.org) as a promising tool, together with a longitudinal biobank of well characterized and genotyped ADPKD children. We also described a new modality for TKV measurement in ADPKD children by demonstrating that the novel developed 3DUS technique is a valuable method to MRI to measure the renal volume. We have laid the foundations to meet the following challenges in the near future: identification of rapid progressors at childhood and defining childhood outcome parameters, which are fundamental milestones in the future pediatric research. After all, the best chance for preserving long-term renal function may be given by an early therapeutic start. status: published

Published
2018

6. ADPedKD: A Global Online Platform on the Management of Children With ADPKD

Author

De Rechter, S, Bockenhauer, D, Guay-Woodford, LM, Liu, I, Mallett, AJ, Soliman, NA, Sylvestre, LC, Schaefer, F, Liebau, MC, Mekahli, D, Adamczyk, P, Akinci, N, Alpay, H, Ardelean, C, Ayasreh, N, Aydin, Z, Bael, A, Baudouin, V, Bayrakci, US, Bensman, A, Bialkevich, H, Biebuyck, A, Boyer, O, Bjanid, O, Brylka, A, Caliskan, S, Cambier, A, Camelio, A, Carbone, V, Charbit, M, Chiodini, B, Chirita, A, Cicek, N, Cerkauskiene, R, Collard, L, Conceicao, M, Constantinescu, I, Couderc, A, Crapella, B, Cvetkovic, M, Dima, B, Diomeda, F, Docx, M, Dolan, N, Dossier, C, Drozdz, D, Drube, J, Dunand, O, Dusan, P, Eid, LA, Emma, F, Espino Hernandez, M, Fila, M, Furlano, M, Gafencu, M, Ghuysen, M, Giani, M, Giordano, M, Girisgen, I, Godefroid, N, Godron-Dubrasquet, A, Gojkovic, I, Gonzalez, E, Gokce, I, Groothoff, JW, Guarino, S, Guffens, A, Hansen, P, Harambat, J, Haumann, S, He, G, Heidet, L, Helmy, R, Hemery, F, Hooman, N, Ilanas, B, Jankauskiene, A, Janssens, P, Karamaria, S, Kazyra, I, Koenig, J, Krid, S, Krug, P, Kwon, V, La Manna, A, Leroy, V, Litwin, M, Lombet, J, Longo, G, Lungu, AC, Mallawaarachchi, A, Marin, A, Marzuillo, P, Massella, L, Mastrangelo, A, McCarthy, H, Miklaszewska, M, Moczulska, A, Montini, G, Morawiec-Knysak, A, Morin, D, Murer, L, Negru, I, Nobili, F, Obrycki, L, Otoukesh, H, Ozcan, S, Pape, L, Papizh, S, Parvex, P, Pawlak-Bratkowska, M, Prikhodina, L, Prytula, A, Quinlan, C, Raes, A, Ranchin, B, Ranguelov, N, Repeckiene, R, Ronit, C, Salomon, R, Santagelo, R, Saygili, SK, Schaefer, S, Schreuder, M, Schurmans, T, Seeman, T, Segers, N, Sinha, M, Snauwaert, E, Spasojevic, B, Stabouli, S, Stoica, C, Stroescu, R, Szczepanik, E, Szczepanska, M, Taranta-Janusz, K, Teixeira, A, Thumfart, J, Tkaczyk, M, Torra, R, Torres, D, Tram, N, Utsch, B, Vande Walle, J, Vieux, R, Vitkevic, R, Wilhelm-Bals, A, Wuehl, E, Yildirim, ZY, Yuksel, S, Zachwieja, K, De Rechter, S, Bockenhauer, D, Guay-Woodford, LM, Liu, I, Mallett, AJ, Soliman, NA, Sylvestre, LC, Schaefer, F, Liebau, MC, Mekahli, D, Adamczyk, P, Akinci, N, Alpay, H, Ardelean, C, Ayasreh, N, Aydin, Z, Bael, A, Baudouin, V, Bayrakci, US, Bensman, A, Bialkevich, H, Biebuyck, A, Boyer, O, Bjanid, O, Brylka, A, Caliskan, S, Cambier, A, Camelio, A, Carbone, V, Charbit, M, Chiodini, B, Chirita, A, Cicek, N, Cerkauskiene, R, Collard, L, Conceicao, M, Constantinescu, I, Couderc, A, Crapella, B, Cvetkovic, M, Dima, B, Diomeda, F, Docx, M, Dolan, N, Dossier, C, Drozdz, D, Drube, J, Dunand, O, Dusan, P, Eid, LA, Emma, F, Espino Hernandez, M, Fila, M, Furlano, M, Gafencu, M, Ghuysen, M, Giani, M, Giordano, M, Girisgen, I, Godefroid, N, Godron-Dubrasquet, A, Gojkovic, I, Gonzalez, E, Gokce, I, Groothoff, JW, Guarino, S, Guffens, A, Hansen, P, Harambat, J, Haumann, S, He, G, Heidet, L, Helmy, R, Hemery, F, Hooman, N, Ilanas, B, Jankauskiene, A, Janssens, P, Karamaria, S, Kazyra, I, Koenig, J, Krid, S, Krug, P, Kwon, V, La Manna, A, Leroy, V, Litwin, M, Lombet, J, Longo, G, Lungu, AC, Mallawaarachchi, A, Marin, A, Marzuillo, P, Massella, L, Mastrangelo, A, McCarthy, H, Miklaszewska, M, Moczulska, A, Montini, G, Morawiec-Knysak, A, Morin, D, Murer, L, Negru, I, Nobili, F, Obrycki, L, Otoukesh, H, Ozcan, S, Pape, L, Papizh, S, Parvex, P, Pawlak-Bratkowska, M, Prikhodina, L, Prytula, A, Quinlan, C, Raes, A, Ranchin, B, Ranguelov, N, Repeckiene, R, Ronit, C, Salomon, R, Santagelo, R, Saygili, SK, Schaefer, S, Schreuder, M, Schurmans, T, Seeman, T, Segers, N, Sinha, M, Snauwaert, E, Spasojevic, B, Stabouli, S, Stoica, C, Stroescu, R, Szczepanik, E, Szczepanska, M, Taranta-Janusz, K, Teixeira, A, Thumfart, J, Tkaczyk, M, Torra, R, Torres, D, Tram, N, Utsch, B, Vande Walle, J, Vieux, R, Vitkevic, R, Wilhelm-Bals, A, Wuehl, E, Yildirim, ZY, Yuksel, S, and Zachwieja, K

Abstract

BACKGROUND: Autosomal dominant polycystic kidney disease (ADPKD) is the most common monogenic cause of renal failure. For several decades, ADPKD was regarded as an adult-onset disease. In the past decade, it has become more widely appreciated that the disease course begins in childhood. However, evidence-based guidelines on how to manage and approach children diagnosed with or at risk of ADPKD are lacking. Also, scoring systems to stratify patients into risk categories have been established only for adults. Overall, there are insufficient data on the clinical course during childhood. We therefore initiated the global ADPedKD project to establish a large international pediatric ADPKD cohort for deep characterization. METHODS: Global ADPedKD is an international multicenter observational study focusing on childhood-diagnosed ADPKD. This collaborative project is based on interoperable Web-based databases, comprising 7 regional and independent but uniformly organized chapters, namely Africa, Asia, Australia, Europe, North America, South America, and the United Kingdom. In the database, a detailed basic data questionnaire, including genetics, is used in combination with data entry from follow-up visits, to provide both retrospective and prospective longitudinal data on clinical, radiologic, and laboratory findings, as well as therapeutic interventions. DISCUSSION: The global ADPedKD initiative aims to characterize in detail the most extensive international pediatric ADPKD cohort reported to date, providing evidence for the development of unified diagnostic, follow-up, and treatment recommendations regarding modifiable disease factors. Moreover, this registry will serve as a platform for the development of clinical and/or biochemical markers predicting the risk of early and progressive disease.

Published
2019

7. RENAL DEVELOPMENT AND CYSTIC DISEASES

Author

Cabrera-Lopez, C., primary, Ars, E., additional, Marti, T., additional, Harris, P. C., additional, Torra, R., additional, Clerckx, C., additional, Migeon, T., additional, Chen, Z., additional, Ronco, P., additional, Plaisier, E., additional, Lamers, I. J., additional, Van Reeuwijk, J., additional, Azam, M., additional, Boldt, K., additional, Maria, M., additional, Koster-Kamphuis, L., additional, Qamar, R., additional, Ueffing, M., additional, Cremers, F. P., additional, Roepman, R., additional, Arts, H. H., additional, Papizh, S., additional, Dlin, V., additional, Leontieva, I., additional, Tutelman, K., additional, Perrone, R. D., additional, Bae, K. T., additional, Chapman, A. B., additional, Devuyst, O., additional, Gansevoort, R. T., additional, Grantham, J. J., additional, Higashihara, E., additional, Torres, V. E., additional, Sergeyeva, O., additional, Zhou, W., additional, Blais, J. D., additional, Czerwiec, F. S., additional, Liu, F., additional, Liao, Y., additional, Fu, P., additional, Casteleijn, N., additional, Zittema, D., additional, Bakker, S., additional, Boertien, W., additional, Gaillard, C., additional, Meijer, E., additional, Spithoven, E., additional, Struck, J., additional, Gansevoort, R., additional, Robinson, P., additional, McEwan, P., additional, Hadimeri, H., additional, Ong, A. C. M., additional, Orskov, B., additional, Peces, R., additional, Sandford, R., additional, Scolari, F., additional, Walz, G., additional, Cooke, C., additional, O'Reilly, K., additional, Riwanto, M., additional, Kapoor, S., additional, Rodriguez, D., additional, Edenhofer, I., additional, Segerer, S., additional, Wuthrich, R. P., additional, De Rechter, S., additional, Bacchetta, J., additional, Van Dyck, M., additional, Evenepoel, P., additional, De Schepper, J., additional, Levtchenko, E., additional, Mekahli, D., additional, Carr, A., additional, Makin, A., additional, Baker, A., additional, Obeidova, L., additional, Stekrova, J., additional, Seeman, T., additional, Puchmajerova, A., additional, Reiterova, J., additional, Kohoutova, M., additional, Tesar, V., additional, Treille, S., additional, Bailly, J.-M., additional, Guillaume, B., additional, Tuta, L., additional, Stanigut, A., additional, Botea, F., additional, Jo, H. A., additional, Park, H. C., additional, Kim, H., additional, Han, M., additional, Huh, H., additional, Jeong, J. C., additional, Oh, K.-H., additional, Yang, J., additional, Koo, T. Y., additional, Hwang, Y.-H., additional, Ahn, C., additional, Pisani, A., additional, Remuzzi, G., additional, Ruggenenti, P., additional, Riccio, E., additional, Visciano, B., additional, Spinelli, L., additional, Kim, J. I., additional, Park, K. M., additional, Liu, F. X., additional, Rutherford, P., additional, Smoyer-Tomic, K., additional, Martinez Jimenez, V., additional, Comas, J., additional, Arcos, E., additional, Diaz, J. M., additional, Muray, S., additional, Cabezuelo, J., additional, Ballarin, J., additional, Miyaoka, T., additional, Morimoto, S., additional, Kataoka, H., additional, Mochizuki, T., additional, Tsuchiya, K., additional, Ichihara, A., additional, and Nitta, K., additional

Published
2014
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8. ADPedKD : a global online platform on the management of children with ADPKD

Author

Stéphanie De Rechter, Detlef Bockenhauer, Lisa M. Guay-Woodford, Isaac Liu, Andrew J. Mallett, Neveen A. Soliman, Lucimary C. Sylvestre, Franz Schaefer, Max C. Liebau, Djalila Mekahli, P. Adamczyk, N. Akinci, H. Alpay, C. Ardelean, N. Ayasreh, Z. Aydin, A. Bael, V. Baudouin, U.S. Bayrakci, A. Bensman, H. Bialkevich, A. Biebuyck, O. Boyer, O. Bjanid, A. Bryłka, S. Çalışkan, A. Cambier, A. Camelio, V. Carbone, M. Charbit, B. Chiodini, A. Chirita, N. Çiçek, R. Cerkauskiene, L. Collard, M. Conceiçao, I. Constantinescu, A. Couderc, B. Crapella, M. Cvetkovic, B. Dima, F. Diomeda, M. Docx, N. Dolan, C. Dossier, D. Drozdz, J. Drube, O. Dunand, P. Dusan, L.A. Eid, F. Emma, M. Espino Hernandez, M. Fila, M. Furlano, M. Gafencu, M.S. Ghuysen, M. Giani, M. Giordano, I. Girisgen, N. Godefroid, A. Godron-Dubrasquet, I. Gojkovic, E. Gonzalez, I. Gökçe, J.W. Groothoff, S. Guarino, A. Guffens, P. Hansen, J. Harambat, S. Haumann, G. He, L. Heidet, R. Helmy, F. Hemery, N. Hooman, B. llanas, A. Jankauskiene, P. Janssens, S. Karamaria, I. Kazyra, J. Koenig, S. Krid, P. Krug, V. Kwon, A. La Manna, V. Leroy, M. Litwin, J. Lombet, G. Longo, A.C. Lungu, A. Mallawaarachchi, A. Marin, P. Marzuillo, L. Massella, A. Mastrangelo, H. McCarthy, M. Miklaszewska, A. Moczulska, G. Montini, A. Morawiec-Knysak, D. Morin, L. Murer, I. Negru, F. Nobili, L. Obrycki, H. Otoukesh, S. Özcan, L. Pape, S. Papizh, P. Parvex, M. Pawlak-Bratkowska, L. Prikhodina, A. Prytula, C. Quinlan, A. Raes, B. Ranchin, N. Ranguelov, R. Repeckiene, C. Ronit, R. Salomon, R. Santagelo, S.K. Saygılı, S. Schaefer, M. Schreuder, T. Schurmans, T. Seeman, N. Segers, M. Sinha, E. Snauwaert, B. Spasojevic, S. Stabouli, C. Stoica, R. Stroescu, E. Szczepanik, M. Szczepańska, K. Taranta-Janusz, A. Teixeira, J. Thumfart, M. Tkaczyk, R. Torra, D. Torres, N. Tram, B. Utsch, J. Vande Walle, R. Vieux, R. Vitkevic, A. Wilhelm-Bals, E. Wühl, Z.Y. Yildirim, S. Yüksel, K. Zachwieja, Clinical sciences, Faculty of Medicine and Pharmacy, Internal Medicine Specializations, Nephrology, İÜC, AGEM - Amsterdam Gastroenterology Endocrinology Metabolism, ARD - Amsterdam Reproduction and Development, Paediatric Nephrology, AGEM - Inborn errors of metabolism, APH - Quality of Care, APH - Methodology, De Rechter, S., Bockenhauer, D., Guay-Woodford, L. M., Liu, I., Mallett, A. J., Soliman, N. A., Sylvestre, L. C., Schaefer, F., Liebau, M. C., Mekahli, D., Adamczyk, P., Akinci, N., Alpay, H., Ardelean, C., Ayasreh, N., Aydin, Z., Bael, A., Baudouin, V., Bayrakci, U. S., Bensman, A., Bialkevich, H., Biebuyck, A., Boyer, O., Bjanid, O., Brylka, A., Caliskan, S., Cambier, A., Camelio, A., Carbone, V., Charbit, M., Chiodini, B., Chirita, A., Cicek, N., Cerkauskiene, R., Collard, L., Conceicao, M., Constantinescu, I., Couderc, A., Crapella, B., Cvetkovic, M., Dima, B., Diomeda, F., Docx, M., Dolan, N., Dossier, C., Drozdz, D., Drube, J., Dunand, O., Dusan, P., Eid, L. A., Emma, F., Espino Hernandez, M., Fila, M., Furlano, M., Gafencu, M., Ghuysen, M. S., Giani, M., Giordano, M., Girisgen, I., Godefroid, N., Godron-Dubrasquet, A., Gojkovic, I., Gonzalez, E., Gokce, I., Groothoff, J. W., Guarino, S., Guffens, A., Hansen, P., Harambat, J., Haumann, S., He, G., Heidet, L., Helmy, R., Hemery, F., Hooman, N., Llanas, B., Jankauskiene, A., Janssens, P., Karamaria, S., Kazyra, I., Koenig, J., Krid, S., Krug, P., Kwon, V., La Manna, A., Leroy, V., Litwin, M., Lombet, J., Longo, G., Lungu, A. C., Mallawaarachchi, A., Marin, A., Marzuillo, P., Massella, L., Mastrangelo, A., Mccarthy, H., Miklaszewska, M., Moczulska, A., Montini, G., Morawiec-Knysak, A., Morin, D., Murer, L., Negru, I., Nobili, F., Obrycki, L., Otoukesh, H., Ozcan, S., Pape, L., Papizh, S., Parvex, P., Pawlak-Bratkowska, M., Prikhodina, L., Prytula, A., Quinlan, C., Raes, A., Ranchin, B., Ranguelov, N., Repeckiene, R., Ronit, C., Salomon, R., Santagelo, R., Saygili, S. K., Schaefer, S., Schreuder, M., Schurmans, T., Seeman, T., Segers, N., Sinha, M., Snauwaert, E., Spasojevic, B., Stabouli, S., Stoica, C., Stroescu, R., Szczepanik, E., Szczepanska, M., Taranta-Janusz, K., Teixeira, A., Thumfart, J., Tkaczyk, M., Torra, R., Torres, D., Tram, N., Utsch, B., Vande Walle, J., Vieux, R., Vitkevic, R., Wilhelm-Bals, A., Wuhl, E., Yildirim, Z. Y., Yuksel, S., Zachwieja, K., UCL - SSS/IREC/PEDI - Pôle de Pédiatrie, UCL - (SLuc) Service de pédiatrie générale, Parvex, Paloma Maria, Gonzalez, Elsa, Wilhelm-Bals, Alexandra, Amsterdam Reproduction & Development (AR&D), De Rechter, Stephanie, Bockenhauer, Detlef, Guay-Woodford, Lisa M., Liu, Isaac, Mallett, Andrew J., Soliman, Neveen A., Sylvestre, Lucimary C., Schaefer, Franz, Liebau, Max C., Mekahli, Djalila, Baudouin, V, Carbone, V, Constantinescu, I, Ghuysen, Ms, Girisgen, I, Gojkovic, I, Gokce, I, Ilanas, B., Kazyra, I, Kwon, V, Leroy, V, McCarthy, H., Negru, I, and Wuehl, E.

Subjects
medicine.medical_specialty, ADPKD, ADPedKD Registry, children, longitudinal, 030232 urology & nephrology, Autosomal dominant polycystic kidney disease, Psychological intervention, CHILDHOOD, BLOOD-PRESSURE, PROGRESSION, Disease, 030204 cardiovascular system & hematology, urologic and male genital diseases, lcsh:RC870-923, Disease course, CARDIOVASCULAR-ABNORMALITIES, 03 medical and health sciences, 0302 clinical medicine, Clinical Research, LEFT-VENTRICULAR MASS, Medicine and Health Sciences, Medicine, Children, DISEASE ADPKD, DOMINANT POLYCYSTIC KIDNEY, SPECTRUM, Science & Technology, ddc:618, business.industry, urogenital system, Urology & Nephrology, medicine.disease, lcsh:Diseases of the genitourinary system. Urology, female genital diseases and pregnancy complications, 3. Good health, Disease factors, Nephrology, Family medicine, Cohort, RENAL CONCENTRATING CAPACITY, VOLUME, Observational study, business, Life Sciences & Biomedicine, Progressive disease
Abstract

Background: Autosomal dominant polycystic kidney disease (ADPKD) is the most common monogenic cause of renal failure. For several decades, ADPKD was regarded as an adult-onset disease. In the past decade, it has become more widely appreciated that the disease course begins in childhood. However, evidence-based guidelines on how to manage and approach children diagnosed with or at risk of ADPKD are lacking. Also, scoring systems to stratify patients into risk categories have been established only for adults. Overall, there are insufficient data on the clinical course during childhood. We therefore initiated the global ADPedKD project to establish a large international pediatric ADPKD cohort for deep characterization., Methods: Global ADPedKD is an international multicenter observational study focusing on childhood-diagnosed ADPKD. This collaborative project is based on interoperable Web-based databases, comprising 7 regional and independent but uniformly organized chapters, namely Africa, Asia, Australia, Europe, North America, South America, and the United Kingdom. In the database, a detailed basic data questionnaire, including genetics, is used in combination with data entry from follow-up visits, to provide both retrospective and prospective longitudinal data on clinical, radiologic, and laboratory findings, as well as therapeutic interventions., Discussion: The global ADPedKD initiative aims to characterize in detail the most extensive international pediatric ADPKD cohort reported to date, providing evidence for the development of unified diagnostic, follow-up, and treatment recommendations regarding modifiable disease factors. Moreover, this registry will serve as a platform for the development of clinical and/or biochemical markers predicting the risk of early and progressive disease., C1 [De Rechter, Stephanie; Mekahli, Djalila] Univ Hosp Leuven, Dept Pediat Nephrol, Herestr 49, B-3000 Leuven, Belgium., [De Rechter, Stephanie; Mekahli, Djalila] Katholieke Univ Leuven, Dept Dev & Regenerat, PKD Res Grp, Leuven, Belgium., [Bockenhauer, Detlef] UCL Ctr Nephrol, London, England., [Bockenhauer, Detlef] Great Ormond St Hosp NHS Fdn Trust, London, England., [Guay-Woodford, Lisa M.] Childrens Natl Hlth Syst, Ctr Translat Sci, Washington, DC USA., [Liu, Isaac] Natl Univ Hlth Syst, Khoo Teck Puat Natl Univ, Childrens Med Inst, Singapore, Singapore., [Mallett, Andrew J.] Royal Brisbane & Womens Hosp, Kidney Hlth Serv, Brisbane, Qld, Australia., [Mallett, Andrew J.] Royal Brisbane & Womens Hosp, Conjoint Renal Res Lab, Brisbane, Qld, Australia., [Mallett, Andrew J.] Univ Queensland, Fac Med, Brisbane, Qld, Australia., [Mallett, Andrew J.] Univ Queensland, Inst Mol Biosci, Brisbane, Qld, Australia., [Mallett, Andrew J.] KidGen Collaborat & Australian Genom Hlth Allianc, Melbourne, Vic, Australia., [Soliman, Neveen A.] Cairo Univ, Ctr Pediat Nephrol & Transplantat, Kasr Al Ainy Sch Med, Dept Pediat, Cairo, Egypt., [Sylvestre, Lucimary C.] Hosp Pequeno Principe, Curitiba, Parana, Brazil., [Schaefer, Franz] Heidelberg Univ, Ctr Pediat & Adolescent Med, Div Pediat Nephrol, Med Ctr, Heidelberg, Germany., [Liebau, Max C.] Univ Hosp Cologne, Dept Pediat, Cologne, Germany., [Liebau, Max C.] Univ Hosp Cologne, Ctr Mol Med, Cologne, Germany., [Adamczyk, P.; Bjanid, O.; Brylka, A.; Morawiec-Knysak, A.; Szczepanska, M.] Dept Pediat, Zabrze, Poland., [Akinci, N.] Sariyer SISLI Hamidiye Etfal Res & Educ Hosp, Istanbul, Turkey., [Alpay, H.; Cicek, N.; Gokce, I] Marmara Univ, Sch Med, Div Pediat Nephrol, Istanbul, Turkey., [Ardelean, C.; Chirita, A.; Gafencu, M.; Stroescu, R.] Timisoara Children Hosp, Timisoara, Romania., [Ayasreh, N.; Furlano, M.; Torra, R.] Fundacio Puigvert, Barcelona, Spain., [Aydin, Z.; Bayrakci, U. S.] Ankara Univ Hlth Sci, Child Hlth & Dis, Ankara, Turkey., [Bael, A.; Docx, M.; Segers, N.] Koningin Paola Kinderziekenhuis Antwerpen, Antwerp, Belgium., [Baudouin, V; Cambier, A.; Couderc, A.; Dossier, C.; Kwon, V] Hop Robert Debre, AP HP, Paris, France., [Bensman, A.; Biebuyck, A.; Boyer, O.; Charbit, M.; Heidet, L.; Krid, S.; Krug, P.; Salomon, R.] Pediat Nephrol Necker Hosp, Paris, France., [Bialkevich, H.; Kazyra, I] 2nd City Childrens Clin Hosp, Natl Ctr Pediat Nephrol & RRT, Minsk, BELARUS., [Caliskan, S.; Ozcan, S.; Saygili, S. K.] Istanbul Cerrahpasa Fac Med, Istanbul, Turkey., [Camelio, A.; Nobili, F.; Vieux, R.] CHU Besancon, Besancon, France., [Carbone, V; Diomeda, F.; Torres, D.] Pediat Nephrol Unit Bari, Bari, Italy., [Chiodini, B.] HUDERF, Brussels, Belgium., [Collard, L.] CHR La Citadelle, Liege, Belgium., [Conceicao, M.; Teixeira, A.] Ctr Hosp Porto, Ctr Materno Infantil Norte, Porto, Portugal., [Constantinescu, I; Lungu, A. C.; Marin, A.; Negru, I; Stroescu, R.] Fundeni Clin Inst, Bucharest, Romania., [Crapella, B.; Giani, M.; Mastrangelo, A.; Montini, G.] Fdn IRCCS Ca Granda, Pediat Nephrol Dialysis & Transplant Unit, Milan, Italy., [Cvetkovic, M.; Gojkovic, I] Univ Childrens Hosp, Belgrade, Serbia., [Dima, B.] Clin Europe Hop St Elisabeth, Brussels, Belgium., [Dolan, N.] Our Ladys Childrens Hosp, Dublin, Ireland., [Drozdz, D.; Miklaszewska, M.; Zachwieja, K.] Jagiellonian Univ, Med Coll Cracow, Pediat Nephrol & Hypertens, Krakow, Poland., [Drube, J.; Pape, L.] Hannover Med Sch, Hannover, Germany., [Dunand, O.; Leroy, V] Pediat Nephrol Unit St Denis, St Denis, Reunion, France., [Dusan, P.; Spasojevic, B.; Stabouli, S.] Aristotle Univ Thessaloniki, Dept Pediat, Thessaloniki, Greece., [Eid, L. A.] Dubai Hosp, Pediat Nephrol Dept, Dubai, U Arab Emirates., [Emma, F.; Massella, L.] Bambino Gesu Pediat Hosp, Rome, Italy., [Espino Hernandez, M.] Hosp Infantil 12 Octubre Madrid, Madrid, Spain., [Fila, M.; Hemery, F.; Morin, D.] CHU Arnaud Villeneuve, Montpellier, France., [Ghuysen, Ms] CHU Liege, Liege, Belgium., [Giordano, M.] Pediat Nephrol Unit, Bari, Italy., [Girisgen, I; Yuksel, S.] Pamukkale Univ, Med Fac, Dept Pediat Nephrol, Denizli, Turkey., [Godefroid, N.; Ranguelov, N.] Clin Univ St Luc, Brussels, Belgium., [Godron-Dubrasquet, A.; Harambat, J.; Ilanas, B.] Bordeaux Univ Childrens Hosp, Bordeaux, France., [Gonzalez, E.] Childrens Univ Hosp, Geneva, Switzerland., [Groothoff, J. W.] Emma Childrens Hosp, Amsterdam, Netherlands., [Guarino, S.; La Manna, A.; Marzuillo, P.] Univ Campania Luigi Vanvitelli, Caserta, Italy., [Guffens, A.] CHC Clin Esperence, Montegnee, Belgium., [Hansen, P.] CHU Tivoli, La Louviere, Belgium., [Haumann, S.] Univ Klinikum Koln, Cologne, Germany., [He, G.] Foshan Women & Children Hosp, Foshan, Peoples R China., [Helmy, R.] Cairo Univ, Kasr Al Ainy Sch Med, Cairo, Egypt., [Hooman, N.; Otoukesh, H.] Iran Univ Med Sci, Aliasghar Clin Res Dev Unit, Tehran, Iran., [Janssens, P.] Univ Hosp Brussels, Brussels, Belgium., [Karamaria, S.; Prytula, A.; Raes, A.; Snauwaert, E.; Vande Walle, J.] UZ Gent, Ghent, Belgium., [Koenig, J.] Univ Hosp Muenster, Munster, Germany., [Litwin, M.; Obrycki, L.] Childrens Mem Hlth Inst, Warsaw, Poland., [Lombet, J.] CHR Citadelle, Liege, Belgium., [Longo, G.; Murer, L.] Hosp Univ Padova, Pediat Nephrol Dialysis & Transplant Unit, Padua, Italy., [Mallawaarachchi, A.] Garvan Inst, Darlinghurst, NSW, Australia., [Mallawaarachchi, A.] Royal Prince Alfred Hosp, Camperdown, NSW, Australia., [Mallawaarachchi, A.; McCarthy, H.; Quinlan, C.] KidGen, Sydney, NSW, Australia., [McCarthy, H.] Childrens Hosp Westmead, Westmead, NSW, Australia., [McCarthy, H.] Sydney Childrens Hosp, Sydney, NSW, Australia., [Papizh, S.; Prikhodina, L.] Pirogov Russian Nat Res Med Uni, Res & Clin Inst Pediat, Moscow, Russia., [Parvex, P.; Wilhelm-Bals, A.] Childrens Univ Hosp Geneva, Geneva, Switzerland., [Pawlak-Bratkowska, M.; Szczepanik, E.; Tkaczyk, M.] Polish Mothers Mem Hosp, Res Inst, Lodz, Poland., [Quinlan, C.] RCH Melbourne, Melbourne, Vic, Australia., [Ranchin, B.] Hop Femme Mere Enfant, Bron, France., [Ronit, C.] Ctr Hosp Luxembourg, Clin Pediat, Luxembourg, Luxembourg., [Schaefer, S.; Wuehl, E.] Ctr Pediat & Adolescent, Div Pediat Nephrol, Heidelberg, Germany., [Schreuder, M.] Radboudumc Amalia Childrens Hosp, Nijmegen, Netherlands., [Schurmans, T.; Tram, N.] CHU Charleroi, Charleroi, Belgium., [Seeman, T.] Charles Univ Prague, Prague, Czech Republic., [Seeman, T.] Motol Univ Hosp, Prague, Czech Republic., [Sinha, M.] Evelina London Childrens Hosp, London, England., [Taranta-Janusz, K.] Dept Pediat & Nephrol, Bialystok, Poland., [Thumfart, J.] Berlin Charite Univ Med, Berlin, Germany., [Utsch, B.] Herford Hosp, Dept Paediat, Herford, Germany., [Yildirim, Z. Y.] Istanbul Univ, Fac Med, Pediat Nephrol Dept, Istanbul, Turkey.

Published
2019

9. Antibiotic Prophylaxis in Infants with Grade III, IV, or V Vesicoureteral Reflux.

Author

Morello W, Baskin E, Jankauskiene A, Yalcinkaya F, Zurowska A, Puccio G, Serafinelli J, La Manna A, Krzemień G, Pennesi M, La Scola C, Becherucci F, Brugnara M, Yuksel S, Mekahli D, Chimenz R, De Palma D, Zucchetta P, Vajauskas D, Drozdz D, Szczepanska M, Caliskan S, Lombet J, Minoli DG, Guarino S, Gulleroglu K, Ruzgiene D, Szmigielska A, Barbi E, Ozcakar ZB, Kranz A, Pasini A, Materassi M, De Rechter S, Ariceta G, Weber LT, Marzuillo P, Alberici I, Taranta-Janusz K, Caldas Afonso A, Tkaczyk M, Català M, Cabrera Sevilla JE, Mehls O, Schaefer F, and Montini G

Subjects
Female, Humans, Infant, Male, Glomerulonephritis, Intention to Treat Analysis, Drug Resistance, Bacterial drug effects, Antibiotic Prophylaxis adverse effects, Antibiotic Prophylaxis methods, Vesico-Ureteral Reflux complications, Vesico-Ureteral Reflux drug therapy, Anti-Bacterial Agents administration & dosage, Anti-Bacterial Agents adverse effects, Anti-Bacterial Agents therapeutic use, Urinary Tract Infections etiology, Urinary Tract Infections microbiology, Urinary Tract Infections prevention & control
Abstract

Background: The efficacy of continuous antibiotic prophylaxis in preventing urinary tract infection (UTI) in infants with grade III, IV, or V vesicoureteral reflux is controversial., Methods: In this investigator-initiated, randomized, open-label trial performed in 39 European centers, we randomly assigned infants 1 to 5 months of age with grade III, IV, or V vesicoureteral reflux and no previous UTIs to receive continuous antibiotic prophylaxis (prophylaxis group) or no treatment (untreated group) for 24 months. The primary outcome was the occurrence of the first UTI during the trial period. Secondary outcomes included new kidney scarring and the estimated glomerular filtration rate (GFR) at 24 months., Results: A total of 292 participants underwent randomization (146 per group). Approximately 75% of the participants were male; the median age was 3 months, and 235 participants (80.5%) had grade IV or V vesicoureteral reflux. In the intention-to-treat analysis, a first UTI occurred in 31 participants (21.2%) in the prophylaxis group and in 52 participants (35.6%) in the untreated group (hazard ratio, 0.55; 95% confidence interval [CI], 0.35 to 0.86; P = 0.008); the number needed to treat for 2 years to prevent one UTI was 7 children (95% CI, 4 to 29). Among untreated participants, 64.4% had no UTI during the trial. The incidence of new kidney scars and the estimated GFR at 24 months did not differ substantially between the two groups. Pseudomonas species, other non- Escherichia coli organisms, and antibiotic resistance were more common in UTI isolates obtained from participants in the prophylaxis group than in isolates obtained from those in the untreated group. Serious adverse events were similar in the two groups., Conclusions: In infants with grade III, IV, or V vesicoureteral reflux and no previous UTIs, continuous antibiotic prophylaxis provided a small but significant benefit in preventing a first UTI despite an increased occurrence of non- E. coli organisms and antibiotic resistance. (Funded by the Italian Ministry of Health and others; PREDICT ClinicalTrials.gov number, NCT02021006; EudraCT number, 2013-000309-21.)., (Copyright © 2023 Massachusetts Medical Society.)

Published
2023
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10. Low agreement between various eGFR formulae in pediatric and young adult ADPKD patients.

Author

Schellekens P, Verjans M, Janssens P, Dachy A, De Rechter S, Breysem L, Allegaert K, Bammens B, Vennekens R, Vermeersch P, Pottel H, and Mekahli D

Subjects
Humans, Child, Female, Male, Young Adult, Infant, Newborn, Infant, Child, Preschool, Adolescent, Adult, Glomerular Filtration Rate, Longitudinal Studies, Prospective Studies, Creatinine, Polycystic Kidney, Autosomal Dominant diagnosis, Polycystic Kidney, Autosomal Dominant genetics, Transition to Adult Care, Renal Insufficiency, Chronic
Abstract

Background: Young autosomal dominant polycystic kidney disease (ADPKD) patients are becoming the new target population for the development of new treatment options. Determination of a reliable equation for estimated glomerular filtration rate (eGFR) from early stages is needed with the promising potential interventional therapies., Methods: Prospective and longitudinal study on a cohort of 68 genotyped ADPKD patients (age range 0-23 years) with long-term follow-up. Commonly used equations for eGFR were compared for their relative performance., Results: The revised Schwartz formula (CKiD) showed a highly significant decline in eGFR with aging (- 3.31 mL/min/1.73 m 2 /year, P < 0.0001). The recently updated equation by the Schwartz group (CKiDU25) showed a smaller (- 0.90 mL/min/1.73 m 2 /year) but significant (P = 0.001) decline in eGFR with aging and also showed a significant sex difference (P < 0.0001), not observed by the other equations. In contrast, the full age spectrum (FAS) equations (FAS-SCr, FAS-CysC, and the combined) showed no age and sex dependency. The prevalence of hyperfiltration is highly dependent on the formula used, and the highest prevalence was observed with the CKiD Equation (35%)., Conclusions: The most widely used methods to calculate eGFR in ADPKD children (CKiD and CKiDU25 equations) were associated with unexpected age or sex differences. The FAS equations were age- and sex-independent in our cohort. Hence, the switch from the CKiD to CKD-EPI equation at the transition from pediatric to adult care causes implausible jumps in eGFR, which could be misinterpreted. Having reliable methods to calculate eGFR is indispensable for clinical follow-up and clinical trials. A higher resolution version of the Graphical abstract is available as Supplementary information., (© 2023. The Author(s), under exclusive licence to International Pediatric Nephrology Association.)

Published
2023
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11. Risk Severity Model for Pediatric Autosomal Dominant Polycystic Kidney Disease Using 3D Ultrasound Volumetry.

Author

Breysem L, De Keyzer F, Schellekens P, Dachy A, De Rechter S, Janssens P, Vennekens R, Bammens B, Irazabal MV, Van Ongeval C, Harris PC, and Mekahli D

Subjects
Humans, Female, Male, Child, Prospective Studies, Child, Preschool, Adolescent, Infant, Kidney diagnostic imaging, Kidney pathology, Organ Size, Risk Assessment, TRPP Cation Channels genetics, Infant, Newborn, Disease Progression, Predictive Value of Tests, Polycystic Kidney, Autosomal Dominant diagnostic imaging, Polycystic Kidney, Autosomal Dominant pathology, Imaging, Three-Dimensional, Severity of Illness Index, Ultrasonography
Abstract

Background: Height-adjusted total kidney volume (htTKV) measured by imaging defined as Mayo Imaging Class (MIC) is a validated prognostic measure for autosomal dominant polycystic kidney disease (ADPKD) in adults to predict and stratify disease progression. However, no stratification tool is currently available in pediatric ADPKD. Because magnetic resonance imaging and computed tomography in children are difficult, we propose a novel 3D ultrasound-based pediatric Leuven Imaging Classification to complement the MIC., Methods: A prospective study cohort of 74 patients with genotyped ADPKD (37 female) was followed longitudinally with ultrasound, including 3D ultrasound, and they underwent in total 247 3D ultrasound assessments, with patients' median age (interquartile range [IQR]) at diagnosis of 3 (IQR, 0-9) years and at first 3D ultrasound evaluation of 10 (IQR, 5-14) years. First, data matching was done to the published MIC classification, followed by subsequent optimization of parameters and model type., Results: PKD1 was confirmed in 70 patients (95%), PKD2 in three (4%), and glucosidase IIα unit only once (1%). Over these 247 evaluations, the median height was 143 (IQR, 122-166) cm and total kidney volume was 236 (IQR, 144-344) ml, leading to an htTKV of 161 (IQR, 117-208) ml/m. Applying the adult Mayo classification in children younger than 15 years strongly underestimated ADPKD severity, even with correction for height. We therefore optimized the model with our pediatric data and eventually validated it with data of young patients from Mayo Clinic and the Consortium for Radiologic Imaging Studies of Polycystic Kidney Disease used to establish the MIC., Conclusions: We proposed a five-level Leuven Imaging Classification ADPKD pediatric model as a novel classification tool on the basis of patients' age and 3D ultrasound-htTKV for reliable discrimination of childhood ADPKD severity., (Copyright © 2023 by the American Society of Nephrology.)

Published
2023
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13. Enhanced MCP-1 Release in Early Autosomal Dominant Polycystic Kidney Disease.

Author

Janssens P, Decuypere JP, De Rechter S, Breysem L, Van Giel D, Billen J, Hindryckx A, De Catte L, Baldewijns M, Claes KBM, Wissing KM, Devriendt K, Bammens B, Meyts I, Torres VE, Vennekens R, and Mekahli D

Abstract

Introduction: Autosomal dominant polycystic kidney disease (ADPKD) causes kidney failure typically in adulthood, but the disease starts in utero . Copeptin, epidermal growth factor (EGF), and monocyte chemoattractant protein-1 (MCP-1) are associated with severity and hold prognostic value in adults but remain unstudied in the early disease stage. Kidneys from adults with ADPKD exhibit macrophage infiltration, and a prominent role of MCP-1 secretion by tubular epithelial cells is suggested from rodent models., Methods: In a cross-sectional study, plasma copeptin, urinary EGF, and urinary MCP-1 were evaluated in a pediatric ADPKD cohort and compared with age-, sex-, and body mass index (BMI)-matched healthy controls. MCP-1 was studied in mouse collecting duct cells, human proximal tubular cells, and fetal kidney tissue., Results: Fifty-three genotyped ADPKD patients and 53 controls were included. The mean (SD) age was 10.4 (5.9) versus 10.5 (6.1) years ( P  = 0.543), and the estimated glomerular filtration rate (eGFR) was 122.7 (39.8) versus 114.5 (23.1) ml/min per 1.73 m 2 ( P  = 0.177) in patients versus controls, respectively. Plasma copeptin and EGF secretion were comparable between groups. The median (interquartile range) urinary MCP-1 (pg/mg creatinine) was significantly higher in ADPKD patients (185.4 [213.8]) compared with controls (154.7 [98.0], P  = 0.010). Human proximal tubular cells with a heterozygous PKD1 mutation and mouse collecting duct cells with a PKD1 knockout exhibited increased MCP-1 secretion. Human fetal ADPKD kidneys displayed prominent MCP-1 immunoreactivity and M2 macrophage infiltration., Conclusion: An increase in tubular MCP-1 secretion is an early event in ADPKD. MCP-1 is an early disease severity marker and a potential treatment target., (© 2021 International Society of Nephrology. Published by Elsevier Inc.)

Published
2021
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14. ADPedKD: A Global Online Platform on the Management of Children With ADPKD.

Author

De Rechter S, Bockenhauer D, Guay-Woodford LM, Liu I, Mallett AJ, Soliman NA, Sylvestre LC, Schaefer F, Liebau MC, and Mekahli D

Abstract

Background: Autosomal dominant polycystic kidney disease (ADPKD) is the most common monogenic cause of renal failure. For several decades, ADPKD was regarded as an adult-onset disease. In the past decade, it has become more widely appreciated that the disease course begins in childhood. However, evidence-based guidelines on how to manage and approach children diagnosed with or at risk of ADPKD are lacking. Also, scoring systems to stratify patients into risk categories have been established only for adults. Overall, there are insufficient data on the clinical course during childhood. We therefore initiated the global ADPedKD project to establish a large international pediatric ADPKD cohort for deep characterization., Methods: Global ADPedKD is an international multicenter observational study focusing on childhood-diagnosed ADPKD. This collaborative project is based on interoperable Web-based databases, comprising 7 regional and independent but uniformly organized chapters, namely Africa, Asia, Australia, Europe, North America, South America, and the United Kingdom. In the database, a detailed basic data questionnaire, including genetics, is used in combination with data entry from follow-up visits, to provide both retrospective and prospective longitudinal data on clinical, radiologic, and laboratory findings, as well as therapeutic interventions., Discussion: The global ADPedKD initiative aims to characterize in detail the most extensive international pediatric ADPKD cohort reported to date, providing evidence for the development of unified diagnostic, follow-up, and treatment recommendations regarding modifiable disease factors. Moreover, this registry will serve as a platform for the development of clinical and/or biochemical markers predicting the risk of early and progressive disease.

Published
2019
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15. Unmet needs and challenges for follow-up and treatment of autosomal dominant polycystic kidney disease: the paediatric perspective.

Author

De Rechter S, Bammens B, Schaefer F, Liebau MC, and Mekahli D

Abstract

Awareness is growing that the clinical course of autosomal dominant polycystic kidney disease (ADPKD) already begins in childhood, with a broad range of both symptomatic and asymptomatic features. Knowing that parenchymal destruction with cyst formation and growth starts early in life, it seems reasonable to assume that early intervention may yield the best chances for preserving renal outcome. Interventions may involve lifestyle modifications, hypertension control and the use of disease-modifying treatments once these become available for the paediatric population with an acceptable risk and side-effect profile. Until then, screening of at-risk children is controversial and not generally recommended since this might cause psychosocial and financial harm. Also, the clinical and research communities are facing important questions as to the nature of potential interventions and their optimal indications and timing. Indeed, challenges include the identification and validation of indicators, both measuring and predicting disease progression from childhood, and the discrimination of slow from rapid progressors in the paediatric population. This discrimination will improve both the cost-effectiveness and benefit-to-risk ratio of therapies. Furthermore, we will need to define outcome measures, and to evaluate the possibility of a potential therapeutic window of opportunity in childhood. The recently established international register ADPedKD will help in elucidating these questions. In this review, we provide an overview of the current knowledge on paediatric ADPKD as a future therapeutic target population and its unmet challenges.

Published
2018
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16. Renal progression factors in young patients with tuberous sclerosis complex: a retrospective cohort study.

Author

Janssens P, Van Hoeve K, De Waele L, De Rechter S, Claes KJ, Van de Perre E, Wissing KM, Bammens B, Jansen A, and Mekahli D

Subjects
Adolescent, Adult, Aged, Angiomyolipoma epidemiology, Angiomyolipoma etiology, Angiomyolipoma pathology, Child, Child, Preschool, Disease Progression, Female, Follow-Up Studies, Glomerular Filtration Rate, Humans, Hypertension epidemiology, Hypertension etiology, Hypertension pathology, Infant, Infant, Newborn, Kidney pathology, Kidney Diseases, Cystic epidemiology, Kidney Diseases, Cystic etiology, Kidney Diseases, Cystic pathology, Kidney Failure, Chronic etiology, Kidney Failure, Chronic pathology, Kidney Neoplasms epidemiology, Kidney Neoplasms etiology, Kidney Neoplasms pathology, Male, Middle Aged, Prevalence, Proteinuria epidemiology, Proteinuria etiology, Proteinuria pathology, Retrospective Studies, Risk Factors, Young Adult, Kidney Failure, Chronic epidemiology, Tuberous Sclerosis complications
Abstract

Background: Renal pathology in tuberous sclerosis complex (TSC) is characterized by the growth of angiomyolipoma and renal cysts, and in rare cases renal cell carcinoma. Other consequences of renal involvement in TSC, including hypertension, proteinuria, and hyperfiltration, are not well studied. We aimed to analyze the early manifestations of the renal TSC phenotype in a young TSC cohort and to explore common, modifiable risk factors., Methods: In this retrospective cohort study, TSC patients attending the TSC clinics of two tertiary hospitals were included. Data on demographics, history, genotype, kidney function, hematuria, proteinuria, blood pressure, and renal imaging were collected., Results: Eighty patients were included, with a median age of 0.8 years (0.0-63.0) at first presentation, and a median follow-up time of 10.2 (0.4-41.0) years. Mutation analysis was available in 64 patients (80%). Renal lesions (cysts or angiomyolipoma) were observed in 55/73 (75%). Thirty-two percent (19/60) were hypertensive, 8/51 (16%) had proteinuria, and 18/71 (25%) had hyperfiltration (median eGFR 154 ml/min/m 2 ). Six (7.5%) patients had developed end stage renal disease at the last follow-up. No association was found between hyperfiltration, hypertension, or proteinuria and CKD ≥ 3. Cox regression showed a significant positive association between the presence of a renal intervention and CKD ≥ 3 (Hazard-Ratio 3.91, P < 0.05)., Conclusions: Besides renal cysts and angiomyolipoma, the modifiable progression factors hypertension, proteinuria, and hyperfiltration occur frequently and early in TSC patients. This represents a preventive treatment target.

Published
2018
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17. Simultaneous determination of allantoin and adenosine in human urine using liquid chromatography - UV detection.

Author

Andries A, De Rechter S, Janssens P, Mekahli D, and Van Schepdael A

Subjects
Adult, Drug Stability, Humans, Linear Models, Reproducibility of Results, Sensitivity and Specificity, Uric Acid urine, Young Adult, Adenosine urine, Allantoin urine, Chromatography, High Pressure Liquid methods, Spectrophotometry, Ultraviolet methods
Abstract

We report a HPLC-UV method for the quantitative determination of allantoin and adenosine in human urine, validated according to the acceptance criteria of both the USA Food and Drug Administration (FDA) guideline for bioanalytical method validation and the European Medicines Agency (EMA) validation guidelines. Both allantoins and adenosine are compounds of the purine catabolic pathway. Adenosine is situated at the top as a uric acid (UA) precursor, while allantoin is the best-known degradation product of UA. These two compounds are endogenously present in human urine. Chromatographic separation was achieved with a gradient elution at 0.6 mL/min using a Zorbax SB-Aq column coupled to a Zorbax SB-Aq guard column. Three different mobile phases were used: mobile phase A consisted of 10 mM KH 2 PO 4 (pH 4.7) in milli-Q water, mobile phase B was 12.5 mM KH 2 PO 4 (pH 4.7) - ACN (80:20) and mobile phase C consisted of ACN - H 2 O (50:50). The linear response range in human urine was 14-800 μM for allantoin and 1.25-50 μM for adenosine. The recoveries of allantoin, adenosine and the internal standard were greater than 93.8%. The intra-day accuracy ranged between 99.5 and 104.9% for allantoin and between 96.6 and 107.3% for adenosine, while the inter-day accuracy ranged respectively from 91.2 to 103.0% and from 94.5 to 107.8%. The intra-day precision range was from 0.8 to 6.2% RSD for allantoin and from 0.6 to 15.0% for adenosine. The inter-day precision ranged from 2.1-17.5% for allantoin and from 2.9-17.9% for adenosine. This method was successfully applied to analyze both compounds in urine samples of healthy volunteers. In conclusion, an accurate, precise and stable HPLC-UV method was developed and validated to quantify the endogenously present compounds allantoin and adenosine in human urine samples., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published
2018
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18. Prevalence of Hypertension in Children with Early-Stage ADPKD.

Author

Massella L, Mekahli D, Paripović D, Prikhodina L, Godefroid N, Niemirska A, Ağbaş A, Kalicka K, Jankauskiene A, Mizerska-Wasiak M, Afonso AC, Salomon R, Deschênes G, Ariceta G, Özçakar ZB, Teixeira A, Duzova A, Harambat J, Seeman T, Hrčková G, Lungu AC, Papizh S, Peco-Antic A, De Rechter S, Giordano U, Kirchner M, Lutz T, Schaefer F, Devuyst O, Wühl E, and Emma F

Subjects
Adolescent, Blood Pressure Monitoring, Ambulatory, Child, Female, Humans, Logistic Models, Male, Prevalence, Retrospective Studies, Risk Factors, Hypertension epidemiology, Polycystic Kidney, Autosomal Dominant complications
Abstract

Background and Objectives: Autosomal dominant polycystic kidney disease is the most common inheritable kidney disease, frequently thought to become symptomatic in adulthood. However, patients with autosomal dominant polycystic kidney disease may develop signs or symptoms during childhood, in particular hypertension. Although ambulatory BP monitoring is the preferred method to diagnose hypertension in pediatrics, data in children with autosomal dominant polycystic kidney disease are limited., Design, Setting, Participants, & Measurements: Our retrospective multicenter study was conducted to collect ambulatory BP monitoring recordings from patients with autosomal dominant polycystic kidney disease age <18 years old. Basic anthropometric parameters as well as data on kidney function, BP treatment, and kidney ultrasound were also collected., Results: Data from 310 children with autosomal dominant polycystic kidney disease with a mean age of 11.5±4.1 years old were collected at 22 European centers. At the time when ambulatory BP monitoring was performed, 95% of children had normal kidney function. Reference data for ambulatory BP monitoring were available for 292 patients. The prevalence rates of children with hypertension and/or those who were treated with antihypertensive drugs were 31%, 42%, and 35% during daytime, nighttime, or the entire 24-hour cycle, respectively. In addition, 52% of participants lacked a physiologic nocturnal BP dipping, and 18% had isolated nocturnal hypertension. Logistic regression analysis showed a significant association between a categorical cyst score that was calculated on the basis of the number of cysts >1 cm per kidney and daytime hypertension (odds ratio, 1.70; 95% confidence interval, 1.21 to 2.4; P =0.002), nighttime hypertension (odds ratio, 1.31; 95% confidence interval, 1.05 to 1.63; P =0.02), or 24-hour hypertension (odds ratio, 1.39; 95% confidence interval, 1.08 to 1.81; P =0.01). Kidney length, expressed as SD score, was also significantly associated with nighttime hypertension (odds ratio, 1.23; 95% confidence interval, 1.06 to 1.42; P =0.10)., Conclusions: These data indicate high prevalence of hypertension in children with autosomal dominant polycystic kidney disease starting at young ages., (Copyright © 2018 by the American Society of Nephrology.)

Published
2018
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19. 3DUS as an alternative to MRI for measuring renal volume in children with autosomal dominant polycystic kidney disease.

Author

Breysem L, De Rechter S, De Keyzer F, Smet MH, Bammens B, Van Dyck M, Hofmans M, Oyen R, Levtchenko E, and Mekahli D

Subjects
Adolescent, Child, Female, Humans, Image Processing, Computer-Assisted methods, Kidney pathology, Male, Imaging, Three-Dimensional methods, Kidney diagnostic imaging, Magnetic Resonance Imaging methods, Polycystic Kidney, Autosomal Dominant diagnostic imaging, Ultrasonography methods
Abstract

Background: Total kidney volume, measured by magnetic resonance imaging (MRI), is a validated disease progression marker in adults with autosomal dominant polycystic kidney disease (ADPKD). However, in childhood, MRI is burdensome, explaining the need for alternatives., Methods: Kidney volume (KV) was evaluated in 30 children with ADPKD, using three-dimensional ultrasound (3DUS), applying the ellipsoid method and manual contouring (KV 3DUS-ellipsoid, KV 3DUS-contour respectively); manual contouring on MRI (KV MRI ), and the ellipsoid method on two-dimensional ultrasound (2DUS, KV 2DUS ). Correlations and differences were evaluated using Pearson's r and Wilcoxon signed-rank tests, and variability using Bland-Altman plots., Results: All ultrasound volumetry methods showed significantly lower mean (± SD) KV (mL), compared with MRI-KV 2DUS : 159 (±101); K 3DUS-ellipsoid : 169 (±105); KV 3DUS-contour : 185 (±110); KV MRI : 206 (±130); all p < 0.001. All had a strong correlation with KV MRI : 2DUS: r = 0.96; 3DUS-ellipsoid: r = 0.89 and 3DUS-contour: r = 0.94. Both before and after correction factor application, Bland-Altman plots showed lower variability and absolute error for KV 3DUS-contour vs KV 2DUS and KV 3DUS-ellipsoid ., Conclusions: Compared with MRI, ultrasound volumetry was prone to underestimation. However, KV 3DUS-contour represents a valuable alternative for MRI in early ADPKD. Although more time-consuming, KV 3DUS-contour is recommended over KV 2DUS for estimation and follow-up of KV in ADPKD children, given its smaller error.

Published
2018
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20. Expanding the role of vasopressin antagonism in polycystic kidney diseases: From adults to children?

Author

Janssens P, Weydert C, De Rechter S, Wissing KM, Liebau MC, and Mekahli D

Subjects
Adult, Animals, Child, Cyclic AMP metabolism, Humans, Kidney metabolism, Kidney physiopathology, Signal Transduction drug effects, Signal Transduction physiology, Vasopressins metabolism, Antidiuretic Hormone Receptor Antagonists therapeutic use, Polycystic Kidney, Autosomal Dominant drug therapy, Tolvaptan therapeutic use
Abstract

Polycystic kidney disease (PKD) encompasses a group of genetic disorders that are common causes of renal failure. The two classic forms of PKD are autosomal recessive polycystic kidney disease (ARPKD) and autosomal dominant polycystic kidney disease (ADPKD). Despite their clinical differences, ARPKD and ADPKD share many similarities. Altered intracellular Ca 2+ and increased cyclic adenosine monophosphate (cAMP) concentrations have repetitively been described as central anomalies that may alter signaling pathways leading to cyst formation. The vasopressin V2 receptor (V2R) antagonist tolvaptan lowers cAMP in cystic tissues and slows renal cystic progression and kidney function decline when given over 3 years in adult ADPKD patients. Tolvaptan is currently approved for the treatment of rapidly progressive disease in adult ADPKD patients. On the occasion of the recent initiation of a clinical trial with tolvaptan in pediatric ADPKD patients, we aim to describe the most important aspects in the literature regarding the AVP-cAMP axis and the clinical use of tolvaptan in PKD.

Published
2018
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21. Is Autosomal Dominant Polycystic Kidney Disease Becoming a Pediatric Disorder?

Author

De Rechter S, Breysem L, and Mekahli D

Abstract

Autosomal dominant polycystic kidney disease (ADPKD) affects 1 in 400 to 1,000 live births, making it the most common monogenic cause of renal failure. Although no definite cure is available yet, it is important to affect disease progression by influencing modifiable factors such as hypertension and proteinuria. Besides this symptomatic management, the only drug currently recommended in Europe for selected adult patients with rapid disease progression, is the vasopressin receptor antagonist tolvaptan. However, the question remains whether these preventive interventions should be initiated before extensive renal damage has occurred. As renal cyst formation and expansion begins early in life, frequently in utero , ADPKD should no longer be considered an adult-onset disease. Moreover, the presence of hypertension and proteinuria in affected children has been reported to correlate well with disease severity. Until now, it is controversial whether children at-risk for ADPKD should be tested for the presence of the disease, and if so, how this should be done. Herein, we review the spectrum of pediatric ADPKD and discuss the pro and contra of testing at-risk children and the challenges and unmet needs in pediatric ADPKD care.

Published
2017
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22. Evidence for Bone and Mineral Metabolism Alterations in Children With Autosomal Dominant Polycystic Kidney Disease.

Author

De Rechter S, Bacchetta J, Godefroid N, Dubourg L, Cochat P, Maquet J, Raes A, De Schepper J, Vermeersch P, Van Dyck M, Levtchenko E, D'Haese P, Evenepoel P, and Mekahli D

Subjects
Adolescent, Case-Control Studies, Child, Child, Preschool, Cross-Sectional Studies, Female, Fibroblast Growth Factor-23, Humans, Male, Minerals metabolism, Phosphorus metabolism, Polycystic Kidney, Autosomal Dominant complications, Bone Diseases genetics, Bone Diseases metabolism, Bone and Bones metabolism, Calcification, Physiologic genetics, Polycystic Kidney, Autosomal Dominant genetics, Polycystic Kidney, Autosomal Dominant metabolism
Abstract

Context: Autosomal dominant polycystic kidney disease (ADPKD) is the most common hereditary kidney disease. Hypophosphatemia was demonstrated in adult patients with preserved renal function, together with high fibroblast growth factor 23 (FGF23) and low soluble Klotho levels. The latter explained the relative FGF23 hyporesponsiveness in this cohort., Objective: Evaluating phosphate and bone mineral metabolism in children with ADPKD compared with what is known in adult ADPKD patients., Design: Observational cross-sectional study., Setting: Multicenter study via ambulatory care in tertiary centers., Participants: Ninety-two children with ADPKD (52 males; mean ± standard deviation age, 10.2 ± 5.0 years) and 22 healthy controls (HCs, 10 males; mean ± standard deviation age, 10.3 ± 4.1 years)., Main Outcome Measures: The predictor was early ADPKD stage. Bone mineral metabolism and renal phosphate handling were the main outcome measures. Performed measurements were serum phosphate, tubular maximum phosphorus reabsorption per glomerular filtration rate, FGF23, soluble Klotho, sclerostin, and bone alkaline phosphatase., Results: ADPKD children had significantly lower serum phosphate levels compared with HC. Low tubular maximum phosphorus reabsorption per glomerular filtration rate was observed in 24% of patients, although not significantly different from HC. Serum FGF23 and soluble Klotho levels were comparable between patients and HC. In addition, we showed decreased bone alkaline phosphatase levels in ADPKD children, suggesting suppressed bone formation., Conclusions: This report demonstrates hypophosphatemia and suppressed bone formation in a pediatric ADPKD cohort, with preserved renal function, compared with HC. Although FGF23 levels were not different from controls, they should be considered inappropriate, given the concomitant hypophosphatemia. Further studies are required to elucidate underlying pathophysiology and potential clinical consequences., (Copyright © 2017 Endocrine Society)

Published
2017
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23. Clinicians' attitude towards family planning and timing of diagnosis in autosomal dominant polycystic kidney disease.

Author

De Rechter S, Kringen J, Janssens P, Liebau MC, Devriendt K, Levtchenko E, Bergmann C, Jouret F, Bammens B, Borry P, Schaefer F, and Mekahli D

Subjects
Adult, Female, Humans, Male, Middle Aged, Polycystic Kidney, Autosomal Dominant physiopathology, Polycystic Kidney, Autosomal Dominant therapy, Surveys and Questionnaires, Attitude of Health Personnel, Family Planning Services, Polycystic Kidney, Autosomal Dominant diagnosis
Abstract

Several ethical aspects in the management of Autosomal Dominant Polycystic Kidney Disease (ADPKD) are still controversial, including family planning and testing for disease presence in at-risk individuals. We performed an online survey aiming to assess the opinion and current clinical practice of European pediatric and adult nephrologists, as well as geneticists. A total of 410 clinicians (53% male, mean (SD) age of 48 (10) years) responded, including 216 pediatric nephrologists, 151 adult nephrologists, and 43 clinical geneticists. While the 3 groups agreed to encourage clinical testing in asymptomatic ADPKD minors and adults, only geneticists would recommend genetic testing in asymptomatic at-risk adults (P<0.001). Statistically significant disagreement between disciplines was observed regarding the ethical justification of prenatal genetic diagnosis, termination of pregnancy and pre-implantation genetic diagnosis (PGD) for ADPKD. Particularly, PGD is ethically justified according to geneticists (4.48 (1.63)), whereas pediatric (3.08 (1.78); P<0.001) and adult nephrologists (3.66 (1.88); P<0.05) appeared to be less convinced. Our survey suggests that most clinicians support clinical testing of at-risk minors and adults in ADPKD families. However, there is no agreement for genetic testing in asymptomatic offspring and for family planning, including PGD. The present data highlight the need for a consensus among clinicians, to avoid that ADPKD families are being given conflicting information.

Published
2017
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25. Autophagy in renal diseases.

Author

De Rechter S, Decuypere JP, Ivanova E, van den Heuvel LP, De Smedt H, Levtchenko E, and Mekahli D

Subjects
Animals, Epithelial Cells drug effects, Epithelial Cells metabolism, Humans, Kidney drug effects, Kidney metabolism, Kidney physiopathology, Kidney Diseases drug therapy, Kidney Diseases metabolism, Kidney Diseases physiopathology, Molecular Targeted Therapy, Signal Transduction, Urological Agents therapeutic use, Autophagy drug effects, Epithelial Cells pathology, Kidney pathology, Kidney Diseases pathology
Abstract

Autophagy is the cell biology process in which cytoplasmic components are degraded in lysosomes to maintain cellular homeostasis and energy production. In the healthy kidney, autophagy plays an important role in the homeostasis and viability of renal cells such as podocytes and tubular epithelial cells and of immune cells. Recently, evidence is mounting that (dys)regulation of autophagy is implicated in the pathogenesis of various renal diseases, and might be an attractive target for new renoprotective therapies. In this review, we provide an overview of the role of autophagy in kidney physiology and kidney diseases.

Published
2016
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26. Charcot-Marie-Tooth: are you testing for proteinuria?

Author

De Rechter S, De Waele L, Levtchenko E, and Mekahli D

Subjects
Adolescent, Adult, Age of Onset, Charcot-Marie-Tooth Disease genetics, Charcot-Marie-Tooth Disease urine, Child, Child, Preschool, Formins, Humans, Microfilament Proteins genetics, Proteinuria etiology, Young Adult, Charcot-Marie-Tooth Disease diagnosis, Proteinuria diagnosis
Abstract

Charcot-Marie-Tooth disease (CMT) is a clinically and genetically heterogeneous group of inherited disorders affecting motor and sensory nerves of the peripheral nervous system. CMT has been reported to be associated with renal diseases, mostly focal segmental glomerulosclerosis (FSGS). However, it was unknown whether these two clinical manifestations represent one common underlying disorder or separate disease entities. Several reports have shown a high prevalence of mutations (75%) in the inverted formin gene (INF2) in patients with CMT-associated glomerulopathy, suggesting that these mutations are a common cause of the dual phenotype. For this reason, we strongly suggest to screen for proteinuria in CMT patients, in order to identify patients with this renal-neurologic phenotype in an early stage, and to perform genetic testing for INF2 mutations., (Copyright © 2014 European Paediatric Neurology Society. Published by Elsevier Ltd. All rights reserved.)

Published
2015
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