Literature DB >> 29423210

The European Renal Association - European Dialysis and Transplant Association (ERA-EDTA) Registry Annual Report 2015: a summary.

Anneke Kramer¹, Maria Pippias¹, Marlies Noordzij¹, Vianda S Stel¹, Nikolaos Afentakis², Patrice M Ambühl³, Anton M Andrusev^4,5, Emma Arcos Fuster⁶, Federico E Arribas Monzón⁷, Anders Åsberg⁸, Myftar Barbullushi⁹, Marjolein Bonthuis¹⁰, Fergus J Caskey^11,12, Pablo Castro de la Nuez¹³, Harijs Cernevskis¹⁴, Jean-Marin des Grottes¹⁵, Liliana Garneata¹⁶, Eliezer Golan¹⁷, Marc H Hemmelder¹⁸, Kyriakos Ioannou^19,20, Faical Jarraya²¹, Mykola Kolesnyk²², Kirill Komissarov²³, Mathilde Lassalle²⁴, Fernando Macario²⁵, Beatriz Mahillo-Duran²⁶, Angel L Martín de Francisco²⁷, Runolfur Palsson^28,29, Ülle Pechter³⁰, Halima Resic³¹, Boleslaw Rutkowski³², Carmen Santiuste de Pablos³³, Nurhan Seyahi³⁴, Sanja Simic Ogrizovic³⁵, María F Slon Roblero³⁶, Viera Spustova³⁷, Olivera Stojceva-Taneva³⁸, Jamie Traynor³⁹, Ziad A Massy^40,41, Kitty J Jager¹.

Abstract

BACKGROUND: This article summarizes the European Renal Association - European Dialysis and Transplant Association (ERA-EDTA) Registry's 2015 Annual Report. It describes the epidemiology of renal replacement therapy (RRT) for end-stage renal disease (ESRD) in 2015 within 36 countries.
METHODS: In 2016 and 2017, the ERA-EDTA Registry received data on patients who were undergoing RRT for ESRD in 2015, from 52 national or regional renal registries. Thirty-two registries provided individual patient-level data and 20 provided aggregated-level data. The incidence, prevalence and survival probabilities of these patients were determined.
RESULTS: In 2015, 81 373 individuals commenced RRT for ESRD, equating to an overall unadjusted incidence rate of 119 per million population (pmp). The incidence ranged by 10-fold, from 24 pmp in Ukraine to 232 pmp in the Czech Republic. Of the patients commencing RRT, almost two-thirds were men, over half were aged ≥65 years and a quarter had diabetes mellitus as their primary renal diagnosis. Treatment modality at the start of RRT was haemodialysis for 85% of the patients, peritoneal dialysis for 11% and a kidney transplant for 4%. By Day 91 of commencing RRT, 82% of patients were receiving haemodialysis, 13% peritoneal dialysis and 5% had a kidney transplant. On 31 December 2015, 546 783 individuals were receiving RRT for ESRD, corresponding to an unadjusted prevalence of 801 pmp. This ranged throughout Europe by more than 10-fold, from 178 pmp in Ukraine to 1824 pmp in Portugal. In 2015, 21 056 kidney transplantations were performed, equating to an overall unadjusted transplant rate of 31 pmp. This varied from 2 pmp in Ukraine to 94 pmp in the Spanish region of Cantabria. For patients commencing RRT during 2006-10, the 5-year unadjusted patient survival probabilities on all RRT modalities combined was 50.0% (95% confidence interval 49.9-50.1).

Entities: Chemical

Keywords: dialysis; end-stage renal disease; epidemiology; kidney transplantation; survival analysis

Year: 2018 PMID： 29423210 PMCID： PMC5798130 DOI： 10.1093/ckj/sfx149

Source DB: PubMed Journal: Clin Kidney J ISSN： 2048-8505

Introduction

The European Renal Association – European Dialysis and Transplant Association (ERA-EDTA) Registry’s Annual Report describes the epidemiology of renal replacement therapy (RRT) for end-stage renal disease (ESRD) within Europe and countries bordering the Mediterranean Sea based on data collected via national and regional renal registries [1]. On an annual basis we publish a summary of the ERA-EDTA Registry’s Annual Report that is intended to provide an overview of the current status of RRT for ESRD in Europe [2-4]. In 2016 and 2017, we received the 2015 data from 52 national or regional renal registries in 36 countries covering a general population of 683.4 million people, representing 80.3% of the 2015 European general population. Thirty-two national or regional renal registries from 17 countries provided individual patient data, whereas 20 countries or regions provided aggregated-level data (see Appendix 1). The proportion of the European population covered by the ERA-EDTA Registry in 2015 was higher than in 2014 (65.4%) due to the inclusion of Russia and Belarus in this year’s Annual Report. Furthermore, compared with the 2014 ERA-EDTA Registry’s Annual Report, Switzerland switched from providing aggregated data to providing individual patient data, while Montenegro was unable to provide data. This summary presents the 2015 incidence and prevalence of patients receiving RRT, kidney transplantation activity and the patient and graft survival in these 36 countries. A description of the methods to analyse the data, along with the full results, can be found in the ERA-EDTA Registry 2015 Annual Report [1].

Results

Incidence of RRT

In 2015, 81 373 individuals commenced RRT for ESRD, which equated to an overall unadjusted incidence rate of 119 per million population (pmp, Table 1). The unadjusted incidence rate was highest in the Czech Republic (232 pmp), Greece (227 pmp) and Portugal (227 pmp), whereas it was lowest in Ukraine (24 pmp) and Russia (51 pmp, Table 1 and Figures 1 and 2). The top five countries with the highest incident rates were equal to the top five in 2014, except for the Czech Republic, which had the fourth highest incident rate in 2014, but the highest incident rate in 2015. Of the patients commencing RRT, 62% were men, 52% were aged ≥65 years and 23% had diabetes mellitus as their primary renal diagnosis (Figure 3). The mean age of the patients commencing RRT in all countries and regions combined was 63.1 years, ranging from 48.1 years in Albania to 70.6 years in the Dutch-speaking part of Belgium (Table 1). The majority of patients started RRT with haemodialysis (85%), while 11% of patients started with peritoneal dialysis and 4% received a pre-emptive kidney transplant (Figure 4). However, the initial treatment modality varied considerably between age groups, as the proportion of patients receiving either peritoneal dialysis or a pre-emptive transplant decreased with increasing age. Furthermore, patients with a primary renal diagnosis of diabetes mellitus were less likely to receive a pre-emptive kidney transplant compared with the non-diabetic group (2% versus 6%). Of the incident patients alive and receiving RRT at Day 91 after the start of treatment, the majority (82%) were receiving haemodialysis, 13% were receiving peritoneal dialysis and 5% were living with a kidney transplant (Figure 5). In the first 90 days of treatment, the percentage of patients receiving haemodialysis decreased, this was particularly evident in the younger age groups.

Table 1

Incidence of RRT in 2015 at Day 1, for all primary renal diseases combined and diabetes mellitus Types 1 and 2, as count (n) and unadjusted rate pmp, and the mean age at the start of RRT

Country/region	General population covered by the registry in thousands	Incidence of RRT in 2015, at Day 1
Country/region	General population covered by the registry in thousands	All (n)	All (pmp)	Mean age (years)	DM (n)	DM (pmp)
Albania	2851	251	88	52.5	30	11
Austria	8585	1204	140	65.0	316	37
Belarus	9299	747	80		167	18
Belgium, Dutch-speaking^a	6473	1158	179	70.6	234	36
Belgium, French-speaking^a	4802	902	188	67.8	197	41
Bosnia and Herzegovina	3531	404	114	61.4	122	35
Bulgaria^b	7154	1093	153		278	39
Croatia	3427	540	158	65.3	168	49
Cyprus	855	164	192	66.3	61	71
Czech Republic^b	10 293	2393	232
Denmark	5740	621	108	62.3	179	31
Estonia	1315	114	87	58.6	23	17
Finland	5480	520	95	59.6	177	32
France	66 624	11 084	166	67.9	2513	38
Georgia	3714	694	187	61.9	158	43
Greece	10 821	2455	227	69.6	646	60
Iceland	331	24	73	57.4	5	15
Israel	8380	1606	192	65.3	723	86
Italy (5 of 20 regions)	16 986	2232	131	68.2	402	24
Latvia	1574	152	97	62.2	23	15
Lithuania	2921	308	105	64.7	44	15
Macedonia	2022	307	152	63.5	71	35
Norway	5189	514	99	63.0	90	17
Poland	37 967	6617	174
Portugal	10 375	2352	227		771	74
Romania	19 617	3125	159	61.7	355	18
Russia	145 080	7413	51	52.3	1297	9
Serbia	7095	818	115	62.4	185	26
Slovakia	5426	916	169	62.8	334	62
Spain (all regions)	46 624	6277	135	64.8	1454	31
Spain, Andalusia	8402	1037	123	62.6	263	31
Spain, Aragon	1323	155	117	66.2	6	5
Spain, Asturias	1050	176	168	66.6	45	43
Spain, Basque country	2165	265	122	64.8	58	27
Spain, Cantabria^a	584	61	104	65.6	16	27
Spain, Castile and León^a	2466	287	116	67.4	71	29
Spain, Castile-La Mancha^a	2056	220	107	64.0	47	23
Spain, Catalonia	7508	1247	166	66.9	213	28
Spain, Extremadura	1093	152	139	66.2	34	31
Spain, Galicia	2728	393	144	65.6	104	38
Spain, Community of Madrid	6437	807	125	65.2	217	34
Spain, Region of Murcia	1467	184	125	62.3	37	25
Spain, Navarre^a	637	92	144	63.6	16	25
Spain, Valencian region	4981	734	147	64.8	147	30
Sweden	9799	1166	119	63.7	306	31
Switzerland	8282	848	102	64.6	155	19
The Netherlands	16 940	1996	118	63.7	375	22
Tunisia, Sfax region	1186	193	163	59.4	62	52
Turkey^c	78 736	11 597	147		636	8
Ukraine	42 759	1024	24	48.1	248	6
UK, England^a^,^d	54 786	6323	115	62.3	1546	28
UK, Northern Ireland^a	1852	220	119	63.5	51	28
UK, Scotland	5373	619	115	59.6	173	32
UK, Wales^a	3099	382	123	63.3	104	34
All countries	683 363	81 373	119	63.1	14 679	26

When cells are left empty, the data are unavailable and could not be used for the calculation of the summary data.

Patients younger than 20 years of age are not reported. The true incidence counts are, therefore, slightly higher than the counts reported here.

Data on incidence include dialysis patients only.

Data on incidence of primary renal disease (DM) is based on 1707 dialysis patients (14.7% of total).

The incidence is underestimated by ∼4% due to a small number of centres not submitting complete data for 2015.

DM , diabetes mellitus as primary renal disease.

Fig. 1.

Unadjusted incidence rates of RRT pmp, by country/region at Day 1 in 2015. The incidence rate for Bulgaria, the Czech Republic, Russia and Slovakia only includes patients receiving dialysis. For England (UK), the overall incidence of RRT is underestimated by ∼4%.

Fig. 2.

Unadjusted (left panel) and adjusted (right panel) incidence rates of RRT pmp by country/region at Day 1 in 2015. Registries providing individual patient data are shown as dark bars, and registries providing aggregated-level data as light bars. Adjustment of incidence rates was performed by standardizing the rates to the age and gender distribution of the EU27 population [5]. The incidence rate for Bulgaria, the Czech Republic, Russia and Slovakia only includes patients receiving dialysis. For England (UK), the overall incidence of RRT is underestimated by ∼4%.

Fig. 3.

Unadjusted incidence of RRT (%) by (A) gender, (B) age and (C) primary renal diagnosis at Day 1 in 2015. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data.

Fig. 4.

Unadjusted incidence (%) of (A) treatment modality overall, and treatment modality by (B) gender, (C) age and (D) primary renal diagnosis in 2015. (B–D) Only based on data from registries providing individual patient data. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. HD, haemodialysis; PD, peritoneal dialysis; Tx, transplant; DM, diabetes mellitus.

Fig. 5.

Unadjusted incidence (%) of (A) treatment modality overall, and treatment modality by (B) gender, (C) age and (D) primary renal diagnosis at Day 91 in 2015. (B–D) Only based on data from registries providing individual patient data. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. HD, haemodialysis; PD, peritoneal dialysis; Tx, transplant; DM, diabetes mellitus.

Incidence of RRT in 2015 at Day 1, for all primary renal diseases combined and diabetes mellitus Types 1 and 2, as count (n) and unadjusted rate pmp, and the mean age at the start of RRT When cells are left empty, the data are unavailable and could not be used for the calculation of the summary data. Patients younger than 20 years of age are not reported. The true incidence counts are, therefore, slightly higher than the counts reported here. Data on incidence include dialysis patients only. Data on incidence of primary renal disease (DM) is based on 1707 dialysis patients (14.7% of total). The incidence is underestimated by ∼4% due to a small number of centres not submitting complete data for 2015. DM , diabetes mellitus as primary renal disease. Unadjusted incidence rates of RRT pmp, by country/region at Day 1 in 2015. The incidence rate for Bulgaria, the Czech Republic, Russia and Slovakia only includes patients receiving dialysis. For England (UK), the overall incidence of RRT is underestimated by ∼4%. Unadjusted (left panel) and adjusted (right panel) incidence rates of RRT pmp by country/region at Day 1 in 2015. Registries providing individual patient data are shown as dark bars, and registries providing aggregated-level data as light bars. Adjustment of incidence rates was performed by standardizing the rates to the age and gender distribution of the EU27 population [5]. The incidence rate for Bulgaria, the Czech Republic, Russia and Slovakia only includes patients receiving dialysis. For England (UK), the overall incidence of RRT is underestimated by ∼4%. Unadjusted incidence of RRT (%) by (A) gender, (B) age and (C) primary renal diagnosis at Day 1 in 2015. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. Unadjusted incidence (%) of (A) treatment modality overall, and treatment modality by (B) gender, (C) age and (D) primary renal diagnosis in 2015. (B–D) Only based on data from registries providing individual patient data. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. HD, haemodialysis; PD, peritoneal dialysis; Tx, transplant; DM, diabetes mellitus. Unadjusted incidence (%) of (A) treatment modality overall, and treatment modality by (B) gender, (C) age and (D) primary renal diagnosis at Day 91 in 2015. (B–D) Only based on data from registries providing individual patient data. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. HD, haemodialysis; PD, peritoneal dialysis; Tx, transplant; DM, diabetes mellitus.

Prevalence of RRT

On 31 December 2015, 546 783 individuals were receiving RRT for ESRD (Table 2). This corresponds to an overall unadjusted prevalence of 801 pmp. Again there was considerable variation between countries, with the highest unadjusted prevalence seen in Portugal (1824 pmp) and the Spanish regions of Catalonia (1355 pmp) and Valencia (1333 pmp) (Table 2 and Figures 6 and 7). The unadjusted prevalence of RRT was considerably lower in Ukraine (178 pmp) and Russia (303 pmp). The top five countries with the highest prevalence remained the same as with 2014. Of the prevalent patients the majority were men (60%), 42% were aged ≥65 years and 16% had diabetes mellitus as their primary renal diagnosis (Figure 8). The mean age of the prevalent patients receiving RRT in all countries and regions combined was 60.8 years, ranging from 48.6 years in Ukraine to 66.8 years in Portugal (Table 2). The majority of prevalent patients (58%) were receiving haemodialysis, 36% of patients were living with a kidney transplant and only 5% were on peritoneal dialysis (Figure 9). Once again the modality of RRT varied considerably between age groups as the proportion of patients with a kidney transplant decreased with increasing age. For those aged 20–44 years, 66% were living with a kidney transplant whereas this was true for only 42% of patients aged 65–74 years. Prevalent patients with a primary renal diagnosis of diabetes mellitus were much less likely to be living with a kidney transplant compared with the patients without diabetes mellitus (28% versus 49%).

Table 2

Prevalence of RRT on 31 December 2015, for all primary renal diseases combined and diabetes mellitus Types 1 and 2, as count (n) and unadjusted rate pmp, and the mean age of prevalent patients

Country/region	General population covered by the registry in thousands	Prevalent patients on RRT in 2015
Country/region	General population covered by the registry in thousands	All (n)	All (pmp)	Mean age (years)	DM (n)	DM (pmp)
Albania	2851	1214	426	50.3	144	51
Austria	8585	9259	1079	61.0	1828	213
Belarus	9299	3204	345		444	48
Belgium, Dutch-speaking^a	6473	8142	1258	65.8	1400	216
Belgium, French-speaking^a	4802	6143	1279	64.8	1071	223
Bosnia and Herzegovina	3531	2653	751	59.4	512	145
Bulgaria	7154	4241	593
Croatia	3427	2553	745	65.6	656	191
Cyprus	855
Czech Republic	10 293	11 444	1112
Denmark	5740	5190	904	58.4	878	153
Estonia	1315	869	661	57.8	163	124
Finland	5480	4679	854	58.8	1189	217
France	66 624	83 042	1246	63.0	13 217	198
Georgia	3714	2327	627	56.5	483	130
Greece	10 821	13 359	1235	64.0	2485	230
Iceland	331	218	659	54.6	23	70
Israel^b	8380	6442	769	65.6	2954	352
Italy (5 of 20 regions)	16 986	17 832	1050	62.2	2061	121
Latvia	1574	1007	640	55.9	95	60
Lithuania	2921	2203	754
Macedonia	2022	1598	790	57.8	245	121
Norway	5189	4836	932	59.3	644	124
Poland	37 967	30 400	801
Portugal^c	10 375	18 928	1824	66.8	3392	327
Romania^d	19 617	18 977	967	60.5	1996	102
Russia	145 080	43 955	303	54.4	5318	37
Serbia	7095	5673	800	59.2	935	132
Slovakia^b	5426	3337	615	63.3	1145	211
Spain (all regions)	46 624	56 354	1209	63.2	8863	190
Spain, Andalusia	8402	9640	1147	60.2	1476	176
Spain, Aragon	1323	1539	1164	62.7	238	180
Spain, Asturias	1050	1256	1196	62.8	206	196
Spain, Basque country	2165	2656	1227	61.8	286	132
Spain, Cantabria^a	584	662	1134	62.2	89	152
Spain, Castile and León^a	2466	2761	1119	64.3	476	193
Spain, Castile-La Mancha^a	2056	2241	1090	62.0	341	166
Spain, Catalonia	7508	10 171	1355	62.7	1414	188
Spain, Community of Madrid	6437	7008	1089	61.5	1247	194
Spain, Extremadura	1093	1256	1149	61.4	191	175
Spain, Galicia	2728	3559	1305	62.2	608	223
Spain, Navarre^a	637	799	1254	62.0	112	176
Spain, Region of Murcia	1467	1888	1287	61.8	257	175
Spain, Valencian region	4981	6638	1333	62.8	883	177
Sweden	9799	9421	961	59.6	1668	170
Switzerland^e	8282	7714	931	62.5	1166	141
The Netherlands	16 940	16 764	990	60.1	2122	125
Tunisia, Sfax region^b	1186	923	778	58.3	184	155
Turkey^f	78 736	73 660	936		2048	26
UK, England^a^,g	54 786	50 999	931	58.6	8483	155
UK, Northern Ireland^a	1852	1693	914	58.4	258	139
UK, Scotland	5373	4923	916	56.6	781	145
UK, Wales^a	3099	2997	967	59.4	509	164
Ukraine	42 759	7610	178	48.6	1137	27
All countries	683 363	546 783	801	60.8	70 497	128

When cells are left empty, the data are unavailable and could not be used for the calculation of the summary data.

Patients younger than 20 years of age are not reported. The true prevalent counts are therefore slightly higher than the counts reported here.

Data on prevalence include dialysis patients only.

Data on prevalence of primary renal disease (DM) include dialysis patients only.

The prevalence is underestimated by ∼3% due to an estimated 30% underreporting of patients living on a functioning graft.

The prevalence is underestimated by ∼6% due to an estimated 11% underreporting of patients living on a functioning graft.

Data on the prevalence of primary renal disease (DM) is based on 6400 dialysis patients (8.7% of total).

The prevalence is underestimated by ∼1% due to a small number of centres not submitting complete data for 2015.

DM, diabetes mellitus as primary renal disease.

Fig. 6.

Unadjusted prevalence of RRT pmp by country/region on 31 December 2015. The prevalence for Israel, Slovakia and Tunisia (Sfax region) only includes patients receiving dialysis. For Romania, Switzerland and England (UK), the overall prevalence of RRT is underestimated by, respectively, 3, 6 and 1%.

Fig. 7.

Unadjusted (left panel) and adjusted (right panel) prevalence of RRT pmp by country/region on 31 December 2015. Registries providing individual patient data are shown as dark bars, and registries providing aggregated-level data as light bars. Adjustment of the prevalence was performed by standardizing the prevalence to the age and gender distribution of the EU27 population [5]. The prevalence for Israel, Slovakia and Tunisia (Sfax region) only includes patients receiving dialysis. For Romania, Switzerland and England (UK), the overall prevalence of RRT is underestimated by, respectively, 3, 6 and 1%.

Fig. 8.

Unadjusted prevalence (%) by (A) gender, (B) age and (C) primary renal diagnosis on 31 December 2015. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data.

Fig. 9.

Unadjusted prevalence (%) of (A) treatment modality overall, and treatment modality by (B) gender, (C) age and (D) primary renal diagnosis on 31 December 2015. (B–D) Only based on data from registries providing individual patient data. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. HD, haemodialysis; PD, peritoneal dialysis; Tx, transplant; DM, diabetes mellitus.

Prevalence of RRT on 31 December 2015, for all primary renal diseases combined and diabetes mellitus Types 1 and 2, as count (n) and unadjusted rate pmp, and the mean age of prevalent patients When cells are left empty, the data are unavailable and could not be used for the calculation of the summary data. Patients younger than 20 years of age are not reported. The true prevalent counts are therefore slightly higher than the counts reported here. Data on prevalence include dialysis patients only. Data on prevalence of primary renal disease (DM) include dialysis patients only. The prevalence is underestimated by ∼3% due to an estimated 30% underreporting of patients living on a functioning graft. The prevalence is underestimated by ∼6% due to an estimated 11% underreporting of patients living on a functioning graft. Data on the prevalence of primary renal disease (DM) is based on 6400 dialysis patients (8.7% of total). The prevalence is underestimated by ∼1% due to a small number of centres not submitting complete data for 2015. DM, diabetes mellitus as primary renal disease. Unadjusted prevalence of RRT pmp by country/region on 31 December 2015. The prevalence for Israel, Slovakia and Tunisia (Sfax region) only includes patients receiving dialysis. For Romania, Switzerland and England (UK), the overall prevalence of RRT is underestimated by, respectively, 3, 6 and 1%. Unadjusted (left panel) and adjusted (right panel) prevalence of RRT pmp by country/region on 31 December 2015. Registries providing individual patient data are shown as dark bars, and registries providing aggregated-level data as light bars. Adjustment of the prevalence was performed by standardizing the prevalence to the age and gender distribution of the EU27 population [5]. The prevalence for Israel, Slovakia and Tunisia (Sfax region) only includes patients receiving dialysis. For Romania, Switzerland and England (UK), the overall prevalence of RRT is underestimated by, respectively, 3, 6 and 1%. Unadjusted prevalence (%) by (A) gender, (B) age and (C) primary renal diagnosis on 31 December 2015. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. Unadjusted prevalence (%) of (A) treatment modality overall, and treatment modality by (B) gender, (C) age and (D) primary renal diagnosis on 31 December 2015. (B–D) Only based on data from registries providing individual patient data. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. HD, haemodialysis; PD, peritoneal dialysis; Tx, transplant; DM, diabetes mellitus.

Kidney transplantation

In 2015, 21 056 kidney transplantations were performed, which equated to an overall unadjusted transplant rate of 31 pmp (Figure 10). Again there was considerable variation between countries/regions with unadjusted kidney transplant rates well over 70 pmp in some Spanish regions, and very low unadjusted kidney transplant rates in Ukraine (2 pmp) and Macedonia (6 pmp). Overall, the unadjusted deceased donor transplant rate was more than twice that of the unadjusted living donor transplant rate (23 pmp versus 10 pmp; 68% versus 29%, Figure 11). The highest unadjusted rates of deceased donor transplants were seen in some Spanish regions (>60 pmp, Figure 12), whereas the highest unadjusted rate of living donor transplants were seen in the Netherlands (30 pmp), Turkey (32 pmp) and Northern Ireland (33 pmp, Figure 12).

Fig. 10.

Fig. 11.

Percentage of kidney transplants performed in 2015 by kidney donor type. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data.

Fig. 12.

Unadjusted deceased donor (left panel) and living donor (right panel) kidney transplants performed in 2015 pmp, by country/region. Registries providing individual patient-level data are shown as dark bars, and registries providing aggregated-level data as light bars. Data based on patients aged ≥20 years in Dutch-speaking Belgium, French-speaking Belgium, the Spanish regions of Cantabria, Castile and León, Castile-La Mancha and Navarre and the UK: England, Northern Ireland and Wales. The total count for Austria is based on residents and non-residents. For Romania, Switzerland and England (UK), the overall transplant rate is underestimated by, respectively, 30, 6 and 7%.

Kidney transplants performed in 2015, as counts and pmp (unadjusted) by country/region. Registries providing individual patient-level data are shown as dark bars, and registries providing aggregated-level data as light bars. Data based on patients aged ≥20 years in Dutch-speaking Belgium, French-speaking Belgium, the Spanish regions of Cantabria, Castile and León, Castile-La Mancha and Navarre and the UK: England, Northern Ireland and Wales. The total count for Austria is based on residents and non-residents. For Romania, Switzerland and England (UK), the overall transplant rate is underestimated by, respectively, 30, 6 and 7%. Percentage of kidney transplants performed in 2015 by kidney donor type. See Appendix 1 for a list of countries and regions supplying individual patient-level or aggregated-level data. Unadjusted deceased donor (left panel) and living donor (right panel) kidney transplants performed in 2015 pmp, by country/region. Registries providing individual patient-level data are shown as dark bars, and registries providing aggregated-level data as light bars. Data based on patients aged ≥20 years in Dutch-speaking Belgium, French-speaking Belgium, the Spanish regions of Cantabria, Castile and León, Castile-La Mancha and Navarre and the UK: England, Northern Ireland and Wales. The total count for Austria is based on residents and non-residents. For Romania, Switzerland and England (UK), the overall transplant rate is underestimated by, respectively, 30, 6 and 7%.

Survival of patients receiving RRT

For patients commencing RRT in the period 2006–10, the 1-, 2- and 5-year unadjusted patient survival probabilities for all RRT modalities combined were 83.2% [95% confidence interval (CI) 83.1–83.4], 72.7% (95% CI 72.6–72.9) and 50.0% (95% CI 49.9–50.1), respectively (see Table 3 for a description of the countries/regions included in this analysis). For patients commencing dialysis between 2006 and 2010, the 5-year unadjusted patient survival probability was 41.8% (95% CI 41.7–41.9). Adjusted analyses comparing patient survival on haemodialysis and peritoneal dialysis revealed higher survival probabilities in the first 3 years for patients on peritoneal dialysis (Figure 13). For those with a kidney transplant, 5-year adjusted patient and graft survival were higher with a living donor transplant compared with a deceased donor transplant [94.5% (95% CI 94.0–95.0) versus 91.7% (95% CI 91.3–92.1) for patient survival and 86.6% (95% CI 85.8–87.4) versus 80.7% (95% CI 80.2–81.2) for graft survival]. See Table 3 for a description of the adjustments made and the countries/regions included in this analysis.

Table 3

The survival probabilities at 1, 2 and 5 years by treatment modality and cohort, from Day 1 of the start of RRT/dialysis, or from the day of kidney transplantation

Survival type	Survival probabilities as percentage (95% CIs)
	Cohort: 2006–10			Cohort: 2009–13
	1 year	2 years	5 years	1 year	2 years
Patient survival on RRT
Unadjusted	83.2 (83.1–83.4)	72.7 (72.6–72.9)	50.0 (49.9–50.1)	84.4 (84.2–84.5)	74.3 (74.2–74.5)
Adjusted^a	85.9 (85.8–86.1)	76.1 (75.9–76.3)	51.1 (50.8–51.4)	86.9 (86.7–87.1)	77.6 (77.4–77.9)
Patient survival on dialysis
Unadjusted	82.2 (82.1–82.4)	70.4 (70.2–70.6)	41.8 (41.7–41.9)	83.3 (83.1–83.4)	71.9 (71.7–72.0)
Adjusted^a	84.4 (84.2–84.6)	73.5 (73.3–73.7)	45.0 (44.7–45.4)	85.7 (85.5–85.9)	75.4 (75.2–75.6)
Patient survival after first kidney transplantation (deceased donor)
Unadjusted	96.1 (95.9–96.4)	94.3 (94.1–94.6)	88.0 (87.6–88.3)	96.3 (96.1–96.5)	94.3 (94.0–94.5)
Adjusted^b	97.5 (97.3–97.6)	96.2 (96.0–96.4)	91.7 (91.3–92.1)	97.8 (97.7–98.0)	96.5 (96.3–96.7)
Graft survival after first kidney transplantation (deceased donor)
Unadjusted	90.9 (90.5–91.2)	88.1 (87.8–88.5)	78.9 (78.5–79.3)	91.1 (90.8–91.3)	88.1 (87.7–88.4)
Adjusted^b	91.8 (91.4–92.1)	89.3 (88.9–89.7)	80.7 (80.2–81.2)	92.4 (92.1–92.7)	89.8 (89.4–90.1)
Patient survival after first kidney transplantation (living donor)
Unadjusted	98.6 (98.3–98.8)	97.7 (97.4–98.0)	94.1 (93.6–94.6)	98.9 (98.7–99.1)	97.9 (97.6–98.2)
Adjusted^b	98.7 (98.5–99.0)	98.0 (97.7–98.3)	94.5 (94.0–95.0)	99.1 (98.9–99.2)	98.2 (98.0–98.5)
Graft survival after first kidney transplantation (living donor)
Unadjusted	95.9 (95.4–96.3)	94.1 (93.6–94.5)	87.4 (86.7–88.0)	96.5 (96.2–96.8)	94.7 (94.3–95.1)
Adjusted^b	95.6 (95.2–96.1)	93.8 (93.2–94.3)	86.6 (85.8–87.4)	96.3 (95.9–96.7)	94.4 (93.9–94.9)

This is based on data from the following renal registries providing individual patient data: Austria, Belgium (Dutch-speaking), Belgium (French-speaking), Denmark, Finland, France, Greece, Iceland, Norway, Spain (Andalusia), Spain (Aragon), Spain (Asturias), Spain (Basque country), Spain (Cantabria), Spain (Castile and León), Spain (Castile-La Mancha), Spain (Catalonia), Spain (Extremadura), Spain (Galicia), Spain (Community of Madrid), Spain (Valencian region), Sweden, the Netherlands, UK (all countries).

Analyses were adjusted using fixed values: age (67 years), gender (63% men) and primary renal disease (24% diabetes mellitus, 19% hypertension/renal vascular disease, 11% glomerulonephritis and 46% other causes).

Analyses were adjusted using fixed values: age (50 years), gender (63% men) and primary renal disease (14% diabetes mellitus, 10% hypertension/renal vascular disease, 23% glomerulonephritis and 53% other causes).

Fig. 13.

Adjusted patient survival of patients starting haemodialysis and peritoneal dialysis between 2006 and 2010 from Day 91 (left panel) and patients receiving a first transplant from a living or deceased donor between 2006 and 2010 (right panel), adjusted for age, gender and primary renal diagnosis. Survival on dialysis was adjusted using the following fixed values: age (67 years), gender (63% men) and primary renal disease (24% diabetes mellitus, 19% hypertension/renal vascular disease, 11% glomerulonephritis and 46% other causes). Survival after kidney transplantation was adjusted using the following fixed values: age (50 years), gender (63% men) and primary renal disease (14% diabetes mellitus, 10% hypertension/renal vascular disease, 23% glomerulonephritis and 53% other causes). These figures are based on data from the following registries providing individual patient data: Austria, Belgium (Dutch-speaking), Belgium (French-speaking), Denmark, Finland, France, Greece, Iceland, Norway, Spain (Andalusia), Spain (Aragon), Spain (Asturias), Spain (Basque country), Spain (Cantabria), Spain (Castile and León), Spain (Castile-La Mancha), Spain (Catalonia), Spain (Extremadura), Spain (Galicia), Spain (Community of Madrid), Spain (Valencian region), Sweden, the Netherlands and UK (all countries).

The survival probabilities at 1, 2 and 5 years by treatment modality and cohort, from Day 1 of the start of RRT/dialysis, or from the day of kidney transplantation This is based on data from the following renal registries providing individual patient data: Austria, Belgium (Dutch-speaking), Belgium (French-speaking), Denmark, Finland, France, Greece, Iceland, Norway, Spain (Andalusia), Spain (Aragon), Spain (Asturias), Spain (Basque country), Spain (Cantabria), Spain (Castile and León), Spain (Castile-La Mancha), Spain (Catalonia), Spain (Extremadura), Spain (Galicia), Spain (Community of Madrid), Spain (Valencian region), Sweden, the Netherlands, UK (all countries). Analyses were adjusted using fixed values: age (67 years), gender (63% men) and primary renal disease (24% diabetes mellitus, 19% hypertension/renal vascular disease, 11% glomerulonephritis and 46% other causes). Analyses were adjusted using fixed values: age (50 years), gender (63% men) and primary renal disease (14% diabetes mellitus, 10% hypertension/renal vascular disease, 23% glomerulonephritis and 53% other causes). Adjusted patient survival of patients starting haemodialysis and peritoneal dialysis between 2006 and 2010 from Day 91 (left panel) and patients receiving a first transplant from a living or deceased donor between 2006 and 2010 (right panel), adjusted for age, gender and primary renal diagnosis. Survival on dialysis was adjusted using the following fixed values: age (67 years), gender (63% men) and primary renal disease (24% diabetes mellitus, 19% hypertension/renal vascular disease, 11% glomerulonephritis and 46% other causes). Survival after kidney transplantation was adjusted using the following fixed values: age (50 years), gender (63% men) and primary renal disease (14% diabetes mellitus, 10% hypertension/renal vascular disease, 23% glomerulonephritis and 53% other causes). These figures are based on data from the following registries providing individual patient data: Austria, Belgium (Dutch-speaking), Belgium (French-speaking), Denmark, Finland, France, Greece, Iceland, Norway, Spain (Andalusia), Spain (Aragon), Spain (Asturias), Spain (Basque country), Spain (Cantabria), Spain (Castile and León), Spain (Castile-La Mancha), Spain (Catalonia), Spain (Extremadura), Spain (Galicia), Spain (Community of Madrid), Spain (Valencian region), Sweden, the Netherlands and UK (all countries).

Expected remaining lifetime

There remains a substantial difference in the expected remaining lifetime between the general population and those receiving dialysis (Figure 14). Patients aged 20–44 years receiving dialysis are expected to live only one-third of the estimated remaining lifetime of the age-matched general population, which is about 35 years less. The prospect is even worse for patients aged 55–64 years, as they are expected to live only a quarter as long as their age-matched counterparts in the general population (∼20 years less). Patients living with a kidney transplant fare better than those receiving dialysis. However, the life expectancy of the transplant recipients aged 20–44 years is still approximately one-third less than that of the age-matched general population (∼17 years less). With increasing age of transplant recipients the percentage disparity in life expectancy with the age-matched general population also increases.

Fig. 14.

Expected remaining lifetimes of the general population (cohort 2011–15), and of prevalent dialysis and transplant patients (cohort 2011–15), by age and gender. This figure is based on data from the following registries providing individual patient data: Austria, Belgium (Dutch-speaking), Belgium (French-speaking), Denmark, Finland, France, Greece, Iceland, Norway, Spain (Andalusia), Spain (Aragon), Spain (Asturias), Spain (Basque Country), Spain (Cantabria), Spain (Castile and León), Spain (Castile-La Mancha), Spain (Catalonia), Spain (Extremadura), Spain (Galicia), Spain (Community of Madrid), Spain (Valencian region), Sweden, the Netherlands, UK (England, Northern Ireland and Wales) and UK (Scotland).

Affiliated registries

Albanian Renal Registry (M. Barbullushi, A. Idrizi and E. Bolleku Likaj); Austrian Dialysis and Transplant Registry (OEDTR) (R. Kramar); Belarus Renal Registry (K. S. Komissarov, A. V. Kalachyk and O. V. Krasko); Dutch-speaking Belgian Society of Nephrology (NBVN) (B. De Moor, F. Schroven and J. De Meester); French-speaking Belgian Society of Nephrology (GNFB) (J. M. des Grottes and F. Collart); Renal Registry Bosnia and Herzegovina (H. Resić, M. Grujicić and S. Corić); Bulgaria (E. S. Vazelov, I. Velinova and M. Gitcheva); Croatian Registry of Renal Replacement Therapy (CRRRT) (I. Bubić, S. Rački and N. Janković); Cyprus Renal Registry (K. Ioannou and all of the renal units providing data); Czech Republic: Registry of Dialysis Patients (RDP) (I. Rychlík, J. Potucek and F. Lopot); Danish Nephrology Registry (DNS) (J. G. Heaf); Estonian Society of Nephrology (Ü. Pechter, M. Rosenberg and K. Lilienthal); Finnish Registry for Kidney Diseases (P. Finne, A. Pylsy and P. H. Groop); France: The Epidemiology and Information Network in Nephrology (REIN) (M. Lassalle and C. Couchoud); Georgian Renal Registry (N. Kantaria and Dialysis Nephrology and Transplantation Union of Georgia); Hellenic Renal Registry (N. Afentakis); Icelandic End-Stage Renal Disease Registry (R. Palsson); Israel National Registry of Renal Replacement Therapy (R. Dichtiar, T. Shohat and E. Golan); Italian Registry of Dialysis and Transplantation (RIDT): (A. Limido, M. Nordio and M. Postorino); Latvian Renal Registry (H. Cernevskis, V. Kuzema and A. Silda); Lithuanian Renal Registry (V. Kuzminskis, I. A. Bumblytė and E. Žiginskienė); Macedonian Renal Registry (L. Trpenovski, J. Masin Spasovska and O. Stojceva-Taneva); Norwegian Renal Registry (T. Leivestad, A. V. Reisæter and A. Åsberg); Polish Renal Registry (M. Klinger, B. Rutkowski and A. Dębska-Ślizień); Portuguese Renal Registry (F. Macário and A. Ferreira); Romanian Renal Registry (RRR) (G. Mircescu, L. Garneata and E. Podgoreanu); Russian Renal Regiostry (N. Tomilina, A. Andrusev and H. Zakharova); Renal Registry in Serbia (N. Maksimovic, all of the Serbian renal units and Serbian Society of Nephrology); Slovakian Renal Registry (V. Spustová, I. Lajdová and M. Karolyova); Spanish RRT National Registry at ONT, Spanish Regional Registries and Spanish Society of Nephrology (SEN) and the regional registries of Andalusia (SICATA) (P. Castro de la Nuez (on behalf of all users of SICATA), Aragon (J. I. Sanchez Miret and J. M. Abad Diez), Asturias (R. Alonso de la Torre, J. R. Quirós and RERCA Working Group), Basque country (UNIPAR) (Á. Magaz, J. Aranzabal, M. Rodrigo and I. Moina), Cantabria (A. L. M. de Francisco, O. Garcia Ruiz and C. Piñera Haces), Castile and León (R. González and C. Fernández-Renedo), Castile-La Mancha (G. Gutiérrez Ávila and I. Moreno Alía), Catalonia (RMRC) (E. Arcos, J. Comas and J. Tort), Extremadura (J. M. Ramos Aceitero and M. A. García Bazaga), Galicia (E. Bouzas-Caamaño and J. Sánchez-Ibáñez), Community of Madrid (M. I. Aparicio de Madre), Renal Registry of the Region of Murcia (C. Santiuste de Pablos and I. Marín Sánchez), Navarre (M. F. Slon Roblero, J. Manrique Escola and J. Arteaga Coloma) and the Valencian region (REMRENAL) (M. Ferrer Alamar, N. Fuster Camarena and J. Pérez Penadés); Swedish Renal Registry (SNR) (K. G. Prütz, M. Stendahl, M. Evans, S. Schön, T. Lundgren and M. Segelmark); Swiss Dialysis Registry (P. Ambühl and R. Winzeler); Dutch Renal Registry (RENINE) (L. Heuveling, S. Vogelaar and M. Hemmelder); Tunisia, Sfax region (D. Zalila, H. Mahfoud and F. Jarraya); Registry of the Nephrology, Dialysis and Transplantation in Turkey (TSNNR) (G. Süleymanlar, N. Seyahi and K. Ateş); Ukrainian Renal Data System (URDS) (M. Kolesnyk, S. Nikolaenko and O. Razvazhaieva); United Kingdom Renal Registry (UKRR) (all the staff of the UK Renal Registry and of the renal units submitting data); Scottish Renal Registry (SRR) (all of the Scottish renal units).

ERA-EDTA Registry Committee Members

C. Zoccali, Italy (ERA-EDTA President); Z. A. Massy, France (Chairman); F. J. Caskey, UK; C. Couchoud, France; M. Evans, Sweden; P. Finne, Finland; J. W. Groothoff, The Netherlands; J. Harambat, France; J. G. Heaf, Denmark; F. Jarraya, Tunisia; M. Nordio, Italy; and I. Rychlik, Czech Republic.

ERA-EDTA Registry Office Staff

K. J. Jager (Managing Director), M. Bonthuis (for the paediatric section), R. Cornet, G. Guggenheim, A. Kramer, M. Noordzij, M. Pippias, V. S. Stel and A. J. Weerstra.

3 in total

1. Renal replacement therapy in Europe: a summary of the 2012 ERA-EDTA Registry Annual Report.

Authors: Maria Pippias; Vianda S Stel; José Maria Abad Diez; Nikolaos Afentakis; Jose Antonio Herrero-Calvo; Manuel Arias; Natalia Tomilina; Encarnación Bouzas Caamaño; Jadranka Buturovic-Ponikvar; Svjetlana Čala; Fergus J Caskey; Pablo Castro de la Nuez; Harijs Cernevskis; Frederic Collart; Ramón Alonso de la Torre; Maria de Los Ángeles García Bazaga; Johan De Meester; Joan Manuel Díaz; Ljubica Djukanovic; Manuel Ferrer Alamar; Patrik Finne; Liliana Garneata; Eliezer Golan; Raquel González Fernández; Gonzalo Gutiérrez Avila; James Heaf; Andries Hoitsma; Nino Kantaria; Mykola Kolesnyk; Reinhard Kramar; Anneke Kramer; Mathilde Lassalle; Torbjørn Leivestad; Frantisek Lopot; Fernando Macário; Angela Magaz; Eduardo Martín-Escobar; Wendy Metcalfe; Marlies Noordzij; Runolfur Palsson; Ülle Pechter; Karl G Prütz; Marina Ratkovic; Halima Resić; Boleslaw Rutkowski; Carmen Santiuste de Pablos; Viera Spustová; Gültekin Süleymanlar; Karlijn Van Stralen; Nestor Thereska; Christoph Wanner; Kitty J Jager
Journal: Clin Kidney J Date: 2015-03-23

2. Renal replacement therapy in Europe: a summary of the 2013 ERA-EDTA Registry Annual Report with a focus on diabetes mellitus.

Authors: Anneke Kramer; Maria Pippias; Vianda S Stel; Marjolein Bonthuis; José Maria Abad Diez; Nikolaos Afentakis; Ramón Alonso de la Torre; Patrice Ambuhl; Boris Bikbov; Encarnación Bouzas Caamaño; Ivan Bubic; Jadranka Buturovic-Ponikvar; Fergus J Caskey; Pablo Castro de la Nuez; Harijs Cernevskis; Frederic Collart; Jordi Comas Farnés; Maria de Los Ángeles Garcia Bazaga; Johan De Meester; Manuel Ferrer Alamar; Patrik Finne; Liliana Garneata; Eliezer Golan; James G Heaf; Marc Hemmelder; Kyriakos Ioannou; Nino Kantaria; Mykola Kolesnyk; Reinhard Kramar; Mathilde Lassalle; Visnja Lezaic; Frantisek Lopot; Fernando Macário; Angela Magaz; Eduardo Martín-Escobar; Wendy Metcalfe; Mai Ots-Rosenberg; Runolfur Palsson; Celestino Piñera Celestino; Halima Resić; Boleslaw Rutkowski; Carmen Santiuste de Pablos; Viera Spustová; Maria Stendahl; Ariana Strakosha; Gültekin Süleymanlar; Marta Torres Guinea; Anna Varberg Reisæter; Evgueniy Vazelov; Edita Ziginskiene; Ziad A Massy; Christoph Wanner; Kitty J Jager; Marlies Noordzij
Journal: Clin Kidney J Date: 2016-01-31

3. The European Renal Association - European Dialysis and Transplant Association Registry Annual Report 2014: a summary.

Authors: Maria Pippias; Anneke Kramer; Marlies Noordzij; Nikolaos Afentakis; Ramón Alonso de la Torre; Patrice M Ambühl; Manuel I Aparicio Madre; Felipe Arribas Monzón; Anders Åsberg; Marjolein Bonthuis; Encarnación Bouzas Caamaño; Ivan Bubic; Fergus J Caskey; Pablo Castro de la Nuez; Harijs Cernevskis; Maria de Los Ángeles Garcia Bazaga; Jean-Marin des Grottes; Raquel Fernández González; Manuel Ferrer-Alamar; Patrik Finne; Liliana Garneata; Eliezer Golan; James G Heaf; Marc H Hemmelder; Alma Idrizi; Kyriakos Ioannou; Faical Jarraya; Nino Kantaria; Mykola Kolesnyk; Reinhard Kramar; Mathilde Lassalle; Visnja V Lezaic; Frantisek Lopot; Fernando Macario; Ángela Magaz; Angel L Martín de Francisco; Eduardo Martín Escobar; Alberto Martínez Castelao; Wendy Metcalfe; Inmaculada Moreno Alia; Maurizio Nordio; Mai Ots-Rosenberg; Runolfur Palsson; Marina Ratkovic; Halima Resic; Boleslaw Rutkowski; Carmen Santiuste de Pablos; Nurhan Seyahi; María Fernanda Slon Roblero; Viera Spustova; Koenraad J F Stas; María E Stendahl; Olivera Stojceva-Taneva; Evgueniy Vazelov; Edita Ziginskiene; Ziad Massy; Kitty J Jager; Vianda S Stel
Journal: Clin Kidney J Date: 2017-01-16

3 in total

54 in total

1. Prostate Cancer Screening and Management in Solid Organ Transplant Candidates and Recipients.

Authors: Ezequiel Becher; Alex Wang; Herbert Lepor
Journal: Rev Urol Date: 2019

Review 2. Coronary artery disease in dialysis patients: evidence synthesis, controversies and proposed management strategies.

Authors: Alexandru Burlacu; Simonetta Genovesi; Carlo Basile; Alberto Ortiz; Sandip Mitra; Dimitrios Kirmizis; Mehmet Kanbay; Andrew Davenport; Frank van der Sande; Adrian Covic
Journal: J Nephrol Date: 2020-05-29 Impact factor: 3.902

3. Podocyte histone deacetylase activity regulates murine and human glomerular diseases.

Authors: Kazunori Inoue; Geliang Gan; Maria Ciarleglio; Yan Zhang; Xuefei Tian; Christopher E Pedigo; Corey Cavanaugh; Janet Tate; Ying Wang; Elizabeth Cross; Marwin Groener; Nathan Chai; Zhen Wang; Amy Justice; Zhenhai Zhang; Chirag R Parikh; Francis P Wilson; Shuta Ishibe
Journal: J Clin Invest Date: 2019-02-18 Impact factor: 14.808

4. Association between anemia and mortality in hemodialysis patients is modified by the presence of diabetes.

Authors: Yukio Maruyama; Eiichiro Kanda; Kan Kikuchi; Masanori Abe; Ikuto Masakane; Takashi Yokoo; Kosaku Nitta
Journal: J Nephrol Date: 2021-02-08 Impact factor: 3.902

5. New Onset Diabetes Mellitus after Transplant: The Challenge Continues.

Authors: Fahad Aziz
Journal: Kidney360 Date: 2021-08-26

6. Employment Status and Work Functioning among Kidney Transplant Recipients.

Authors: Tim J Knobbe; Daan Kremer; Femke I Abma; Coby Annema; Stefan P Berger; Gerjan J Navis; Sijrike F van der Mei; Ute Bültmann; Annemieke Visser; Stephan J L Bakker
Journal: Clin J Am Soc Nephrol Date: 2022-09-26 Impact factor: 10.614

7. Utility of Genomic Testing after Renal Biopsy.

Authors: Susan L Murray; Anthony Dorman; Katherine A Benson; Dervla M Connaughton; Caragh P Stapleton; Neil K Fennelly; Claire Kennedy; Ciara A McDonnell; Kendrah Kidd; Sarah M Cormican; Louise A Ryan; Peter Lavin; Mark A Little; Anthony J Bleyer; Brendan Doyle; Gianpiero L Cavalleri; Friedhelm Hildebrandt; Peter J Conlon
Journal: Am J Nephrol Date: 2019-12-10 Impact factor: 3.754

8. Sex Differences in Kidney Replacement Therapy Initiation and Maintenance.

Authors: Marlies Antlanger; Marlies Noordzij; Moniek van de Luijtgaarden; Juan Jesus Carrero; Runolfur Palsson; Patrik Finne; Marc H Hemmelder; Nuria Aresté-Fosalba; Anna Varberg Reisæter; Aleix Cases; Jamie P Traynor; Reinhard Kramar; Ziad Massy; Kitty J Jager; Manfred Hecking
Journal: Clin J Am Soc Nephrol Date: 2019-10-24 Impact factor: 8.237

9. Novel nephronophthisis-associated variants reveal functional importance of MAPKBP1 dimerization for centriolar recruitment.

Authors: Ria Schönauer; Wenjun Jin; Anastasia Ertel; Melanie Nemitz-Kliemchen; Nydia Panitz; Elena Hantmann; Anna Seidel; Daniela A Braun; Shirlee Shril; Matthias Hansen; Khurrum Shahzad; Richard Sandford; Sophie Saunier; Alexandre Benmerah; Carsten Bergmann; Friedhelm Hildebrandt; Jan Halbritter
Journal: Kidney Int Date: 2020-06-04 Impact factor: 10.612

10. Exploring the relation between mortality and left ventricular structure and function in stable hemodialysis treated patients, a longitudinal multicenter cohort study.

Authors: Lazar A Chisavu; Adrian Apostol; Gheorghe N Pop; Viviana Ivan; Oana Schiller; Flaviu Bob; Luciana Marc; Adelina Mihaescu; Florica Gadalean; Iulia Grosu; Bogdan Timar; Adalbert Schiller
Journal: Sci Rep Date: 2021-06-16 Impact factor: 4.379