Primary aldosteronism is common and contributes to adverse cardiovascular, kidney, and metabolic outcomes. When instituted early and effectively, targeted therapies can mitigate these adverse outcomes. Surgical adrenalectomy is among the most effective treatments because it has the potential to cure, or attenuate the severity of, pathologic aldosterone excess, resulting in a host of biochemical and clinical changes that improve health outcomes. Herein, we review the role of surgical adrenalectomy in primary aldosteronism while emphasizing the physiologic ramifications of surgical intervention, and compare these to other targeted medical therapies for primary aldosteronism. We specifically review the role of curative adrenalectomy for unilateral primary aldosteronism, the role of non-curative adrenalectomy for bilateral primary aldosteronism, and how these interventions influence biochemical and clinical outcomes in relation to medical therapies for primary aldosteronism.
Gregory L Hundemer and Anand Vaidya
Alessia Cozzolino, Tiziana Feola, Ilaria Simonelli, Giulia Puliani, Valeria Hasenmajer, Marianna Minnetti, Elisa Giannetta, Daniele Gianfrilli, Patrizio Pasqualetti, Andrea Lenzi, and Andrea M Isidori
Neurosurgery is the first-line treatment for acromegaly. Whether metabolic disorders are reversible after neurosurgery is still debated. The meta-analysis aimed to address the following questions: (i) Does neurosurgery affect glycolipid metabolism? (ii) Are these effects related to disease control or follow-up length?
A meta-analysis and systematic review of the literature.
Three reviewers searched databases until August 2019 for prospective trials reporting glycometabolic outcomes after neurosurgery. Three other extracted outcomes, all assessed the risk of bias.
Twenty studies were included. Neurosurgery significantly reduced fasting plasma glucose (FPG) (effect size (ES): −0.57 mmol/L, 95% CI: −0.82 to −0.31; P < 0.001), glucose load (ES: −1.10 mmol/L, 95% CI: −1.66 to −0.53; P < 0.001), glycosylated haemoglobin (HbA1c) (ES: −0.28%, 95% CI: −0.42 to −0.14; P < 0.001), fasting plasma insulin (FPI) (ES: −10.53 mU/L, 95% CI: −14.54 to −6.51; P < 0.001), homeostatic model assessment of insulin resistance (HOMA-IR) (ES: −1.98, 95% CI: −3.24 to −0.72; P = 0.002), triglycerides (TGDs) (ES: −0.28 mmol/L, 95% CI: −0.36 to −0.20; P < 0.001) and LDL-cholesterol (LDLC) (ES: −0.23 mmol/L, 95% CI: −0.45 to −0.02 mmol/L); P = 0.030) and increased HDL-cholesterol (HDLC) (ES: 0.21 mmol/L, 95% CI: 0.14 to 0.28; P < 0.001). Meta-regression analysis showed that follow-up length – not disease control – had a significant effect on FPG, with the greatest reduction in the shortest follow-up (beta = 0.012, s.e. = 0.003; P = 0.001).
Neurosurgery improves metabolism with a significant decrease in FPG, glucose load, HbA1c, FPI, HOMA-IR, TGDs, and LDLC and increase in HDLC. The effect on FPG seems to be more related to follow-up length than to disease control.
France Devuyst, Paraskevi Kazakou, Danielle Balériaux, Orsalia Alexopoulou, Agnès Burniat, Sylvie Salenave, Philippe Chanson, Bernard Corvilain, and Dominique Maiter
Claire L Wood, Michael Cole, Malcolm Donaldson, David B Dunger, Ruth Wood, Niamh Morrison, John N S Matthews, Simon H S Pearce, Timothy D Cheetham, and the British Society for Paediatric Endocrinology and Diabetes (BSPED)
First-line treatment of thyrotoxicosis in young people is thionamide anti-thyroid drug (ATD) in a blocking dose with levothyroxine replacement (block and replace, BR) or in a smaller dose tailored to render the patient euthyroid (dose titration, DT). Our objective was to determine which regimen provides more stable biochemical control.
A multi-centre phase III, open-label randomised trial comparing BR with DT in patients aged 2–17 years with newly diagnosed thyrotoxicosis at 15 UK centres.
Patients were randomised shortly after diagnosis and treated for 3 years. The primary outcome was the percentage of serum thyroid-stimulating hormone (TSH) levels in the reference range between 6 months and 3 years. Secondary outcomes included the proportion of Free thyroxine (FT4) levels in the reference range, adverse event frequency and 4 years outcome (remission/relapse).
Eighty-two patients were randomised, with details on clinical course in 81 (62 Female); 40 were allocated to BR (41 DT). Three withdrew with one ineligible. The mean percentage of serum TSH within reference range was 60.2% in BR and 63.8% in DT patients; adjusted difference 4.3%, 95% CI (−7.8 to 16.4); P = 0.48. Proportions for FT4 were 79.2% in BR and 85.7% in DT patients; adjusted difference 6.8%, (−0.2 to 15.6); P = 0.13. Three patients developed neutropenia – all on BR. 6 BR and 10 DT patients were in remission at 4y.
This randomised trial has shown no evidence to suggest that BR, when managing the young patient with thyrotoxicosis, is associated with improved biochemical stability when compared to DT.
Emily Cottrell, Claudia P Cabrera, Miho Ishida, Sumana Chatterjee, James Greening, Neil Wright, Artur Bossowski, Leo Dunkel, Asma Deeb, Iman Al Basiri, Stephen J Rose, Avril Mason, Susan Bint, Joo Wook Ahn, Vivian Hwa, Louise A Metherell, Gudrun E Moore, and Helen L Storr
Copy number variation (CNV) has been associated with idiopathic short stature, small for gestational age and Silver-Russell syndrome (SRS). It has not been extensively investigated in growth hormone insensitivity (GHI; short stature, IGF-1 deficiency and normal/high GH) or previously in IGF-1 insensitivity (short stature, high/normal GH and IGF-1).
Design and methods
Array comparative genomic hybridisation was performed with ~60 000 probe oligonucleotide array in GHI (n = 53) and IGF-1 insensitivity (n = 10) subjects. Published literature, mouse models, DECIPHER CNV tracks, growth associated GWAS loci and pathway enrichment analyses were used to identify key biological pathways/novel candidate growth genes within the CNV regions.
Both cohorts were enriched for class 3–5 CNVs (7/53 (13%) GHI and 3/10 (30%) IGF-1 insensitivity patients). Interestingly, 6/10 (60%) CNV subjects had diagnostic/associated clinical features of SRS. 5/10 subjects (50%) had CNVs previously reported in suspected SRS: 1q21 (n = 2), 12q14 (n = 1) deletions and Xp22 (n = 1), Xq26 (n = 1) duplications. A novel 15q11 deletion, previously associated with growth failure but not SRS/GHI was identified. Bioinformatic analysis identified 45 novel candidate growth genes, 15 being associated with growth in GWAS. The WNT canonical pathway was enriched in the GHI cohort and CLOCK was identified as an upstream regulator in the IGF-1 insensitivity cohorts.
Our cohort was enriched for low frequency CNVs. Our study emphasises the importance of CNV testing in GHI and IGF-1 insensitivity patients, particularly GHI subjects with SRS features. Functional experimental evidence is now required to validate the novel candidate growth genes, interactions and biological pathways identified.
Anna-Maria Eleftheriadou, Sebastian Mehl, Kostja Renko, Rega H Kasim, Jasmin-Annabelle Schaefer, Waldemar B Minich, and Lutz Schomburg
Iodide transport across thyrocytes constitutes a critical step for thyroid hormone biosynthesis, mediated mainly by the basolateral sodium-iodide-symporter (NIS (SLC5A5)) and the apical anion exchanger pendrin (PDS (SLC26A4)). Both transmembrane proteins have been described as autoantigens in thyroid disease, yet the reports on autoantibody (aAb) prevalence and diagnostic usefulness are conflicting. Reasons for the inconclusive findings may be small study groups and principle differences in the technologies used.
We decided to re-evaluate this important issue by establishing novel non-radioactive tests using full-length antigens and comparable protocols, and analyzing a large cohort of thyroid patients (n = 323) and control samples (n = 400).
NIS and PDS were recombinantly expressed as fusion protein with firefly luciferase (Luc). Stably transfected HEK293 cells were used as reproducible source of the autoantigens.
Recombinant NIS-Luc showed iodide transport activity, indicating successful expression and correct processing. Commercial antibodies yielded dose-dependent responses in the newly established assays. Reproducibility of assay signals from patient sera was verified with respect to linearity, stability and absence of matrix effects. Prevalence of PDS-aAb was similar in thyroid patients and controls (7.7% vs 5.0%). NIS-aAb were more prevalent in patients than controls (7.7% vs 1.8%), especially in Graves’ Disease (12.3%). Neither NIS-aAb nor PDS-aAb concentrations were related to TPO-aAb or TSH-receptor-aAb concentrations, or to serum zinc or selenium status.
Our data highlight a potential relevance of autoimmunity against NIS for thyroid disease, whereas an assessment of PDS-aAb in thyroid patients seems not to be of diagnostic value (yet).
Shirui Wang, Xiang Zhou, and Huijuan Zhu
Robin Michelet, Johanna Melin, Zinnia P Parra‐Guillen, Uta Neumann, Martin J Whitaker, Viktoria Stachanow, Wilhelm Huisinga, John Porter, Oliver Blankenstein, Richard J Ross, and Charlotte Kloft
Olaf M Dekkers and Rolf H H Groenwold
The name of the study should properly reflect the actual conduct and analysis of the study. This short paper provides guidance on how to properly name the study design. The first distinction is between a trial (intervention given to patients to study its effect) and an observational study. For observational studies, it should further be decided whether it is cross-sectional or whether follow-up time is taken into account (cohort or case–control study). The distinction prospective-retrospective has two disadvantages: prospective is often seen as marker of higher quality, which is not necessarily true; there is no unifying definition that makes a proper distinction between retrospective and prospective possible.
Juho Kärkinen, Päivi J Miettinen, Taneli Raivio, and Matti Hero
To describe the etiology of severe short stature in the Helsinki University Hospital district covering a population of 1.2 million that is subject to frequent growth monitoring and screening rules during childhood.
Retrospective cohort study.
We identified all subjects born 1990 or later with a height SD score <−3, after the age of 3 years, from the Helsinki University Hospital district growth database. A total of 785 subjects (376 females and 409 males) fulfilled our inclusion criteria; we reviewed their medical records and growth data and report their underlying diagnoses.
A pathological cause for short stature was diagnosed in 76% of the girls and 71% of the boys (P = NS). Syndromes were the most numerous pathological cause (n = 160; 20%), followed by organ disorders (n = 127; 16%), growth hormone deficiency (GHD, n = 94; 12%), SGA without catch-up growth (n = 73; 9%), and skeletal dysplasias (n = 57; 7%). Idiopathic short stature (ISS) was diagnosed in 210 (27%) subjects. The probability of growth-related pathology, particularly of a syndrome or skeletal dysplasia, increased with the shorter height SD score and the greater deviation from the target height. Sitting height to height SDS was increased in subjects with ISS, GHD, and SGA (all P < 0.01).
Height <−3 SDS after 3 years of age usually results from a pathological cause and should be thoroughly investigated in specialized health care. The chance of finding a specific etiology increased with the severity of short stature, and the mismatch with target height.