Skip to main content
BMJ Open Access logoLink to BMJ Open Access
. 2014 Nov 14;90(1070):694–698. doi: 10.1136/postgradmedj-2014-132885

Multicentre study of investigation and management of inpatient hyponatraemia in the UK

Ploutarchos Tzoulis 1, Rhys Evans 2, Agnieszka Falinska 3, Maria Barnard 4, Tricia Tan 3, Emma Woolman 5, Rebecca Leyland 5, Nick Martin 5, Rebecca Edwards 6, Rebecca Scott 7, Kalyan Gurazada 1, Marie Parsons 6, Devaki Nair 5, Bernard Khoo 1, Pierre Marc Bouloux 1
PMCID: PMC4283616  PMID: 25398584

Abstract

Purpose

Hyponatraemia is associated with significant morbidity and mortality. The objectives of this study were to evaluate the investigation and management of hyponatraemia and to assess the use of different therapeutic modalities and their effectiveness in routine practice.

Study design

This multicentre, retrospective, observational study was conducted at three acute NHS Trusts in March 2013. A retrospective chart review was performed on the first 100 inpatients with serum sodium (sNa) ≤128 mmol/L during hospitalisation.

Results

One hundred patients (47 male, 53 female) with a mean±SD age of 71.3±15.4 years and nadir sNa of 123.4±4.3 mmol/L were included. Only 23/100 (23%) had measurements of paired serum and urine osmolality and sodium, while 31% had an assessment of adrenal reserve. The aetiology of hyponatraemia was unrecorded in 58% of cases. The mean length of hospital stay was 17.5 days with an inpatient mortality rate of 16%. At hospital discharge, 53/84 (63.1%) patients had persistent hyponatraemia, including 20/84 (23.8%) with sNa <130 mmol/L. Overall 37/100 (37%) patients did not have any treatment for hyponatraemia. Among 76 therapeutic episodes, the most commonly used treatment modalities were isotonic saline in 38/76 cases (50%) and fluid restriction in 16/76 (21.1%). Fluid restriction failed to increase sNa by >1 mmol/L/day in 8/10 (80%) cases compared with 4/26 (15.4%) for isotonic saline.

Conclusions

Underinvestigation and undertreatment of hyponatraemia is a common occurrence in UK clinical practice. Therefore, development of UK guidelines and introduction of electronic alerts for hyponatraemia should be considered to improve clinical practice.

Introduction

Hyponatraemia, defined as serum sodium (sNa) concentration below 135 mmol/L, is the most common electrolyte abnormality encountered in hospitalised patients, with a reported incidence of 30–42%.1 2 Hyponatraemia is an independent risk factor for mortality3 4 and is associated with an increase in length of hospital stay5 and hospital resource utilisation.6

Accurate diagnosis of hyponatraemia is necessary to guide effective treatment. However, numerous single-centre studies in the UK have consistently reported underutilisation of appropriate biochemical tests in the investigation of hyponatraemia.7–13 It is unclear to what extent inadequate investigation of hyponatraemia reflects UK clinical practice in general. There is also a paucity of data about the utilisation of different therapeutic modalities for hyponatraemia and their efficacy in a real world setting.

This study describes current clinical practice in three acute UK hospitals. The objectives were to evaluate the investigation and management of inpatient hyponatraemia and to assess the use of different therapeutic modalities and their effectiveness.

Methods

Study design

This was a multicentre, retrospective, observational study examining the investigation and management of 100 consecutive inpatients with serum sodium (sNa) ≤128 mmol/L.

Recruitment started on 1 March 2013 and ended on 28 March 2013 when a total of 100 patients were reached. It was conducted simultaneously at three acute NHS Trusts in London: centre 1, an 850-bed teaching hospital; centre 2, including 850 beds across two teaching hospitals; and centre 3, a 450-bed district general hospital. None of the three institutions had local guidelines for the management of hyponatraemia.

Patient selection

We defined inpatient hyponatraemia as an sNa concentration ≤128 mmol/L at any point during hospital admission. Patients were identified through an automated laboratory database search. A cut-off of 128 mmol/L was selected because previous data from this hospital cohort showed an upward inflection in inpatient mortality below that threshold.3 Subjects with hyperglycaemia were included only if their corrected sNa was ≤128 mmol/L. If venous glucose was 15–24.4 mmol/L, sNa was corrected by 1.6 mmol/L for every 5.6 mmol/L increase in glucose concentration above 7 mmol/L; if glucose was >24.4 mmol/L, a correction factor of 2.4 mmol/L was used.14

Data collection

Hospital case notes, laboratory results, drug prescription charts and discharge letters were retrospectively reviewed for each patient after hospital discharge. Data were collected on age, gender, speciality responsible for each patient, drug history, admission to the intensive care unit, length of hospital stay, outcome of admission, investigations and documented cause of hyponatraemia, sNa levels at various time points, use of therapeutic modalities, sNa 24 and 72 h after initiation of treatment, and sNa at hospital discharge.

Adequate investigation of hyponatraemia should include clinical assessment of volume status, measurement of paired serum and urine osmolality and Na, thyroid function tests and serum cortisol measurement. The effectiveness of treatment of hyponatraemia was assessed by sNa concentration at hospital discharge. For the purpose of evaluating the effectiveness of different treatment modalities, ‘clear failure’ of treatment was defined as a total sNa increase of ≤3 mmol/L after the 72 h period after initiation of therapy. Over-rapid correction of hyponatraemia, known to risk osmotic demyelination syndrome,15 16 was defined as an sNa increase of >12 mmol/L in 24 h.

Data analysis

All data were recorded on an Access database and then transferred into an Excel spreadsheet. Data were analysed separately for each hospital and for all three hospitals together. Data were summarised using descriptive statistics, with continuous variables being expressed as mean±SD, and categorical variables as percentages.

Adequacy of investigation was assessed by the percentage of patients who underwent each of the recommended tests. The proportion of patients with normonatraemia and different degrees of hyponatraemia (mild/moderate/severe) was used to determine the effectiveness of management of hyponatraemia. The percentage of patients who had ‘clear failure’ and ‘over-rapid correction’ determined the effectiveness of each therapeutic modality.

Results

Demographic characteristics

Across three hospitals in London, 100 patients (47 male, 53 female) were included with a mean±SD age of 71.3±15.4 years. Centre 1 included 38 patients (19 male, 19 female with a mean age of 73.6±15.1 years), centre 2 contributed 30 patients (13 male, 17 female aged 68.5±15.5 years) and centre 3 contributed 32 patients (15 male, 17 female with a mean age of 70.4±15.4 years).

The mean sNa on admission was 128.1±7.1 mmol/L, and the lowest sNa during hospitalisation was 123.4±4.3 mmol/L. In terms of the time point of onset of hyponatraemia, 58/100 (58%) patients presented on admission with sNa ≤128 mmol/L in comparison with 42/100 (42%) who developed sNa ≤128 mmol/L during hospitalisation.

Speciality distribution

There was a wide distribution of patients within different specialities: 81/100 (81%) patients were under the care of medical specialities including geriatrics (18%), general medicine (11%), respiratory (9%), gastroenterology (9%), oncology (6%), hepatology (6%), cardiology (5%), infectious diseases (5%), endocrinology (4%), nephrology (3%), neurology (3%) and rheumatology (2%); 19/100 (19%) patients were under the care of surgical specialities including general surgery (5%), urology (5%), orthopaedics (4%), cardiothoracic surgery (3%) and gynaecology (2%).

Drug history

Of the 100 patients, 35 were taking ACE inhibitors, 23 loop diuretics, 22 thiazide diuretics, 15 selective serotonin reuptake inhibitors (SSRIs), 14 potassium-sparing diuretics, 12 angiotensin-II receptor antagonists, and 6 tricyclic antidepressants.

Outcome of admission

The inpatient mortality rate in our cohort was 16%. The mean length of hospital stay was 17.5±14.8 days with 9/100 (9%) of patients requiring admission to the intensive care unit.

Diagnostic work-up

Clinical assessment of volume status was documented in 62/100 (62%) cases, while paired serum and urine osmolality and Na were measured in 23/100 (23%). Complete work-up was undertaken in 18/100 (18%) patients, as shown in table 1.

Table 1.

Investigation of patients with hyponatraemia

Total Centre 1 Centre 2 Centre 3
Investigation (N=100) (%) (N=38) (%) (N=30) (%) (N=32) (%)
Volume status 62 71.0 53.4 59.4
Serum osmolality 39 39.5 33.3 43.8
Urine osmolality 33 39.5 30.0 28.1
Urine Na 29 34.2 36.6 15.6
Paired osmolality–Na 23 26.3 26.7 15.6
Serum TSH 61 71.0 63.3 46.9
Serum cortisol 31 34.2 26.6 31.2
Full work-up 18 23.7 20.0 9.4
Expert input 16 13.1 13.3 21.8

TSH, thyroid-stimulating hormone.

Aetiology of hyponatraemia

The aetiology of hyponatraemia was unrecorded in the notes of 58/100 (58%) patients. Review of case notes was used to ascertain the aetiology of hyponatraemia in the remaining 42/100 (42%) patients, as summarised in table 2. Syndrome of inappropriate antidiuretic hormone secretion (SIADH) was attributed to drugs in three cases (SSRIs in two cases and mirtazapine in one case), to malignancy in two cases (small cell lung cancer in one case and chronic lymphocytic leukaemia in one case) and to miscellaneous causes in two cases (SIADH after transsphenoidal surgery and SIADH of unknown cause).

Table 2.

Classification of cases according to documented aetiology of hyponatraemia

Aetiology Overall
(N=42), n (%)
Hypovolaemic 23 (54.7)
 Gastrointestinal Na losses 9 (21.4)
 Poor oral intake 7 (16.6)
 Diuretics 6 (14.3)
 Adrenal insufficiency 1 (2.4)
Euvolaemic 11 (26.2)
 SIADH due to pneumonia 4 (9.5)
 Drug-induced SIADH 3 (7.1)
 Malignant SIADH 2 (4.8)
 Miscellaneous causes 2 (4.8)
Hypervolaemic 8 (19.1)
 Decompensated cirrhosis 4 (9.5)
 Heart failure 4 (9.5)

SIADH, Syndrome of inappropriate antidiuretic hormone secretion.

Only 6/11 (54%) patients diagnosed with SIADH had all the essential tests performed, including clinical assessment of volume status, measurement of paired serum and urine osmolality and Na, and assessment of thyroid and adrenal function.17 18

Effectiveness of treatment of hyponatraemia

Correction of sNa ≥130 mmol/L was observed in 70/84 (83.3%) patients at some point during admission, but hyponatraemia with sNa <130 mmol/L recurred in 6/84 (7.1%). A significant proportion of patients (53/84 equal to 63.1%) had persistent hyponatraemia at discharge from hospital, as shown in table 3.

Table 3.

Serum sodium (sNa) concentration at hospital discharge

SNa at discharge Overall
N=84
Patients with sNa <125 mmol/L (%) 4.8
Patients with sNa 125–129 mmol/L (%) 19.0
Patients with sNa 130–134 mmol/L (%) 39.3
Patients with sNa ≥135 mmol/L (%) 36.9
Mean±SD sNa (mmol/L) 132.8±4.7

Utilisation of treatment modalities

Overall, 37/100 (37%) patients did not have any treatment for hyponatraemia. Of the 63 patients treated for hyponatraemia, 53 received one therapeutic modality, 7 received two modalities, and 3 received three treatment modalities. First-line therapy was isotonic saline in 34/63 (54%) cases, discontinuation of potentially offending drugs in 16/63 (25.4%), fluid restriction in 10/63 (15.9%), infusion of human albumin solution in 2/63 (3.2%), and initiation of hydrocortisone replacement in 1/63 (1.5%) cases. Second-line therapy was isotonic saline in 4/10 (40%) cases, fluid restriction in 4/10 (40%), and hypertonic saline in 2/10 (20%). Only three patients received third-line treatment, including two cases of fluid restriction and one case of demeclocycline.

Potentially offending drugs were discontinued in 36/100 (36%) patients, with the most common being ACE inhibitors or angiotensin-II receptor antagonists (18%), loop diuretics (15%), thiazide diuretics (10%), potassium-sparing diuretics (10%) and SSRIs (3%).

In total, 76 episodes of treatment were recorded, which included isotonic saline in 38/76 (50%) cases, drug discontinuation in 16/76 (21.1%), fluid restriction in 16/76 (21.1%), hypertonic saline in 2/76 (2.6%), human albumin solution in 2/76 (2.6%), hydrocortisone replacement in 1/76 (1.3%) and demeclocycline in 1/76 (1.3%) cases. Use of other drug therapies for SIADH, such as tolvaptan, urea or combination of loop diuretics with oral sodium chloride, was not recorded.

Effectiveness of isotonic saline and fluid restriction

‘Clear failure’ of treatment with a total sNa increase of ≤3 mmol/L after the 72 h period after initiation of therapy was recorded in 4/26 (15.4%) patients treated with isotonic saline compared with 8/10 (80%) individuals managed with fluid restriction, as illustrated in table 4. Fluid restriction was imposed on 16 patients with various volumes prescribed per 24 h (1500 mL in 4 cases, 1000 mL in 9 cases, 750 mL in 1 case and 500 mL in 2 cases). Hypertonic saline was used in two patients, with infusion of 1000 mL saline 1.8% over 18 h increasing sNa by 13 mmol/L, and 300 mL saline 1.8% over 8 h increasing sNa levels by 11 mmol/L.

Table 4.

Effectiveness of isotonic saline and fluid restriction in correcting hyponatraemia in first 72 h

SNa correction after treatment Isotonic saline (N=26) Fluid restriction (N=10)
Mean±SD change in sNa (mmol/L) 7.3±5.0 2.8±3.2
Percentage of patients
 sNa increase <2 mmol/L 7.7 30.0
 sNa increase 2–3 mmol/L 7.7 50.0
 sNa increase 4–8 mmol/L 50.0 10.0
 sNa increase 9–12 mmol/L 19.2 10.0
 sNa increase >12 mmol/L 15.4 0

Over-rapid correction of hyponatraemia (sNa increase of >12 mmol/L/day) was recorded in 3/76 (3.9%) therapeutic episodes. All three patients, two treated with isotonic saline and one with hypertonic saline, had an sNa increase of 13 mmol/L within 24 h without any adverse neurological sequelae.

Discussion

We found that hyponatraemia was frequently underinvestigated, underdiagnosed and suboptimally managed in routine practice in three hospitals in London. Urine Na, the most important biochemical test19 20 in investigation of hyponatraemia, was measured in less than one-third of cases. The underlying aetiology of hyponatraemia, despite being essential to guide appropriate treatment, was unrecorded in more than half of the cases. The limited effectiveness of current management, with 63.1% of patients being discharged with persistent hyponatraemia, was not surprising considering the lack of treatment for hyponatraemia in a substantial proportion of patients. Among patients receiving treatment for hyponatraemia, isotonic saline or fluid restriction were most commonly used, with fluid restriction being ineffective in the majority of cases.

Similar results from all three hospitals indicate that insufficient diagnostic work-up and ineffective treatment of hyponatraemia may reflect UK routine care in general. There are several possible barriers to good clinical practice in this field, such as the diminished provision of undergraduate and postgraduate education in clinical chemistry in recent times,13 21 the lack of national guidelines, the absence of diagnostic algorithms and treatment pathways in most hospitals or their complexity where they exist, and the limited therapeutic options with little evidence basis for the treatment of SIADH. Besides demonstrating suboptimal standard of care for hyponatraemia, we found that fluid restriction, currently the first-line treatment for SIADH, does not correct hyponatraemia in most cases. Potential reasons are poor patient adherence because of thirst, inadequate rigour in the volume of fluid intake prescribed (which needs to be restricted to at least 500 mL/day less than urine output), and its questionable effectiveness per se given the limited evidence base behind its therapeutic value.20 22 Therefore, clinicians should pay more attention to appropriate prescription and implementation of fluid restriction and should also have access to alternative therapeutic options such as vaptans and urea.

In comparison with previous UK studies, we recorded a higher frequency of performance of appropriate diagnostic tests. In the subgroup of our cohort with a nadir sNa ≤125 mmol/L, 40.7% of patients had urine Na and 40.7% had serum cortisol measured compared with 10–18.6%7–10 and 8–15.2%,7–9 11 respectively, reported in other UK series using the same cut-off. It is unclear whether these findings represent a widespread rather than a local improvement in the investigation of hyponatraemia in recent years. Regarding the aetiology of hyponatraemia, SIADH was reported in only a quarter of our cases, in contrast with most studies suggesting it as the most common cause;18 23 24 therefore, SIADH was probably underdiagnosed.

This study has provided insight into the contemporary investigation and management of hyponatraemia in the UK. However, it had a number of limitations. First and foremost, it could not, by its design, test whether undertreatment of hyponatraemia contributed to adverse patient outcomes and, more importantly, whether correcting hyponatraemia could improve clinical outcomes. Second, the small sample size and the fact that all three hospitals are in London raise the question whether the findings apply to UK clinical practice in general. Third, its retrospective nature made accurate identification of the cause of all cases of hyponatraemia impossible. As a result, its ability to evaluate the effectiveness of different therapeutic modalities was limited because failure of treatment might sometimes reflect misdiagnosis.

In conclusion, this study highlights the need to improve clinical practice. It is essential to develop tools such as electronic alert systems for severe hyponatraemia, similar to electronic alerts for acute kidney injury already introduced in several NHS hospitals.25–27 By highlighting hyponatraemia and referring to intranet-based guidelines, electronic alerts could prompt optimal investigation and treatment in a timely manner. Another innovative model of care delivery with the potential to improve standard of care is the development of multidisciplinary hospital ‘hyponatraemia teams’ combining the expertise of endocrinologists, nephrologists, chemical pathologists and other physicians. In addition, UK guidelines on management of hyponatraemia are still needed despite the recent publication of clinical practice guidelines by an expert panel22 and by a joint venture of the European Society of Endocrinology with the European Renal Association.20 The reason is that clinical practice and experience in the UK differ from that in the USA22 and continental Europe20 with regard to the structure of the healthcare system and the availability of treatment options, such as urea and vaptans. Finally, we agree with the authors of both European and US guidelines on the urgent need for studies evaluating the effect of correction of hyponatraemia on patient-important outcomes such as symptoms, quality of life, mortality and length of hospital stay.20 22

Main messages.

  • Hyponatraemia is frequently underinvestigated and underdiagnosed in UK clinical practice.

  • Most patients are discharged with persistent hyponatraemia, while a substantial proportion of them have not received any treatment for hyponatraemia.

  • Fluid restriction is often ineffective in correcting hyponatraemia due to SIADH.

Current research questions.

  • Does correction of hyponatraemia improve patient outcomes such as length of hospital stay and mortality?

  • What would be the impact of measures such as introduction of electronic alert systems or widespread provision of expert input on management of inpatient hyponatraemia and patient outcomes?

  • What is the optimal treatment strategy for hyponatraemia due to SIADH with regard to sodium correction and patient outcomes?

Key references.

  • Tzoulis P, Bagkeris E, Bouloux PM. A case-control study of hyponatraemia as an independent risk factor for inpatient mortality. Clin Endocrinol (Oxf) 2014;81:401–7.

  • Huda MS, Boyd A, Skagen K, et al. Investigation and management of severe hyponatraemia in a hospital setting. Postgrad Med J 2006;82:216–19.

  • Clayton JA, Le Jeune IR, Hall IP. Severe hyponatraemia in medical in-patients: aetiology, assessment and outcome. QJM 2006;99:505–11.

  • Thompson C, Berl T, Tejedor A, et al. Differential diagnosis of hyponatraemia. Best Pract Res Clin Endocrinol Metab 2012;26(Suppl 1):S7–15.

  • Spasovski G, Vanholder R, Allolio B, et al. Clinical practice guideline on diagnosis and treatment of hyponatraemia. Eur J Endocrinol 2014;170:G1–47.

  • Verbalis JG, Goldsmith SR, Greenberg A, et al. Diagnosis, evaluation, and treatment of hyponatremia: expert panel recommendations. Am J Med 2013;126(10 Suppl 1):S1–42.

Footnotes

Contributors: PT conceived and designed the study, monitored data collection for the whole study, cleaned and analysed the data, and drafted and revised the paper. PMB conceived and designed the study, and drafted and revised the paper. RE and AF were involved in data collection and data analysis. MB, TT, BK, MP and DN were involved in study design and patient recruitment, and drafted and revised the paper. EW, RL, NM, RE and RS were involved in patient recruitment, and drafted and revised the paper. KG designed the data collection tools, was involved in data analysis, and drafted and revised the paper. All authors approved the final version of the manuscript.

Competing interests: None.

Ethics approval: It was reviewed and approved by the Clinical Governance & Clinical Audit Departments of all three institutions.

Provenance and peer review: Not commissioned; externally peer reviewed.

References

  • 1.Hawkins RC. Age and gender as risk factors for hyponatremia and hypernatremia. Clin Chim Acta 2003;337:169–72. [DOI] [PubMed] [Google Scholar]
  • 2.Hoorn EJ, Lindemans J, Zietse R. Development of severe hyponatraemia in hospitalized patients: treatment-related risk factors and inadequate management. Nephrol Dial Transplant 2006;21:70–6. [DOI] [PubMed] [Google Scholar]
  • 3.Tzoulis P, Bagkeris E, Bouloux PM. A case-control study of hyponatraemia as an independent risk factor for inpatient mortality. Clin Endocrinol (Oxf) 2014;81:401–7. [DOI] [PubMed] [Google Scholar]
  • 4.Corona G, Giuliani C, Parenti G, et al. Moderate hyponatremia is associated with increased risk of mortality: evidence from a meta-analysis. PLoS ONE 2013;8:e80451. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 5.Wald R, Jaber BL, Price LL, et al. Impact of hospital-associated hyponatremia on selected outcomes. Arch Intern Med 2010;170:294–302. [DOI] [PubMed] [Google Scholar]
  • 6.Zilberberg MD, Exuzides A, Spalding J, et al. Epidemiology, clinical and economic outcomes of admission hyponatremia among hospitalized patients. Curr Med Res Opin 2008;24:1601–8. [DOI] [PubMed] [Google Scholar]
  • 7.Huda MS, Boyd A, Skagen K, et al. Investigation and management of severe hyponatraemia in a hospital setting. Postgrad Med J 2006;82:216–19. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 8.Saeed BO, Beaumont D, Handley GH, et al. Severe hyponatraemia: investigation and management in a district general hospital. J Clin Pathol 2002;55:893–6. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 9.Siddique H, Kahal H, Tahrani AA, et al. The management of hyponatraemia at two district general hospitals in the UK. J Eval Clin Pract 2010;16:1353–6. [DOI] [PubMed] [Google Scholar]
  • 10.Soran H, Alio Z, Pattison T, et al. Management of hyponatraemia: are we doing enough? QJM 2005;98:620–1. [DOI] [PubMed] [Google Scholar]
  • 11.Clayton JA, Le Jeune IR, Hall IP. Severe hyponatraemia in medical in-patients: aetiology, assessment and outcome. QJM 2006;99:505–11. [DOI] [PubMed] [Google Scholar]
  • 12.Crook MA, Velauthar U, Moran L, et al. Review of investigation and management of severe hyponatraemia in a hospital population. Ann Clin Biochem 1999;36(Pt 2):158–62. [DOI] [PubMed] [Google Scholar]
  • 13.Whyte M, Down C, Miell J, et al. Lack of laboratory assessment of severe hyponatraemia is associated with detrimental clinical outcomes in hospitalised patients. Int J Clin Pract 2009;63:1451–5. [DOI] [PubMed] [Google Scholar]
  • 14.Hillier TA, Abbott RD, Barrett EJ. Hyponatremia: evaluating the correction factor for hyperglycemia. Am J Med 1999;106:399–403. [DOI] [PubMed] [Google Scholar]
  • 15.Sterns RH, Riggs JE, Schochet SS Jr. Osmotic demyelination syndrome following correction of hyponatremia. N Engl J Med 1986;314:1535–42. [DOI] [PubMed] [Google Scholar]
  • 16.Sterns RH, Cappuccio JD, Silver SM, et al. Neurologic sequelae after treatment of severe hyponatremia: a multicenter perspective. J Am Soc Nephrol 1994;4:1522–30. [DOI] [PubMed] [Google Scholar]
  • 17.Bartter FC, Schwartz WB. The syndrome of inappropriate secretion of antidiuretic hormone. Am J Med 1967;42:790–806. [DOI] [PubMed] [Google Scholar]
  • 18.Ellison DH, Berl T. Clinical practice. The syndrome of inappropriate antidiuresis. N Engl J Med 2007;356:2064–72. [DOI] [PubMed] [Google Scholar]
  • 19.Thompson C, Berl T, Tejedor A, et al. Differential diagnosis of hyponatraemia. Best Pract Res Clin Endocrinol Metab 2012;26(Suppl 1):S7–15. [DOI] [PubMed] [Google Scholar]
  • 20.Spasovski G, Vanholder R, Allolio B, et al. Clinical practice guideline on diagnosis and treatment of hyponatraemia. Eur J Endocrinol 2014;170: G1–47. [DOI] [PubMed] [Google Scholar]
  • 21.Khromova V, Gray TA. Learning needs in clinical biochemistry for doctors in foundation years. Ann Clin Biochem 2008;45(Pt 1):33–8. [DOI] [PubMed] [Google Scholar]
  • 22.Verbalis JG, Goldsmith SR, Greenberg A, et al. Diagnosis, evaluation, and treatment of hyponatremia: expert panel recommendations. Am J Med 2013;126(10 Suppl 1):S1–42. [DOI] [PubMed] [Google Scholar]
  • 23.Fenske W, Stork S, Blechschmidt A, et al. Copeptin in the differential diagnosis of hyponatremia. J Clin Endocrinol Metab 2009;94:123–9. [DOI] [PubMed] [Google Scholar]
  • 24.Hannon MJ, Thompson CJ. The syndrome of inappropriate antidiuretic hormone: prevalence, causes and consequences. Eur J Endocrinol 2010;162(Suppl 1):S5–12. [DOI] [PubMed] [Google Scholar]
  • 25.Wallace K, Mallard AS, Stratton JD, et al. Use of an electronic alert to identify patients with acute kidney injury. Clin Med 2014;14:22–6. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 26.Porter CJ, Juurlink I, Bisset LH, et al. A real-time electronic alert to improve detection of acute kidney injury in a large teaching hospital. Nephrol Dial Transplant 2014;29:1888–93. [DOI] [PubMed] [Google Scholar]
  • 27.Flynn N, Dawnay A. A simple electronic alert for acute kidney injury. Ann Clin Biochem. Published Online First: 24 Apr 2014. doi:10.1177/0004563214534832. [DOI] [PubMed] [Google Scholar]

Articles from Postgraduate Medical Journal are provided here courtesy of BMJ Publishing Group

RESOURCES