Alzheimer’s disease (AD) is the most common cause of dementia. It is characterized by accumulation of β-amyloid (Aβ) peptides and tau proteins, loss of neurons and cognitive decline. It is difficult to diagnose AD in the early stages by clinical examination. Cerebrospinal fluid (CSF) biomarkers can be used to overcome this and could be useful in clinical practice, research and in trials of novel treatments.
 

by Philip Insel, Dr Rik Ossenkoppele and Dr Niklas Mattsson

Introduction
Alzheimer’s disease (AD) is a neurodegenerative disease that leads to cognitive impairment and ultimately dementia. The majority of the 45 million dementia patients world-wide have dementia due to AD [1]. In terms of brain pathology, AD is characterized by progressive accumulation of extracellular deposits of β-amyloid (Aβ) peptides in plaques and intracellular deposits of tau proteins in neurofibrillary tangles. The abnormal metabolism of Aβ and tau is believed to lead to impaired brain function, loss of synapses and neurons, and cognitive decline. The cognitive domain that is most severely impaired in most AD patients is episodic memory, but other domains such as language, visuo-spatial performance, behaviour and executive function may also become affected. In a subset of patients, deficits in non-memory domains are the dominating (early) features, as we will further discuss below.

Stages of Alzheimer’s disease
There is an increasing awareness among researchers and clinicians that AD starts many years before the onset of dementia. The first stage is thought to be asymptomatic, when pathologies accumulate silently in the brains of affected individuals for years or even decades before clinical symptoms emerge [2]. This is followed by an early clinical stage, which is characterized by objective cognitive impairment but still preserved function. This is often called mild cognitive impairment (MCI) due to AD, or prodromal AD [3]. The final stage is the classic stage, where AD has caused sufficient functional impairment for the patient to qualify for a dementia diagnosis.

Previously the procedure to diagnose AD was based solely on clinical examination and neuropsychological testing of the patient and interviews with proxies and caregivers. These methods are hampered by low sensitivity in the early stages of the disease and low specificity in the late stages of the disease. With the development of novel imaging and biochemistry technologies it is now possible to diagnose AD with the aid of direct evidence of relevant molecular pathologies in the brain. This is a conceptual leap that has revolutionized clinical AD research and is rapidly transforming clinical practice and clinical trial design. In this article we will discuss this development, with a focus on cerebrospinal fluid biomarkers for AD. Key points are summarized in Table 1.

The first steps
The amino acid sequences of Aβ and tau were identified in the mid-1980s [4, 5]. Early on it was suggested that a test for AD could be developed based on serum measurements of Aβ [4], but it was the discovery in the early 1990s that Aβ is secreted into the CSF that boosted the modern development of biochemical AD markers [6]. In the mid-1990s immunoassays (ELISAs) were developed for CSF Aβ1-42 (the prominent Aβ peptide isoform in Aβ plaques, typically reduced in AD patients compared to controls [7]), total-tau (T-tau, increased in AD patients compared to controls [8, 9]), and phosphorylated-tau (P-tau, increased in AD patients compared to other neurological diseases and controls [8]).

A window into the brain
Traditionally, AD could only be diagnosed at the dementia stage, and definite diagnosis was only possible through post-mortem analysis of brain tissue. The CSF biomarkers Aβ1-42, T-tau and P-tau (and imaging technologies not covered in this article) have made it possible to approach identification of AD brain pathology in living patients. Several studies have found that CSF Aβ1-42 is strongly related to the presence of brain Aβ pathology, quantified at autopsy [10] or in vivo using positron emission tomography imaging with tracers specific for fibrillar Aβ [11]. Likewise, although with less strong associations, CSF P-tau correlates with neocortical tangle pathology [12, 13], whereas CSF T-tau is more non-specifically increased in a number of neurological diseases, with the magnitude of the increase correlating with the size of the damaged tissue and the clinical outcome [14, 15]. CSF biomarkers enable detection of AD pathology in patients in early stages of the disease, when only mild symptoms or no clinical symptoms are present. As clinical diagnosis alone is inadequate in those early disease stages, biomarkers may be critical for an accurate diagnosis. CSF biomarkers may also increase the diagnostic accuracy of the diagnosis in advanced clinical stages, by providing biological evidence of AD related pathology. This helps in identifying the clinical syndrome and differentiating it from other neurological diseases.

Challenges
The field is rapidly advancing to overcome some hurdles that have prevented widespread implementation of CSF biomarkers. Problems with between-laboratory and between-assay variability in measurements have been noticed [16] and are being tackled by the development of certified reference procedures (based on selected reaction monitoring mass spectrometry [17]) and certified reference materials (created by the Institute of Reference Materials and Methods [18]). Development of fully automated assays will further bring down the variability and facilitate implementation of CSF biomarkers outside of expert centres (see www.neurochem.gu.se/TheAlzAssQCprogram for updated comparisons of different assay systems in a global quality control programme). In some countries a remaining obstacle is the unwillingness of medical practitioners to perform lumbar punctures, especially outside of highly specialized clinics. More training is needed to increase the familiarity of doctors with this procedure, and more education is needed to inform staff and patients that the procedure is safe. Headache is the only common complication (2–5 % incidence), but this is usually benign and treatable by common analgesics. Severe complications are extremely rare.

Alzheimer’s disease variants
CSF biomarkers of Aβ and tau may be particularly helpful to assist the diagnostic process in patients with a non-amnestic presentation of AD who may show substantial clinical overlap with patients experiencing non-AD types of dementia. Recently, there has been an increased awareness of these atypical presentations such as posterior cortical atrophy (PCA, ‘visual variant AD’ [19]), logopenic variant primary progressive aphasia (‘language variant AD’ [20]), and the behavioural/dysexecutive variant of AD [21]. As previous studies with small sample sizes have yielded conflicting results, we performed a study in 176 patients selected for abnormal CSF Aβ biomarkers to assess whether CSF T-tau and P-tau differ between atypical variants of AD [22]. Bootstrapping showed that the prevalence of abnormal T-tau and P-tau was ~80–90%, roughly equally distributed across AD phenotypes. This suggests that CSF T-tau and P-tau are equally useful in all clinical phenotypes of AD, which is compatible with current National Institute on Aging–Alzheimer’s Association (NIA-AA) and International Working Group for New Research Criteria for the Diagnosis of AD (IWG-2) diagnostic criteria.

Biomarkers in clinical trials
Biomarker measurement is a recent addition to AD clinical trials. The use of biomarkers is thought to improve trial design both in terms of subject selection and measurement of disease progression. It becomes particularly important in trials of disease-modifying treatments to recruit only those subjects with the target pathology of the therapy. Several recent failed trials may have been hindered by the inclusion of subjects without the underlying pathology [23]. Biomarkers are also less affected by measurement error compared with clinical outcomes and thus offer certain advantages in measuring progression over time, especially in early stages of disease [24]. In these early stages of the disease, before the onset of clinical symptoms, the ability of biomarkers to predict future pathology and cognitive decliners will aid in identifying those most in need of treatment. This will become especially important if intervention in the earliest stages of the disease, prior to substantial neurodegeneration, offers the best chance of a treatment to be effective.

Early treatment trials of anti-Aβ therapies employ thresholds to ensure recruitment of subjects with a minimal level of Aβ pathology. This threshold is frequently taken to be the level of amyloid pathology that most accurately distinguishes cases of AD from cognitively-normal controls [25]. However, if earlier treatment has a higher likelihood of success, identifying subjects with normal amyloid levels who are likely to have elevated levels in the future may be a further step toward early intervention. A recent study demonstrated that amyloid-negative subjects with low levels of CSF Aβ1-42 were much more likely to become amyloid-positive in the near term [26]. Individuals with CSF Aβ1-42 levels in the low normal range may be optimal candidates for early intervention trials aimed at halting further Aβ accumulation.

Conclusions
CSF biomarkers have helped to transform the diagnosis of AD from a clinical diagnosis to a biomarker-informed diagnosis based on molecular evidence of the underlying neuropathology. This has implications for research, where CSF biomarkers enable researchers to characterize subjects at all levels of cognitive function, in clinical practice, where CSF biomarkers aid doctors in diagnosis of AD versus other causes of cognitive impairment, and in the design of clinical trials, where CSF biomarkers may be used to enrich study populations and construct sensitive measures of outcomes to increase study power.

References
1. Alzheimer’s disease International: World Alzheimer Report 2015 (http://www.alz.co.uk/research/world-report-2015).
2. Jansen WJ, Ossenkoppele R, Knol DL, Tijms BM, et al. Prevalence of cerebral amyloid pathology in persons without dementia: a meta-analysis.
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3. Albert MS, DeKosky ST, Dickson D, Dubois B, et al. The diagnosis of mild cognitive impairment due to Alzheimer’s disease: recommendations from the National Institute on Aging-Alzheimer’s Association workgroups on diagnostic guidelines for Alzheimer’s disease. Alzheimers Dement. 2011; 7: 270–279.
4. Glenner GG, Wong CW. Alzheimer’s disease: initial report of the purification and characterization of a novel cerebrovascular amyloid protein. Biochem Biophys Res Commun. 1984; 120: 885–890.
5. Grundke-Iqbal I, Iqbal K, Quinlan M, Tung YC, et al. Microtubule-associated protein tau. A component of Alzheimer paired helical filaments. J Biol Chem. 1986; 261: 6084–6089.
6. Seubert P, Vigo-Pelfrey C, Esch F, Lee M, et al. Isolation and quantification of soluble Alzheimer’s beta-peptide from biological fluids. Nature 1992; 359: 325–327.
7. Motter R, Vigo-Pelfrey C, Kholodenko D, Barbour R, et al. Reduction of beta-amyloid peptide42 in the cerebrospinal fluid of patients with Alzheimer’s disease. Ann Neurol. 1995; 38: 643–648.
8. Blennow K, Wallin A, Agren H, Spenger C, et al. Tau protein in cerebrospinal fluid: a biochemical marker for axonal degeneration in Alzheimer disease? Mol Chem Neuropathol. 1995; 26: 231–245.
9. Vandermeeren M, Mercken M, Vanmechelen E, Six J, et al. Detection of tau proteins in normal and Alzheimer’s disease cerebrospinal fluid with a sensitive sandwich enzyme-linked immunosorbent assay. J Neurochem. 1993; 61: 1828–1834.
10. Strozyk D, Blennow K, White LR, Launer LJ. CSF Abeta 42 levels correlate with amyloid-neuropathology in a population-based autopsy study. Neurology. 2003; 60: 652–656.
11. Fagan AM, Mintun MA, Mach RH, Lee SY, et al. Inverse relation between in vivo amyloid imaging load and cerebrospinal fluid Abeta42 in humans. Ann Neurol. 2006; 59: 512–519.
12. Tapiola T, Alafuzoff I, Herukka SK, Parkkinen L, et al. Cerebrospinal fluid {beta}-amyloid 42 and tau proteins as biomarkers of Alzheimer-type pathologic changes in the brain. Arch Neurol. 2009; 66: 382–389.
13. Seppala TT, Nerg O, Koivisto AM, Rummukainen J, et al. CSF biomarkers for Alzheimer disease correlate with cortical brain biopsy findings. Neurology. 2012; 78: 1568–1575.
14. Hesse C, Rosengren L, Andreasen N, Davidsson P, et al. Transient increase in total tau but not phospho-tau in human cerebrospinal fluid after acute stroke. Neurosci Lett. 2001; 297: 187–190.
15. Otto M, Wiltfang J, Tumani H, Zerr I, et al. Elevated levels of tau-protein in cerebrospinal fluid of patients with Creutzfeldt-Jakob disease. Neurosci Lett. 1997; 225: 210–212.
16. Mattsson N, Andreasson U, Persson S, Carrillo MC, et al. CSF biomarker variability in the Alzheimer’s Association quality control program. Alzheimers Dement J Alzheimers Assoc. 2013; 9: 251–261.
17. Leinenbach A, Pannee J, Dülffer T, Huber A, et al. Mass Spectrometry-Based Candidate Reference Measurement Procedure for Quantification of Amyloid-β in Cerebrospinal Fluid. Clin Chem. 2014; 60: 987–994.
18. Mattsson N, Zetterberg H. What is a certified reference material? Biomark Med. 2012; 6: 369–370.
19. Crutch SJ, Lehmann M, Schott JM, Rabinovici GD, et al. Posterior cortical atrophy. Lancet Neurol. 2012; 11: 170–178.
20. Gorno-Tempini ML, Hillis AE, Weintraub S, Kertesz A, et al. Classification of primary progressive aphasia and its variants. Neurology 2011; 76: 1006–1014.
21. Ossenkoppele R, Pijnenburg YAL, Perry DC, Cohn-Sheehy BI, et al. The behavioural/dysexecutive variant of Alzheimer’s disease: clinical, neuroimaging and pathological features. Brain J Neurol. 2015; 138: 2732–2749.
22. Ossenkoppele R, Mattsson N, Teunissen CE, Barkhof F, et al. Cerebrospinal fluid biomarkers and cerebral atrophy in distinct clinical variants of probable Alzheimer’s disease. Neurobiol Aging 2015; 36: 2340–2347.
23. Karran E, Hardy J. Antiamyloid therapy for Alzheimer’s disease—are we on the right road? N Eng J Med. 2014; 370: 377–378.
24. Hendrix SB. Measuring clinical progression in MCI and pre-MCI populations: Enrichment and optimizing clinical outcomes over time. Alzheimer’s Res Ther. 2012; 4: 24.
25. Shaw LM, Vanderstichele H, Knapik‐Czajka M, Clark CM, et al. Cerebrospinal fluid biomarker signature in Alzheimer’s disease neuroimaging initiative subjects. Ann Neurol. 2009; 65: 403–413.
 26. Mattsson N, Insel PS, Donohue M, Jagust W, et al. Predicting reduction of cerebrospinal fluid β-amyloid 42 in cognitively healthy controls. JAMA Neurol. 2015; 72: 554–560.

The authors
Philip Insel^1,2,3 MSs; Rik Ossenkoppele^4,5 PhD; Niklas Mattsson*¹ MD, PhD
¹ Clinical Memory Research Unit, Faculty of Medicine, Lund University, Lund, Sweden
² Center for Imaging of Neurodegenerative Diseases, Department of Veterans Affairs Medical Center, San Francisco, CA, USA
³ Department of Radiology and Biomedical Imaging, University of California, San Francisco, CA, USA
⁴ Alzheimer Center and Department of Neurology, Neuroscience Campus Amsterdam, VU University Medical Center, Amsterdam, the Netherlands
⁵ Memory and Aging Center, University of California San Francisco, San Francisco, CA, USA

*Corresponding author
E-mail: Niklas.mattsson@med.lu.se

To reduce the window period for HIV-1 infection, a method for detecting trace amounts of HIV-1 p24 in blood is needed. We developed a simple de novo ultrasensitive colorimetric ELISA by adding a thio-NAD cycling solution to the standard ELISA. The limit of detection for p24 was 0.005 IU (i.e. attomoles) per assay by the ultrasensitive colorimetric ELISA.

by Dr A. Nakatsuma, M. Kaneda, H. Kodama, M. Morikawa, S. Watabe, et al.

Background
During the window period between infection with human immunodeficiency virus type 1 (HIV-1) and the appearance of detectable antibodies to HIV-1, the infection cannot be diagnosed. Attempts to shorten this period have been made using a fourth-generation immunoassay that detects both HIV-1/2 IgG/M and HIV-1 p24 antigens [1]. However, most of the commercially available detection systems for fourth-generation immunoassays use chemiluminescent measurement and thus require specialized, highly expensive automated measurement equipment. For this reason, fourth-generation immunoassays are performed only at diagnostics companies and hub hospitals. To overcome this limitation and to test many samples simultaneously, there is need of an immunoassay with increased sensitivity for the HIV-1 p24 antigen that nonetheless uses a common enzyme and does not require any specialized instruments.

In 2010, French health authorities mandated a limit of detection of at least 2 IU/mL of HIV-1 p24 antigen for a Conformité Européenne (CE)-marked HIV antigen/antibody assay [2]. According to this mandate, commercially available assay kits were manufactured to detect p24 antigen with limits of detection ranging from 0.505 to 1.901 IU/mL and from 11.9 to 33.5 pg/mL [2]. Units of pg/mL are used for the Société Française de Tranfusion Sanguine (SFTS) standard (i.e. recombinant proteins), versus IU/mL for the WHO (World Health Organization) standard. As 1 IU/mL is estimated to be equivalent to 10 pg/mL and MW = 24 000 for p24, the best sensitivity in these kits is 0.505 IU/mL, which is ~2 × 10⁻¹⁶ moles/mL.

To date, numerous methods have been proposed for the detection of p24 antigen. However, the limit of detection of p24 antigen is not expected to overcome the sensitivity of 10−17 to 10⁻¹⁸ moles/mL. In addition, we have to note that HIV testing of many samples requires not only ultrasensitive HIV-1 p24 detection but also rapidity, a reasonable cost, and a simple protocol without the requirement of special equipment. In the present review, we introduce a de novo ultrasensitive colorimetric enzyme-linked immunosorbent assay (ELISA) for HIV-1 p24 [3].

Mechanism of ultrasensitive colorimetric ELISA
Watabe and colleagues developed an ultrasensitive ELISA to measure trace amounts of proteins by combining a conventional ELISA with thionicotinamide-adenine dinucleotide (thio-NAD) cycling [4]. Their rationale was that although proteins cannot be amplified by polymerase chain reaction (PCR) in the manner of nucleic acids, a detectable signal for proteins can be amplified. Thus, their ultrasensitive ELISA (Fig. 1) employs a sandwich method using a primary and a secondary antibody for antigens. An androsterone derivative, 3α-hydroxysteroid, is produced by the hydrolysis of 3α-hydroxysteroid 3-phosphate with alkaline phosphatase linked to the secondary antibody. This 3α-hydroxysteroid is oxidized to a 3-ketosteroid by 3α-hydroxysteroid dehydrogenase (3αHSD) with a cofactor thio-NAD. By the opposite reaction, the 3-ketosteroid is reduced to a 3α-hydroxysteroid by 3α-HSD with a cofactor NADH. During this cycling reaction, thio-NADH accumulates in a quadratic function-like fashion. Accumulated thio-NADH can be measured directly at an absorbance of 400 nm without any interference from other cofactors.

This method enables the detection of a target protein with ultrasensitivity (10⁻¹⁹ moles/assay) by measuring the cumulative quantity of thio-NADH by a colorimetric method without the use of any special instruments for the measurements of fluorescence, luminescence or radio isotopes [4]. Further, we should note that this ultrasensitive method will allow a technician to detect trace amounts of proteins simply by applying thio-NAD cycling reagents to the conventional ELISA system. We therefore applied this ultrasensitive ELISA to the detection of HIV-1 p24 antigen in blood [3].

Sensitivity and stability of the ultrasensitive colorimetric ELISA for HIV-1 p24
A typical linear calibration curve for HIV-1 p24 antigen provided by the ultrasensitive ELISA coupled with thio-NAD cycling was y = 0.27x + 0.019, R² = 0.99 in the range of 0.1‒1.0 IU/mL. The limit of detection of p24 was 0.0055 IU/assay (i.e. ~2 × 10−18 moles/assay). These findings indicate that the ultrasensitive colorimetric ELISA succeeds in detecting p24 at the attomole level [3]. Because this measurement system employs a 50 µL solution for each assay, the detection limit corresponded to 0.1 IU/mL, or 10⁻¹⁷ moles/mL. Therefore, even in terms of the concentration per mL, our detection limit is less than one-tenth of that required by the French health authorities [2]. The coefficient of variation was 8% for 1 IU/mL.

Spike-and-recovery test using serum
We attempted to perform spike-and-recovery tests in which the HIV-1 p24 antigen was added to the control serum. Because our results demonstrated that the ratio was about 100% for 0.5 IU/mL of HIV-1 p24, which was less than the value (2 IU/mL) required for a CE-marked HIV antigen/antibody assay (see Background), the ultrasensitive method was judged to sufficiently detect IV-1 p24 antigen in human blood obtained from patients in the very early period after infection.

Detection of HIV-1 p24 in the early stages of infection
It is important to diagnose primary HIV-1 infection and begin antiretroviral treatment as early as possible. Most HIV-1/2 antibody diagnostic tests detect the antibodies for the antigens of HIV-1 gp41 and HIV-2 gp36, which are highly conservative transmembrane proteins. These tests are quick and easy, and thus have been widely used in many clinics and public health centres. However, when only the antibody diagnostic tests are used, there is a long delay (generally a 28-day window period) before diagnosis is possible [5]. Further, HIV-1/2 antibody tests in children younger than 18 months tend to be especially inaccurate as a result of the continued presence of maternal antibodies [6]. To shorten the delay and to validate HIV tests, the HIV-1 p24 antigen, the concentration of which is expected to increase before antibodies emerge, should be detectable in trace amounts. HIV-1 p24 in blood emerges transiently in the very early period after infection, and then its concentration quickly returns to the basal level [5]. An HIV-1 p24 test is, therefore, very useful as a screening test in the early stage of infection.

Closing the gap on PCR-based nucleic acid testing (NAT)
Generally, the gold standard for diagnosing HIV-1 is PCR-based nucleic acid testing (NAT) [7], but this method is expensive and has infrastructure requirements, a long measuring time, and high complexity, thereby limiting its usefulness for large numbers of samples. There is also the issue that much of the world lacks access to reliable NAT, and thus in many geographic regions the policy is to simply wait until symptoms develop. Use of ultrasensitive detection of HIV-1 p24 antigen for early diagnosis would be a simple and reasonable alternative to NAT, such as for monitoring HIV treatment and protecting the blood supply. Accordingly, it is time to reconsider whether NAT should be the gold standard for diagnosing HIV-1. Barletta et al. claimed that the target protein (i.e. HIV-1 p24 antigen) is present in the virion in much higher numbers than viral RNA copies (approximately 3000 HIV-1 p24 antigen molecules versus 2 RNA copies per virion) [8]. The 10⁻¹⁸ moles/assay value in our present results corresponds to 10⁶ protein molecules/assay, or ~10³ RNA copies/assay. Although under laboratory conditions a real-time PCR (i.e. NAT) can detect on the order of 10¹ RNA copies/assay, the limitation of detection is usually in the order of 10² RNA copies/assay [9]. Hence, the ultrasensitive ELISA coupled with thio-NAD cycling for HIV-1 p24 is closing in on the detection limit obtained by NAT, with a margin of difference of only one order of magnitude.

Conclusion
The ultrasensitive ELISA coupled with thio-NAD cycling is a very convenient method for the early testing of HIV-1 infection because it requires only the addition of a thio-NAD cycling solution to the usual ELISA without the use of any specialized measuring equipment. Consequently, the present method could be widely used as a powerful tool to test many samples simultaneously.

References
1. George CRR, Robertson PW, Lusk MJ, Whybin R, Rawlinson W. Prolonged second diagnostic window for human immunodeficiency virus type 1 in a fourth-generation immunoassay: Are alternative testing strategies required? J Clin Microbiol. 2014; 52: 4105–4108.
2. Ly TD, Plantier JC, Leballais L, Gonzalo S, Lemée V, Laperche S. The variable sensitivity of HIV Ag/Ab combination assays in the detection of p24Ag according to genotype could compromise the diagnosis of early HIV infection. J Clin Virol. 2012; 55: 121–127.
3. Nakatsuma A, Kaneda M, Kodama H, Morikawa M, Watabe S, Nakaishi K, Yamashita M, Yoshimura T, Miura T, Ninomiya M, Ito E. Detection of HIV-1 p24 at attomole level by ultrasensitive ELISA with thio-NAD cycling. PLoS One 2015; 10: e0131319.
4. Watabe S, Kodama H, Kaneda M, Morikawa M, Nakaishi K, Yoshimura T. Ultrasensitive enzyme-linked immunosorbent assay (ELISA) of proteins by combination with the thio-NAD cycling method. BIOPHYSICS. 2014; 10: 49–54.
5. World Health Organization (WHO). HIV/AIDS Fact sheet No 360. WHO 2015; http://www.who.int/mediacentre/factsheets/fs360/en/
6. Zijenah LS, Tobaiwa O, Rusakaniko S, Nathoo KJ, Nhembe M, Matibe P, Katzenstein DA. Signal-boosted qualitative ultrasensitive p24 antigen assay for diagnosis of subtype C HIV-1 infection in infants under the age of 2 years. J Acquir Immune Defic Syndr. 2005; 39: 391–394.
7. Patel P, Mackellar D, Simmons P, Uniyal A, Gallagher K, Bennett B, Sullivan TJ, Kowalski A, Parker MM, LaLota M, Kerndt P, Sullivan PS; Centers for Disease Control and Prevention Acute HIV Infection Study Group. Detecting acute human immunodeficiency virus infection using 3 different screening immunoassays and nucleic acid amplification testing for human immunodeficiency virus RNA, 2006-2008. Arch Intern Med. 2010; 170: 66–74.
8. Barletta JM, Edelman DC, Constantine NT. Lowering the detection limits of HIV-1 viral load using real-time immuno-PCR for HIV-1 p24 antigen. Am J Clin Pathol. 2004; 122: 20–27.
9. Wagatsuma A, Sadamoto H, Kitahashi T, Lukowiak K, Urano A, Ito E. Determination of the exact copy numbers of particular mRNAs in a single cell by quantitative real-time RT-PCR. J Exp Biol. 2005; 208: 2389–2398.

The authors
Akira Nakatsuma¹ PhD, PhC; Mugiho Kaneda¹ BAgr; Hiromi Kodama¹ MAgr; Mika Morikawa^1,2 BASc; Satoshi Watabe³ BPha; Kazunari Nakaishi²; Masakane Yamashita⁴ PhD; Teruki Yoshimura⁵ PhD, PhC; Toshiaki Miura⁶ PhD, PhC; Masaki Ninomiya¹ PhD, PhC; Etsuro Ito*¹ PhD

*Corresponding author
E-mail: eito@kph.bunri-u.ac.jp

Following the trend in the US, pressure is mounting on big European hospital labs to consolidate their operations and boost workflow performances while at the same time making better use of their staff. The Aptio Automation system from Siemens Healthcare Diagnostics goes a long way to fulfill these objectives. Here we take a look at three specific examples of hospitals that have integrated the system and how it has helped both their clinical and operational effectiveness

National Health Service (NHS) Tayside
NHS Tayside serves a population of 480,000 through a network of 22 hospitals/infirmaries and 69 general-practice sites that rely on two laboratories. The Blood Sciences Laboratory is located at the 900-bed Ninewells Hospital in Dundee, one of the UK’s major teaching hospitals. Here, Aptio Automation merges the three former individual labs onto a single track, providing a full complement of pre- and post-analytical sample-processing modules along with comprehensive analytics. The efficiencies gained have empowered the Ninewells Hospital laboratory to take on 73% of the testing that historically had been conducted at the 260-bed Perth Royal Infirmary (PRI), enabling the smaller PRI laboratory to focus exclusively on acute admissions and inpatient testing. Ninewells now handles 100% of the general practice testing in the entire region.
“Underpinning all of our actions is the commitment to reduce waste and variation—and most of all, to prevent harm to patients,” says Dr. Bill Bartlett, Tayside’s joint clinical director of diagnostics. “Aptio Automation is helping us enable our vision of cost-effective, patient-focused care.”
Using Aptio Automation, Tayside now processes 7,000 tubes per day—a 20% increase in the workload of its main laboratory with no additional staff. Decreased TAT across the board drove a 61% improvement in the TAT for add-on tests – all with the high-quality results derived from the consistency and standardization enabled by automation. Increased capacity has even enabled Tayside to introduce new testing protocols that improve the quality of care and can save the hospital money.
While Tayside staff had ideas about what they needed and wanted to do, Siemens gave them data-driven information to guide their decision making. “Siemens’ expertise and consultative approach was paramount to the success of this project, from beginning to end,” says Dr. Bartlett. “We relied on them to evaluate workloads from a variety of locations and to recommend the optimal mix of instruments to support peak loads. They devised the final track layout for the new space and helped optimize the use of automation to best manage the workflow.”

Carlos Haya Hospital Malaga
Rising along Spain’s Mediterranean coast, Malaga has a population of approximately 600,000 through tourism, construction, and technology services. The healthcare needs of locals and tourists are met by the 1,100-bed Universitario Carlos Haya Hospital. Part of the government-run Andalusian Public Health System, Carlos Haya is a regional institution with four hospitals: the General Hospital, Civil Hospital, CARE Joseph Estrada, and Hospital Materno Infantil. The latter, in addition to providing healthcare for mothers and infants, houses the core laboratory that serves as the reference lab for all four hospitals. The Carlos Haya General Hospital also operates a biochemistry lab and its own emergency lab.
Hospitals in Spain are classified into three tiers, depending on the complexity of the diseases they can treat. Materno Infantil holds the highest rating, Tier 3, which means it handles the most difficult cases. Its core lab provides testing across a wide spectrum of disease states, performing seven million tests a year for approximately 660,000 patients.
The great leap forward occurred in 2012, with the implementation of Siemens Aptio Automation integrated with the Siemens CentraLink Data Management System. The solution delivers extensive automation, customization, and traceability, while eliminating the need for third-party informatics software.
“Aptio Automation strengthened our preanalytical and analytical phases, giving us more capacity, more versatility, and overall, more possibility,” says Dr. Manuel Rodriguez, who is responsible for biochemistry and automation labs. “CentraLink, meanwhile, makes it much easier to manage quality. It facilitates sample follow-up and management of repetitions. With CentraLink control over instrument alarms, we gain comprehensive information on the situation of a particular sample. What’s more, the solution is simple, problem-free, and easy to use.”

Hospital Clinic de Barcelona (CDB)
In 2001, the Hospital Clinic de Barcelona in Spain was among the first healthcare providers in the world to create an automated core laboratory. Today the laboratory is gaining even greater efficiencies with Aptio Automation connecting analytical systems across all four core laboratory disciplines: clinical chemistry, immunoassay, hematology, and hemostasis.
Over the course of its 13-year journey with Siemens, the laboratory has been able to consolidate instruments, integrate and automate STAT testing, reallocate staff to higher-value responsibilities, and save upwards of €600,000 in tube costs – all while increasing clinicians’ trust in the laboratory to support excellence in patient care.
In 2000, Hospital Clinic de Barcelona established the Biomedical Diagnostic Centre (CDB) to provide high-quality, comprehensive service in all areas of laboratory medicine and to be a reference for excellence in the related specialties. The CDB uses a client-focused model to optimize the use of resources while ensuring advanced technological development in healthcare and research.
The CDB is divided into five specialty departments and an operative core laboratory where high-volume automated testing is performed. In total, the CDB is composed of 100 staff specialists from the various laboratory areas along with 300 professionals representing pathology, biochemistry, molecular genetics, hemotherapy and hemostasis, immunology, and microbiology specialties.
The CDB recently began a project to create a Molecular Biology Core Laboratory, which will integrate the most frequently tested molecular technologies.
“Economic pressure is an ongoing fact of life,” says Dr. Aurea Mira, director of the CDB. “Lab automation allows us to improve workflows, optimize human and technology resources, and save money. It also raises hospital awareness of the lab as a provider of fast, accurate testing that supports good clinical outcomes.”