Determination of Effective Albumin in Patients With Decompensated Cirrhosis: Clinical and Prognostic Implications
Bibliographic info
- Authors: Maurizio Baldassarre*, Marina Naldi*, Giacomo Zaccherini, Michele Bartoletti, Agnese Antognoli, Maristella Laggetta, Martina Gagliardi, Manuel Tufoni, Marco Domenicali, Katja Waterstradt, Paola Paterini, Anna Baldan, Simona Leoni, Manuela Bartolini, Pierluigi Viale, Franco Trevisani, Mauro Bernardi**, Paolo Caraceni** (* equal contribution; ** equal contribution)
- Journal: Hepatology, 2021, vol. 74, no. 4, pp. 2058–2073; DOI available
- Institution: University of Bologna, S. Orsola-Malpighi University Hospital; IRCCS AOU Bologna, Italy
Key question
Can the effective albumin concentration (eAlb) — the fraction of circulating albumin with preserved structural and functional integrity — be reliably measured in patients with decompensated cirrhosis, and does it predict ACLF development and 90-day mortality better than total albumin concentration (tAlb)?
Methods
- Sample type: Plasma from hospitalized patients
- Cohort: 319 patients with cirrhosis hospitalized for acute decompensation (AD) with/without ACLF; 18 outpatients with compensated cirrhosis; healthy controls; enrolled Feb 2010 – March 2016, S. Orsola-Malpighi Hospital, Bologna
- Exclusion: albumin infusion in past 15 days; HCC outside Milan criteria; AAH; hematologic malignancies; NYHA>2 heart failure; COPD III-IV; organic kidney disease
- Techniques:
- LC-ESI-MS (top-down) for HSA isoform identification and relative quantification (MaxEnt1 deconvolution, mass range 61,500–71,500 Da)
- Bromocresol green (BCG) for total albumin concentration (tAlb, g/dL)
- EPR (electron paramagnetic resonance) spin-probe for albumin binding function (MedInnovation GmbH, Berlin)
- eAlb calculation: eAlb = tAlb × (native HSA % / 100)
- Inflammatory markers: IL-6 and TNF-α (multiplex immunoassay)
- Severity scores: MELD, MELD-Na, Child-Pugh, CLIF-C AD scores
Main findings
Isoform landscape (11 damaged isoforms detected — more than domenicali-2014)
- Cysteinylated isoforms (HSA+Cys; HSA+Cys+Glyc; HSA+Cys-DA) most abundant in hospitalized patients
- Cysteinylated + glycated (HSA+Cys+Glyc) and N-term truncated + cysteinylated (HSA+Cys-DA) further elevated in ACLF vs AD
- Glycated isoforms (HSA+Glyc; HSA+2Glyc) increased in parallel with cirrhosis severity
eAlb performance
| Comparison | Finding |
|---|---|
| eAlb vs tAlb in severity | eAlb declines more steeply across compensated→AD→ACLF than tAlb |
| eAlb vs clinical scores | eAlb correlates inversely with MELD, MELD-Na, Child-Pugh, CLIF-C AD |
| eAlb vs binding function (EPR) | eAlb better reflects binding capacity than tAlb; tAlb in ACLF patients with same tAlb but different eAlb have very different binding functions |
| eAlb predicts 30-day ACLF | eAlb at admission predicts 30-day occurrence of ACLF (AUROC superior to tAlb) |
| eAlb predicts 90-day mortality | eAlb at admission predicts 90-day mortality (AUROC superior to tAlb) |
Key clinical numbers
- tAlb: outpatients 4.2 g/dL; hospitalized 3.0 g/dL; no difference AD vs ACLF at admission (3.0 vs 2.9 g/dL)
- ⚠️ tAlb cannot distinguish AD from ACLF at admission — eAlb can
- eAlb formula: eAlb (g/L) = tAlb (g/L) × native HSA fraction (%)
Albumin binding function (EPR)
- PCA applied to 6 EPR parameters → binding function correlates better with eAlb than with tAlb
- Patients with equal tAlb but lower eAlb have worse binding function — functional implications
Clinical context
- Disease: Decompensated Liver fibrosis / cirrhosis; ACLF
- Key implication: tAlb measurement in clinical routine does not distinguish structurally intact from damaged albumin → eAlb introduces quality dimension; critical for guiding albumin infusion therapy
- Therapeutic implication: target eAlb rather than tAlb for albumin supplementation decisions
Limitations
- eAlb calculated indirectly (native HSA % × tAlb by BCG) — two-step measurement; BCG method has known limitations for accuracy in severe liver disease
- Single center; observational
- EPR binding function measured by specialized commercial kit — not yet routine
- eAlb cut-off values need external validation before clinical adoption
Connections
- HSA — isoform quantification; native fraction as structural purity index
- Liver fibrosis / ACLF — primary disease context
- domenicali-2014 — predecessor; establishes native HSA as survival predictor; this paper operationalizes it as eAlb
- bernardi-2023 — perspective article on the eAlb paradigm by the same senior author (Bernardi)
- oettl-2013 — parallel approach (HNA2 by IEC); complementary view; eAlb broader concept
- el-balkhi-2025 — ALBOM study uses same top-down MS approach; absolute quantification by lakis-2024; clinically extends eAlb concept to fibrosis staging
- spinella-2016-review — reviews functional albumin concept that this paper operationalizes
My take home notes
- This is the landmark paper defining effective albumin (eAlb). The formula (eAlb = tAlb × native%) is simple but powerful — it combines the quantity (tAlb) with the quality (native fraction by LC-MS) into a single clinically interpretable value.
- The 30-day ACLF prediction and 90-day mortality advantage of eAlb over tAlb is the key clinical result. ACLF patients with the same total albumin can have very different eAlb, predicting drastically different outcomes.
- The EPR binding function result validates that eAlb is not just a theoretical construct — it correlates with actual measured binding capacity, which is the functional foundation of albumin’s non-oncotic roles.
- Limitation to highlight for ALBOM: BCG method overestimates albumin in some scenarios (known colorimetric artifact) — this means eAlb derived from BCG × LC-MS% may have accuracy issues. lakis-2024 (absolute MS quantification) avoids this by directly measuring isoform concentrations in g/L.