Beta-HCG’s half life
| HOSP # | WARD | Labour Ward | |
| CONSULTANT | Dr. Jody Rusch | DOB/AGE | 23 y Female |
Abnormal Result
The beta-HCG measured 1.3 million IU/L initially, then decreased significantly after an induced abortion.
Presenting Complaint
A 23 year old lady, at 36 weeks gestation presented with signs and symptoms of Hyperthyroidism. She also had a “retained placenta with hydatid mole” quoted from the request form
History
The patient presented with a gradual onset of hyperthyroidism signs and symptoms during the pregnancy.
Examination
Retained products of conception. This was subsequently removed and sent for histology (see below).
Laboratory Investigations
| Episode | SA02847149 | SA02854036 | SA02854698 | SA02863861 |
| Date | 14/03/2019 | 17/03/2019 | 18/03/2019 | 20/03/2019 |
| Time | 13:03 | 00:47 | 01:12 | 15:37 |
| Beta-HCG | 1 319 797 | 203 195 | 81 165 | 21 567 |
Other Investigations
Histology
MACROSCOPY:
Specimen consists of a large amount of placental tissue fragments with grape-like structures noted, the largest measuring 14mm in diameter. The largest fragment of tissue measures 155 x 50 x 35mm. The entire specimen weighs 374g.
MICROSCOPY:
Sections of placental tissue demonstrate heterogeneity in villous size with large, hypertrophic villi and small fibrotic villi identified. The enlarged villi are irregularly shaped with scalloped borders, and cistern formation. Circumferential mild trophoblastic hyperplasia is noted in some of the villi. Foci of micro-infarction are noted. Overall features are consistent with a partial hydatidiform mole.
PATHOLOGICAL DIAGNOSIS:
Retained products of conception (placenta), biopsy:
Final Diagnosis
- Gestational trophoblastic disease, consistent with a partial hydatidiform mole
- Hyperthyroidism likely due to the similarity of the alpha subunit in HCG to the alpha-subunit of TSH, hence stimulating the TSH receptors.
Take Home Message
According to the only source I could find during a quick literature search, I came upon the phrase:
Plasma beta-HCG concentration falls according to a multi-exponential curve with a half-life of 0.63 days in the first 2 days following induced abortion, and of 3.85 days in the subsequent 14 days
van der lugt et al – Disappearance of HCG after induced abortion, 1985
Considering the above, I endeavoured on the task of calculating the half life of the HCG between the 4 time points using Prof Pillay’s method:
F=0.5^(t/T), where F=fraction left, t=time difference and T=half life (units to be kept constant for t and T).
An important log-transformation rule to remember in this case is the logarithm power rule:
| Logarithm power rule | logb(x y) = y ∙ logb(x) |
Thus to calculate the half life between two time points (after rearranging formula above):
T= (t * log(0.5)) / log(F)
Hence
Between days 0 and 2.5:
T = (2.5 * log(0.5))/ log(203 195/ 1 319 797)
- T (or half life) = 0.92 days
Similarly between days:
- 2.5 and 3.5: T= 0.76 days
- 3.5 and 6.15: T = 1.39 days
This corresponds fairly to the quoted 0.63 days which increases on subsequent days after abortion.
The discrepancy could likely be explained due to:
- some degree of high dose hook effect at the high HCG concentrations,
- high coefficient of variation at high immunoassay analyte concentrations with assays using a sigmoidal calibration curve,
- variation in the methods of abortion compared to or
- gestational age upon which abortion is done, to name a few.
Nonetheless the above equation from Prof Tahir Pillay is useful to calculate half life.
It is important to screen for hyperthyroidism in patients with hydatid moles and ensure that the TFT’s return to normal when the HCG returns to normal.