Keywords
parathyroidectomy - parathyroid hormone - parathyroid neoplasms
Introduction
Hyperparathyroidism is an endocrine disorder characterized by excessive parathyroid
hormone (PTH) and a common cause of hypercalcemia. The PTH is a major component of
calcium metabolism and it is produced by the parathyroid glands. Disorders of the
parathyroid glands generally involve excessive secretion of PTH leading to a variety
of systemic symptoms. In the cases of primary hyperparathyroidism, 87–91% are caused
by a single adenoma of the parathyroid gland.[1] Other causes, although less common, may include double adenomas, four-gland disease,
and parathyroid carcinoma.[1] It presents more commonly in women and those over the age of 50.[2] Classical symptoms of hyperparathyroidism include kidney stones, abdominal pain,
neurocognitive symptoms, bones pain, muscle weakness, and fatigue. Other symptoms
may exist and vary symptomatically between individual, and individuals may even be
asymptomatic.
Surgical intervention is the only definite treatment for the disorder. Although medical
management may be attempted for the treatment of hyperparathyroidism, greater treatment
and patient outcomes generally favor a surgical approach rather than medical management.[3] The main aim of the surgical treatment is to reduce the levels of PTH that lead
to hypercalcemia and establish a normocalcemic level in the individual. The previously
traditional approach consisted of a bilateral central compartment parathyroid gland
exploration and subsequent excision of the diseased glands. Minimally invasive parathyroidectomy
has now become the more common surgical technique due to advancements in imaging technology,
surgical instrumentation, technique, and the use of intraoperative parathyroid hormone
(ioPTH) monitoring to rapidly determine the adequacy of the surgical excision of the
glands.[4] When compared with the more invasive use of the bilateral neck exploration and surgical
resection, the minimally invasive techniques lead to lower rates of complications
(lower rates of postoperative hypocalcemia and recurrent laryngeal nerve injury),
shorter hospital stays, with an efficacy equal to that of the bilateral neck exploration
method.[5]
Due to the relatively short half-life of the PTH, PTH measurements serve as a useful
laboratory measurement for surgical adequacy. Preoperative PTH levels are routinely
measured to confirm disease state and severity, such as during a clinic visit. A drop
in the ioPTH level by more than 50% of the preoperative PTH level at the 10–15-minute
mark post-excision is considered a standard of care accepted measure of surgery adequacy,
and the vast majority of these patients are cured. However, even this test has false-positive
and false-negative results. At times, the reduction in PTH level hovers around 50%,
leading to further surgical exploration, which may or may not be necessary. There
have been case reports of delayed double adenoma recognition leading to second surgeries,
placing the patient at a high perioperative risk for complications. Therefore, there
is a monumental importance placed on the PTH value measured before the surgery, as
it is used for comparative analysis to the ioPTH post-excision.
At our institution, it is the senior surgeon's (T.H.) practice to obtain a pre-excisional
ioPTH regardless of a documented preoperative level in the records from regular clinic
visits. Surgical excision of the gland occurs after this blood measurement is taken
in the operative room. Discrepancies between the preoperative PTH and pre-excisional
ioPTH have been noted. Due to the potential impact of quantifying adequacy of surgery,
we sought to explore the differences in these levels.
The study aims to analyze the disparity between preoperative PTH and pre-excisional
ioPTH in patients who have undergone surgical correction of their hyperparathyroidism.
We hypothesize that if a consistent disparity is noted, then routine pre-excisional
ioPTH should be considered a standard practice when using PTH levels to assess surgical
adequacy, particularly in cases of non-localizing adenomas or possible double adenomas.
Methods
After receiving exemption by the Institutional Review Board at our institution, we
conducted a retrospective chart review and analysis of adult patients treated for
hyperparathyroidism at a tertiary academic care center from September 2009 to March
2016.
Each patient had a full medical workup for hyperparathyroidism to confirm the diagnosis.
Various variables including elevated preoperative PTH, symptomatic presentations,
medical therapy, bone scans, and progression of the disease were taken into account
before surgical consideration. The patients included in the study consisted of those
who had preoperative PTH levels determined at clinic visits and pre-excisional ioPTH
measured and who subsequently underwent parathyroid surgery for the correction of
their hyperparathyroidism. The patients not included in the study are those that did
not have available data regarding preoperative or pre-excisional laboratory values
or whose data from the blood draw could not be confirmed.
The patients in the study had hyperparathyroidism either from hyperplasia or adenomas.
The minimally invasive surgical approach was utilized for parathyroid resection. Each
patient had a known recorded preoperative PTH level taken during or prior to outpatient
clinical visits. In these clinic visits, blood samples were taken and stored in serum
separating tubes (SSTs). These tubes were then sent for PTH and calcium level analysis
with the use of the VITROS 5600 Integrated System (Ortho Clinical Diagnostics, Raritan,
NJ, USA).
The surgical team performed pre-excisional ioPTH levels following anesthesia induction.
The blood was drawn from the patient and stored in ethylenediaminetetraacetic acid
(EDTA) tubes and transferred for analysis. In addition, the post-excisional PTH levels
were measured in each patient to determine the drop in PTH level from previously measured
elevated PTH values before initiation of surgical resection.
The study evaluated the patients' demographics, etiology of hyperparathyroidism, date
and level of the preoperative PTH from clinic visits, and the date and level of the
pre-excisional ioPTH. The disparity between preoperative the PTH and pre-excisional
ioPTH values was calculated along with t-test comparisons and statistical significance (p < 0.05).
Results
Patient and Disease Characteristics
A total of 33 patients met the criteria for inclusion in the study. There was a female
predominance noted with 22 females and 11 males. The average age at the time of surgery
for the female patients was 59.1 and the average age for the male patients was 46.3.
The primary diagnosis found within the patient population is summarized in [Table 1]. The primary diagnosis was parathyroid adenoma (72.7%) followed by four-gland hyperplasia
(27.3%). Of the 24 patients with parathyroid adenoma, 21 had unilateral adenomas,
while 3 had double adenomas. In addition, the four-gland hyperplasia group consisted
of renal hyperplasia and primary hyperparathyroidism.
Table 1
Disease characteristic prevalence among the patient population
Disease Type
|
Total
|
Parathyroid adenoma
|
24
|
Four-gland hyperplasia (primary hyperparathyroidism or renal hyperplasia)
|
9
|
Primary hyperparathyroidism
|
3
|
Renal hyperplasia
|
6
|
Overall Total
|
33
|
Preoperative PTH and Pre-Excisional Intraoperative PTH Analysis
Each patient had a preoperative PTH, measured at the clinic, and a pre-excisional
ioPTH, measured before the surgical incision was initiated, and the difference between
these two values was calculated for each patient, with a total of 33 patients. [Table 2] summarizes the data pertaining to PTH difference measurements. Four patients, three
with renal parathyroid hyperplasia and one with a parathyroid adenoma, who were outliers
and had a difference of over 400 pg/mL between their preoperative PTH and ioPTH, were
excluded from several calculations as shown in the tables. Calculations that both
included and excluded these patients are in [Table 2]. The average PTH difference in all patients (147.00 pg/mL) and all the patients
excluding the outliers (35.09 pg/mL) was calculated. Statistically significant differences
were noted both when including all patients (p = 0.0347) and all the patients with exclusion of the outliers (p < 0.0001).
Table 2
Statistical data for PTH level difference among the patient population
Preoperative PTH and pre-excisional intraoperative PTH mean difference (pg/mL)
|
95% CI (pg/mL)
|
p-value
|
All patients
|
147.00
|
[11.43; 284.47]
|
0.0347
|
All patients, except those with PTH differences greater than 400 pg/mL
|
35.09
|
[20.27; 49.92]
|
< 0.0001
|
Abbreviations: CI, confidence interval; PTH, parathyroid hormone.
Parathyroid Adenoma PTH vs Four-gland Hyperplasia PTH
A total of 24 patients were diagnosed with parathyroid adenoma. Statistical analyses
regarding parathyroid adenoma are summarized in [Table 3]. One patient had a difference between their preoperative and pre-excisional intraoperative
PTH value of 864 pg/mL and was excluded due to have a difference greater than 400
pg/mL. After exclusion of this one patient, an average PTH difference of 21.98 pg/mL
was noted along with statistical significance (p = 0.0396).
Table 3
Stratification of statistical data for parathyroid hormone (PTH) levels based on pathology
Preoperative PTH and pre-excisional intraoperative PTH mean difference (pg/mL)
|
95% CI (pg/mL)
|
p-value
|
Parathyroid adenoma
|
57.05
|
[−12.21; 126.34]
|
0.1906
|
Parathyroid adenoma except those with PTH differences greater than 400 pg/mL
|
21.98
|
[12.38; 31.58]
|
0.0396
|
Four-gland hyperplasia
|
345.55
|
[−33.35; 724.45]
|
0.1116
|
Four-gland hyperplasia, except those with PTH differences greater than 400 pg/mL
|
74.66
|
[35.66; 113.66]
|
0.0121
|
Primary hyperparathyroidism
|
65.00
|
[52.00; 78.00]
|
0.1272
|
Renal hyperplasia
|
485.33
|
[−60.98; 1032.36]
|
0.1419
|
Renal hyperplasia, except those with PTH differences greater than 400 pg/mL
|
84.33
|
[25.93; 142.73]
|
0.1295
|
Abbreviation: CI, confidence interval.
A total of nine patients were diagnosed with four-gland hyperplasia in which six were
due to renal hyperplasia and three due to primary hyperparathyroidism. Three patients
with renal hyperplasia had a preoperative and intraoperative PTH difference of over
400 pg/mL. The statistical analysis of these pathologies was calculated, and both
included and excluded those with PTH differences greater than 400 pg/mL ([Table 3]). When excluding the three renal hyperplasia patients, an average PTH difference
of 74.66 pg/mL was calculated along with significance (p = 0.0121). No statistical significance was found when examining all patients with four-gland
hyperplasia or when stratifying the four-gland hyperplasia (renal hyperplasia and
primary hyperparathyroidism) group with or without the excluded patients.
Length of Time Intervals between PTH Measurements Analysis
The lengths of time between the dates of preoperative PTH and pre-excisional ioPTH
were calculated for each patient. The average length of time between these dates was
calculated to be 48 days ± 32 days. The linear regression analyzing the relationship
between length of time between PTH measurements and the PTH differences in the patients
revealed an extremely weak correlation of r2
= .15.
Preoperative PTH, Post-surgical PTH, and Consideration for Re-Exploration
The 50% reduction rule was assessed for the potential need for re-exploration. No
patients underwent re-exploration in the study however, we determined how the preoperative
PTH and pre-excisional intraoperative PTH may have influenced the need for re-exploration
([Table 4]). If using the preoperative PTH values alone, 6.1% met the criteria for re-exploration,
while 12.1% were borderline for re-exploration. None of the patients met the criteria
when using the pre-excisional intraoperative PTH values.
Table 4
Parathyroid hormone (PTH) values used to determine the necessity of re-exploration
PTH value used to determine need for re-exploration
|
Need for re-exploration
|
Borderline for re-exploration
|
Preoperative PTH
|
2/33 (6.1%)
|
4/33 (12.1%)
|
Intraoperative PTH
|
0/33 (0%)
|
0/33 (0%)
|
Patient Follow-up
All patients were closely followed postoperatively in regularly scheduled clinic visits
over time. PTH and calcium levels were measured in all the patients during each of
these scheduled visits. There was no evidence of hypercalcemia or recurrent hyperparathyroidism
in any patient to date.
Discussion
The advancements in laboratory monitoring of PTH levels have allowed surgeons to more
accurately assess the success of surgical resection of the parathyroid glands. This
innovation in surgery has become the standard of parathyroid surgery and has reduced
the need of other techniques, such as frozen section analysis and four-gland exploration.[6] Intraoperative PTH monitoring has shown to be both a superior approach to determine
the adequacy of gland section, be more cost effective, and reduce the need for more
invasive approaches to surgery.[6] Using these advantages, the use of minimally invasive techniques is becoming the
standard of care. A decline in the PTH to the normal range, and/or a greater than
50% delta drop in the level, is considered to be the standard for ensuring adequacy
of surgical resection. Therefore, the accuracy of the pre-excisional ioPTH value is
critical to the accuracy of the delta value used for determining completion of surgery.
Every test has a potential for false-positive and false-negative results. Intraoperative
parathyroid hormone monitoring is no different in this respect, particularly when
the decision of whether or not to perform further surgery rests on the percentage
decline of this level. The test results are highly dependent on the parameters used.
If the delta decline is not “sufficient,” the patient will likely undergo further
blood draw and exploration, which increases the operative risk, time, and cost. When
further disease is discovered, the increased interventions are justified, but in cases
in which further exploration is negative for the disease, the benefit to cost/risk
ratio is less favorable. Our study demonstrates a statistically significant difference
of at least 35 pg/mL between the preoperative and pre-excisional ioPTH values. Therefore,
pre-excisional ioPTH levels are critical to reduce the potential for false-positive
and false-negative delta PTH drops intraoperatively. Accuracy of the pre-excisional
levels is one way of minimizing false-positive and false-negative results.
It is unclear why this disparity between intraoperative and preoperative PTH values
exists. The specimen processing of routine outpatient laboratory draws and intraoperative
levels is different not only with respects to the speed of results, but also to the
technique. There currently is not a standard method of PTH processing and analysis
in the laboratory setting. Institutional variations exist which have hindered the
creation of specific guidelines. This is critical as laboratory measurements of PTH
are the mainstay of determining the adequacy of parathyroid surgery. Most centers
use second or third generation immunoassay methods for PTH analysis.[7] Both second and third generation immunoassay methods consist of using two monoclonal
antibodies directed against different regions of the N-terminal and C-terminal residue
to measure PTH levels.[7] Various intraoperative systems reportedly produce results at 5, 8 and 20 minutes,
for example.
One consideration is the storage of the sample; storage in whole blood or in serum
with ethylenediaminetetraacetic acid (EDTA) showed more stability than those without
anticoagulants.[7] Location of the blood draw for PTH also plays a role, and PTH values were higher
when blood was taken from the central venous system, such as the internal jugular
vein, as compared with peripheral sources of blood.[7] Regardless, while similar, the various assays do not process specimens identically,
and therefore the results are not directly comparable. Thus, there is likely an inherent
quantitative difference uniformly between the methods used. To obtain the most consistent
and reliable information, practitioners should plan to run preexcision and post-excision
PTH samples on the same assay, on blood drawn from the same site.
Minimally invasive parathyroidectomy has become the standard method of surgical resection
due to parathyroid pathology. It has shown to be cost effective and successful in
terms of curative rates. Removal of the parathyroid glands with autoimplantation of
one or few glands is one method commonly used to reduce the level of high PTH, but
also to avoid the possibility of hypoparathyroidism.[8] In other cases, complete removal of the parathyroid glands may be necessary. Failure
of achieving an appropriate drop in PTH would warrant a surgical gland exploration.
As mentioned, the value of PTH measured becomes critical when deciding whether a gland
exploration is necessary. Establishment of accurate PTH measurements would facilitate
in decision making of whether a gland exploration is necessary. Gland exploration
requires increased operating room time for the patient, along with higher costs. Due
to the invasive nature of a gland exploration, there is higher potential for surgical
complications, including recurrent and superior laryngeal nerve palsy, iatrogenic
thyroid injury, and unintentional hypoparathyroidism. In skilled hands, these complications
are rare.
However, a more serious issue is when the false-positive result (perceived PTH reduction > 50%
that is not accurate) convinces a practitioner to conclude surgery prematurely. In
one study that was a retrospective review of 723 patients, it was reported that 5
of 21 operative failures were secondary to false-positive ioPTH levels.[9] While uncommon, in these cases, patients are not recognized to have persistent hyperparathyroidism
until they undergo outpatient blood work. Given the statistically significant difference
between preoperative PTH and pre-excisional ioPTH levels we found in our small patient
population, it is reasonable to assume such variations may have been responsible for
the false-positive results in the above-mentioned study.
Furthermore, patients with persistent disease incur more cost and have greater surgical
risks. They typically undergo further diagnostic imaging and blood test, and then
ultimately revision exploration in a previously operated field, which may have varying
degrees of scar tissue and anatomic distortion from prior dissection, lengthening
surgical time and therefore further compounding the cost. In addition, there are the
psychosocial costs, including the additional time off work for the patients and their
transporters for further surgery, potential for hospital admission, the patient's
mental preparation to accept additional higher risk surgery, as well as trust issues
with the practitioner with respects to chances for surgical success.
With respects to patient morbidity, the risks for nerve injury, hemorrhage, and hypoparathyroidism
are significantly increased, as are the operative times and potential for hospital
admission with repeated surgery.[5] The surgical planes may be significantly distorted from prior surgery, complicating
nerve identification despite the use of intraoperative monitors. Dissections are typically
more laborious and lengthy and therefore require more anesthetic and potential need
for hospital stay for what is otherwise typically an outpatient surgery. Accurate
intraoperative testing at the first surgery may prevent this scenario.
The most common potential complication of surgery is recurrent laryngeal nerve injury.
Unilateral injury can result in hoarseness and difficulty swallowing. Bilateral nerve
is a feared, yet rare, complication that can result in airway obstruction leading
to an emergency need for airway management. Intraoperative nerve monitoring allows
continuous monitoring of the nerve, provided that the probe is placed appropriately,
and the machine is functioning. No consensus on its use has been established, and
debate still exists whether nerve monitoring reduces the occurrence of nerve injury
in patients undergoing revision surgery.[10]
[11] However, avoidance of revision surgery provides the best opportunity to reduce the
risk of recurrent laryngeal nerve injury.
Our study is limited by a small sample size. However, despite the small sample size,
the delta between preoperative and pre-excisional ioPTH was statistically significant
and independent of the length of time between blood draws. A larger patient series
could be conducted to further confirm the results and potentially evaluate the disparity
in PTH measurements between the various assays/systems available.
Conclusion
We have demonstrated statistically significant differences between the preoperative
PTH and pre-excisional ioPTH levels. The exact reasons behind the disparity are equivocal
and based on a variety of factors, such as type of immunoassay, machine type used,
storage of PTH, timing, blood source, and possible other reasons may also exist. Accuracy
of the PTH levels is essential to assess whether surgical resection was successful,
and if further surgical exploration is warranted. In a majority of cases, fortunately
this disparity did not impact on the patients' outcome. However, we did identify cases
in which the variance in the preoperative levels could have negatively impacted a
patient's outcome and surgical decisions. Due to the clinical significance of accurate
PTH, establishing a standard and accurate method of PTH measurements would facilitate
the efficacy of parathyroid surgery. We therefore recommend drawing a pre-excisional
ioPTH baseline level despite the documentation of preoperative PTH elevation in the
laboratory records. In addition, accuracy is further improved if the pre-excisional
and post-excisional levels are drawn from the same site.