1. Surgical Anatomy Thyroid and Parathyroid Glands
Bastaninejad Shahin
MD, ORL&HNS, TUMS, Amiralam Hospital

2. Presentation outlines
Thyroid Gland:
General measures
Vascular supply
Important proximities
Surgical approaches and important Landmarks
Parathyroid glands:
Surgical localization
Thyroid Function Tests

3. Thyroid Gland

4. General measures Two lateral lobes connected with isthmus
Total weight is about 15 to 25 g
Each lobe: 4 x 1.5 x 2cm (height/width/depth)
Extends from C5 to T1 vertebra
Isthmus is over 2nd & 3rd tracheal ring
Approximately 40% of patients have a pyramidal lobe that arises from either lobe or the midline isthmus

5. 40% present

6. General measures... Cervical Fascia: True Thyroid Capsule
Surgical Capsule
Berry’s Ligament (connecting the lobes of the thyroid to the cricoid cartilage and the first two tracheal rings)
Surgical Approaches regarding to the Fascia:
Intracapsular Thyroidectomy
Extracapsular Thyroidectomy
Combine!?

7. Berry’s Ligament

8. Vascular Supply Two pairs of arteries Three pairs of veins
Connecting vessels within the thyroid true capsule
In less than 10%, there is a midline arterial supply to the gland, named as Thyroid Ima artery

10. Important proximities

15.  About 12cm
 About 5-6cm

16. Non-recurrent LN, Less than 1%

17. Can be find in only 10-30% of the times
1 cm

18. Surgical approaches and Landmarks
The course of the inferior laryngeal nerve is highly variant
Incidence of nerve paralysis is three to four times greater in cases in which the recurrent nerve was not localized compared with cases in which it was
Try to seek, expose and identifying the nerve, instead of avoiding it!
Extracapsular approach with nerve identification is the method of choice

19. The most common course of the nerve is within TE Groove (48
The most common course of the nerve is within TE Groove (48.5% - not depicted here)
Incidence is more higher in Revision cases
42.2%
5.4%
3.9%

20. Extralaryngeal Branching (35.5% in some reports up to 80%!)

21. Surgical approaches and Landmarks
Lateral Approach
Inferior Thyroidal Artery
Tubercle of Zuckerkandl (ZT)
Inferior Approach
Lore’s triangle
Tracheoesophageal Groove
Superior Approach
Posterolateral aspect of the Cricoid
Berry’s ligament
Inferior border of the inferior Constrictor
Inferior horn of the thyroid cartilage

22. ...Lateral Approach Used most commonly
RLN is identified typically at the thyroid midpole level (less nerve dissection required)
This approach is less useful for Revision

24. ZT is Present in 63-80% of the patients

25. ...Inferior Approach
Used for Revision cases and Goiter surgery (not substernal)
Problem: Longer nerve dissection and probability of Parathyroid glands ischemia
Benefit: nerve will be find before any extralaryngeal branching

27. ...Superior Approach Used for large substernal Goiters
Nerve is at the lower edge of the lateral aspect of the cricoid cartilage
Nerve should be identified just caudal to the lowest fibers of the inferior constrictor

28. Parathyroid Glands

29. General measures Two pairs: Superior and Inferior
Weight is about 50 to 70 mg
Size 5 x 3 x 1 mm
Color of normal parathyroid glands ranges from yellowish brown to reddish brown
87% there are four glands (super numerary glands are usually in the mediastinum or thymus gland)
Their Arterial supply is usually from Inferior Thyroid artery (80%)

31. Surgical Localization
Superior Parathyroid Glands
80% they are at the cricothyroid junction approximately 1 cm cranial to the juxtaposition of the recurrent laryngeal nerve and the inferior thyroid artery.
Ectopic glands: it cloud be intrathyroid, paraesophageal, retroesophageal and mediastinal (posterior superior compartment)

32. ...Surgical Localization
Inferior Parathyroid Glands:
More variable location
More than 50% of the inferior parathyroid glands are situated near the lower pole of the thyroid gland
Ectopic glands: it could be situated in thyrothymic ligament (28%) or mediastinum (Anterior superior compartment)

34. Thyroid Laboratory Tests

35. Thyroid Function Tests
TSH
FT4, (T4)
FT3, (T3)
Thyroglobulin
Thyroid stimulating immunoglobulin (TSI)
Antithyroid peroxidase antibodies (Anti-TPO)
RAIU

36. Serum TSH Single best initial test of the thyroid function
Normal range 0.5 – 5.0 mU/L
If TSH alone is the first line test, what diagnoses will be missed?
Pituitary disease or tumors
Hypothyroidism develops within 12 months of treatment for thyrotoxicosis (the TSH value remains suppressed)
Thyroid hormone resistancy
Non-thyroidal illness (NTI)
Pregnancy
 In these cases testing of free thyroid hormones is recommended in addition to the TSH assay (FT4 + TSH)
Serum tsh is the single best or initial test of the thyroid function because it is the central to the negative feedback system. It has an inverse, log-linear relationship with thyroid hormone. So small changes in free thyroid hormone would result in large changes in the tsh levels. Most labs adopt a normal range of 0.5 to 5.0 mU/L. Now a day most advanced assays can detect both elevation and significant lowering of tsh levels less than (The third generation of TSH chemiluminometric assays has detection limits of about 0.01mU/L)

37. Screening Recommendations
Various societies and authors disagree about population-based screening
There are insufficient evidences to recommend for or against routine screening for thyroid disease in adults.
The AAFP recommends screening high-risk populations:
women with a family hx of thyroid disease
women >35 y.o.
pregnant women
abnormal physical exam
diabetic patients
Hx of autoimmune disorder
The American Thyroid Association (ATA) recommends screening start at age 35 (and q 5 years after that)

38. Serum T4
Serum total T4 assays measure both bound and unbound (“free”) T4
Levels are high in approximately 90% of hyperthyroid patients and low in approximately 85% of hypothyroid patients.
Serum total T4 is usually measured by radioimmunoassay, chemiluminometric assay, or similar immunometric techniques.
Virtually all 99.97% of serum T4 is bound to TBG (thyroxine binding globulin), transthyretin or TBPA (thyroxine-binding prealbumin), or albumin.
The serum t4 assays meseasure bothe bound and unbound (free) t4.
Levels are high in approximately 90% of hyperthyroid patients and low in approximately 85% of hypothyroid patients. However, many drugs and illnesses can alter concentrations of binding proteins or interaction of the binding protein with T4 or T3 and may cause changes in total hormone concentration but not FT4. For example, pregnancy and anabolic steroids increase total protein so the total serum T4 is high, whereas malnourishment condition lower total protein so the serum total t4 is low. Both of these conditions the free t 4 remain within normal level. Dopamine cause

39. Serum Free T4
FT4 is measured by equilibrium dialysis techniques or estimated indirectly by calculation of free-thyroxine index (FTI)
FT4 assay is preferred test with TSH or when TSH is high
FT4 is the prefered test to truly identify for hyper or hypothyroidism. It can be measured directly by equilibrium dialysis techniques or estimated indirectly by calculation of free thyroxine index (FTI).
FTI can be calculate multiplying total t4 to T3 resin uptake. That would give the t3ru percentage which reflect the free thyroxine. ( It also called by name such as T7 or thyroid hormone-binding ratio. These terminologies are rarely used anymore.)

40. T3, Free T3, and rT3 T3 FT3 Reverse T3 (rT3) binding protein dependent
Levels can be misleading in patients with acute illness, cirrhosis, uremia, or malnutrition
FT3
Useful to distinguish T3 toxicosis from subclinical thyrotoxicosis
When TSH is low, a free T3 assay should be obtained
Measurement of fT3 is not indicated in hypothyroidism
Reverse T3 (rT3)
- increased in NTI
- it is an inactive hormone
- helpful to exclude central hypothyroidism

42. Other Ancillary Tests Serum thyroglobulin
produced and released by thyroid gland
marker for recurrent thyroid cancer
differentiate Graves disease from factitious thyrotoxicosis
Serum thyroid-stimulating immunoglobulin (TSI)
Expensive test
Graves’ disease.
Antithyroid peroxidase antibodies (Anti TPO)
organ-specific and sensitive.
Hashimoto’s thyroiditis
predict overt hypothyroidism (use in subclinical hypothyroidism)
Occasionally, you may need additional tests to determine the underlying causes. Thyroglobulin is only produced and released by thyroid gland; thus, it is a good marker to look for recurrent thyroid cancer. It can also be used to differentiate Graves disease from factitious thyrotoxicosis.
Serum TSI or TSHR-Ab is an expensive test. It is specific to Graves’ disease.
Anti TPO is also organ specific and sensitive. It’s more commonly found in Hashimoto’s thyroiditis and less commonly in Graves’ disease. The presence of anti-TPO in patients with subclinical hypothyroidism would predict that patient likely to have 35-40% chance of becoming overt thyroidism in 2 years.

43. Other… Radioactive iodine uptake (RAIU)
A very high RAIU is seen in individuals whose thyroid gland is overactive (hyperthyroidism)
A low RAIU is seen when the thyroid gland is underactive (hypothyroidism)

44. Thank You!