Title: Thyroid Disease in Pregnancy Chantarojanasiri T. ,MD
1Thyroid Disease in Pregnancy
2OUTLINE
- Normal physiology changes during pregnancy
- Hyperthyroid
- Hypothyroid
- Postpartum thyroid disease
- Thyroid cancer
- Euthyroid with autoimmune thyroid disease
- Practice guidelines
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5Normal physiology
- The hypothalamic pituitary axis
- Thyrotropin-releasing hormone (TRH)
- Produced in a tonic fashion in the
paraventricular nucleus of the hypothalamus. - TSH has an a and ß subunitß subunit confers
specificity. - TSH secretion regulated by negative feedback from
circulating thyroid hormone, dopamine, and
somatostatin. - TSH then stimulates the thyroid gland to produce,
as well as secrete, thyroxine(T4) and
triiodothyronine (T3).
6- The rate-limiting step is iodide trapping
- mediated by TSH.
- nonpregnant state, 80 mg/d to 100 mg/d of iodine
taken up - 20 of the intake is cleared by the thyroid
gland remainder renally
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8Physiologic adaptation during pregnancy
- increase in thyroid-binding globulin
- secondary to an estrogenic stimulation of TBG
synthesis and reduced hepatic clearance of TBG
two to threefold - levels of bound proteins, total thyroxine, and
total triiodothyronine are increased and resin
triiodothyronine uptake (RT3U) is decreased - begins early in the first trimester, plateaus
during midgestation, and persists until shortly
after delivery - decrease in its hepatic clearance,estrogen-induced
sialylation - free T4 and T3 increase slightly during the first
trimester in response to elevated hCG. decline to
nadir in third trimester
9- human chorionic gonadotropin (hCG)
- intrinsic thyrotropic activity
- begins shortly after conception, peaks around
gestational week 10,declines to a nadir by about
week 20 - directly activate the TSH receptor
- partial inhibition of the pituitary gland (by
cross-reactivity of the a subunit) - transient decrease in TSH between Weeks 8 and 14
- mirrors the peak in hCG concentrations
- 20 of normal women, TSH levels decrease to less
than the lower limit of normal
10hCG
TSH
11- A decrease in basal TSH of 0.1 mU/L was observed
for every 10,000 IU/L increment in hCG - reduction in plasma iodide
- fetal monodeiodinase types II and III in the
placenta - increased maternal glomerular filtration rate--
increased renal clearance of iodide throughout
pregnancy - transplacental passage of T4 and iodide and
placental metabolism of iodothyronines - stimulate the maternal thyroid depleting the
maternal circulation of thyroid hormone and its
precursors
12- Hypothyroid25 to 47 average dosage increase
during pregnancy - increased serum thyroid stimulating hormone (TSH)
and thyroglobulin concentrations, relative
hypothyroxinemia, and occasional goiter formation - Esp. from area with borderline iodine sufficiency
- associated with increase in thyroid gland size in
15
13EFFECTS OF PREGNANCY ON THYROID PHYSIOLOGY
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15Hyperthyroidism and pregnancy
- 0.2 of pregnancies
- prevalence 0.1 to 0.4, with 85 Graves disease
- Single toxic adenoma, multinodular toxic goiter,
and subacute thyroiditis - gestational trophoblastic disease,viral
thyroiditis and tumors of the pituitary gland or
ovary (struma ovarii) - TSH is depressed and fT4 and fTI are increased.
- The RT3U that normally is decreased in pregnancy
is increased in hyperthyroidism.
16Hyperthyroidism and pregnancy
- serum TSH value lt0.01 mU/L and also a high serum
free T4 value - may be difficult to determine the cause
- thyroid radionuclide imaging is contraindicated
in pregnant women. - Measurement of thyrotropin receptor antibody
(thyroid stimulating immunoglobulins) ? Graves'
disease during pregnancy - transient hyperthyroidism in hyperemesis
gravidarum and gestational transient
thyrotoxicity (GET)
17Hyperthyroidism and pregnancy
- Severe maternal hyperthyroidism
- increased risk of stillbirth
- preterm delivery
- intrauterine growth restriction
- Preeclampsia
- heart failure
- spontaneous abortion
- Fetal thyroid hyperfunction or hypofunction
caused by TSHRAbs - Fetal goiter from excessive antithyroid drug
treatment - Neonatal thyrotoxicosis
- Increased perinatal and maternal mortality
- Decreased IQ of offspring because of excessive
use of antithyroid drugs
18Transient hyperthyroidism during pregnancy
gestational transient thyrotoxicity (GET)
- hyperemesis gravidarum
- severe nausea and vomiting leading to a 5 loss
of body weight, dehydration, and ketosis. - absence of goiter and ophthalmopathy, and absence
of the common symptoms and signs of
hyperthyroidism - higher serum hCG and estradiol concentrations
- 60 have a subnormal serum TSH level (lt 0.4
mU/L),50 have an elevated serum free T4
concentration - Severity positively correlated with maternal free
T4 levels but not to thyroid function. - 12 elevated free T3 index
- believed to be related to hCG stimulation of the
thyroid gland - Normalization of T4 levels by midgestation.
- Treatment is supportive care
19- GET
- first trimester
- related to hCG stimulation of the thyroid gland
- symptoms of hyperthyroidism and elevated free T4
levels. - The thyroid gland usually is not enlarged
- resolution of symptoms parallels the decline in
hCG levels - usually resolves spontaneously by 20 weeks
gestation - beyond 20 weeks,repeat evaluation for other causes
20Trophoblastic hyperthyroidism
- hydatidiform mole (molar pregnancy)
choriocarcinoma. - high serum hCG concentrations and abnormal hCG
isoforms - 55 to 60 percent had clinically evident
hyperthyroidism - normal thyroid gland and few symptoms of thyroid
hormone excess. - some findings of hyperthyroidism and a diffuse
goiter - ophthalmopathy is not present
- Nausea and vomiting may predominate
21subclinical hyperthyroidism
- associated with osteoporosis, cardiovascular
morbidity, and progression to overt
thyrotoxicosis and thyroid failure. - not associated with adverse pregnancy outcomes
- does not warrant treatment.
22Graves disease
- 95 of thyrotoxicosis during pregnancy.
- activity level fluctuate during gestation, with
- exacerbation during the first trimester
- gradual improvement during the latter half.
- exacerbation shortly after delivery
- clinical scenarios.
- stable Graves disease receiving thionamide
therapy with exacerbation during early pregnancy.
- in remission with a relapse of disease.
- without prior history diagnosed with Graves
disease de novo during pregnancy.
23Graves disease
- Diagnosis
- difficult hypermetabolic symptoms in normal
pregnancy - thyroid examination goiter (with or without
bruit) - suppressed serum TSH level and usually elevated
free and total T4 serum concentrations. - TSH receptor antibodies
- complications related to the duration and control
of maternal hyperthyroidism - autoantibodies mimic TSH can cross the placenta
and cause neonatal Graves disease
24Graves disease
- Pregnancy outcome
- preterm labor
- untreated (88)/partially treated(25)
/adequately treated (8) - preeclampsia
- untreated twice
- stillbirth
- untreated (50) /partially treated (16)
/adequately treated (0) - small for gestational age
- congenital malformations unrelated to thionamide
therapy - Mother may have thyroid-stimulating
hormone-binding inhibitory immunoglobulin (TBII),
- cause transient neonatal hypothyroidism
- fetal bradycardia, goiter,and growth restriction
25Graves disease
- Neonatal thyrotoxicosis
- 1 of infants
- occur in euthyroid mother or has had surgical or
radioactive 131I treatments before pregnancy - fetal ultrasound to exclude evidence of fetal
thyrotoxicosis (eg, an anterior fetal neck mass)
or fetal tachycardia. - fetal goiter, advanced bone age, poor growth, and
craniosynostosis, Cardiac failure and hydrops - Fetal blood sampling Fetal blood for thyroid
function tests by percutaneous umbilical vein
sampling after 20 weeks of gestation - High maternal TSH receptor-stimulating antibody
levels Fetal signs suggestive of thyroid disease
History of a prior baby with hyperthyroidism
26Thyroid storm
- obstetric emergency
- extreme metabolic state
- 10 of pregnant women with hyperthyroidism
- high risk of maternal cardiac failure.
- fever, change in mental status, seizures, nausea,
diarrhea, and cardiac arrhythmias. - inciting event (eg, infection, surgery,
labor/delivery) and a source of infection - treatment immediately, even if serum free T4,
free T3, and TSH levels are not known. - untreated thyroid storm can be shock, stupor, and
coma.
27Guidelines for clinical management of
maternalhyperthyroidism during pregnancy
- 1. Use the lowest dosage of thionamide
(preferably PTU) to maintain maternal total T4
concentrations in the upper one third of normal
to slightly elevated range for pregnancy. - Normal range of total T4 during pregnancy is
estimated to be 1.5 times the nonpregnant state - 2. Monitor maternal total T4 serum concentration
every 24 weeks, and titrate thionamide as
necessary. - Monitoring serum TSH may become useful later.
Shane O. LeBeau, Endocrinol Metab Clin N Am 35
(2006) 117136
28Guidelines for clinical management of
maternalhyperthyroidism during pregnancy
- 3. Measure TSH receptor antibodies
(thyroid-stimulating immunoglobulins or TSH
receptor binding inhibitory immunoglobulins) at
2628 weeks to assess risk of fetal/neonatal
hyperthyroidism. - TSH receptor antibody measurement is crucial in
hypothyroid levothyroxine-treated women with a
prior history of Graves disease, who do not
appear thyrotoxic. - 4. Perform fetal ultrasound at weeks 2628 to
assess potential fetal response to thionamide
treatment and effect of TSH receptor antibodies
on fetal thyroid function
29Guidelines for clinical management of
maternalhyperthyroidism during pregnancy
- 5. Consider thyroidectomy if persistently high
doses of thionamide (PTU gt 600 mg/d or MMI gt 40
mg/d) are required,or if the patient cannot
tolerate thionamide therapy. - 6. ß-Adrenergic blocking agents and low doses of
iodine may be used perioperatively to control
hyperthyroid state. - 7. Check fetal cord blood at delivery for TSH and
T4.
30Treatment
- Thionamides
- propylthiouracil (PTU) and methimazole(MMI)
- Both cross the placenta with equal transfer
kinetics. - Both can cause fetal goiter and hypothyroidism,
usually mild and transient dose-dependent - median time to normalization of maternal thyroid
function - 7 weeks with PTU and 8 weeks with MMI
- PTU more highly bound to albumin
- theorize that MMI crosses the placenta in higher
concentrations
31Treatment
- Thionamides
- maternal rash
- rare birth defects in MMI aplasia cutis, choanal
atresia,esophageal atresia, and minor dysmorphic
features - Low thyroid function at birth ½ neonates whose
mothers received PTU or MMI and had serum T4
concentrations within the normal (non-pregnant)
range - normal IQ scores
- Graves disease may ameliorate
- thionamide discontinued in 30 during the final
weeks - fall in serum TSH receptor-stimulating antibody
concentrations and a rise in TSH
receptor-blocking antibodies. - Graves' hyperthyroidism can worsen postpartum
- do not recommend the use of T4 with thionamide
therapy during pregnancy.
32Treatment
- ß-Adrenergic blockers
- weaned as soon as the hyperthyroidism is
controlled - occasional cases of neonatal growth restriction,
hypoglycemia, respiratory depression, and
bradycardia - increased frequency of first-trimester
miscarriages - avoiding in the first trimester
- Iodides
- past reports of neonatal hypothyroidism after
exposure to iodine - low-dose potassium iodide may be considered
- Preparation for thyroidectomy
- thionamide-intolerant patients refusing surgery.
33Treatment
- Surgery
- Subtotal thyroidectomy
- persistently high dosages of thionamides (PTU gt
600 mg/d, MMI gt 40 mg/d) are required to control
maternal disease - allergic or intolerant of both thionamides
- noncompliant with medical therapy
- compressive symptoms
- second trimester, before gestational week 24
- prepared with a ß-adrenergic blocking agent and a
10- to 14-day course of potassium iodide
34Treatment
- Radioactive iodine therapy
- contraindicated
- fetal thyroid gland begins to concentrate iodine
after gestational week 10, Fetal thyroid tissue
is present by 10 to 12 weeks - predisposing to congenital hypothyroidism
- Nursing
- Breast feeding in mothers taking PTU or MMI is
safe - Thyroid function in newborn infants is unaffected
- PTU is preferred because it is less concentrated
in breast milk
35Hypothyroidism in pregnancy
- elevated serum TSH concentration2.5 of
pregnancies - In iodine-sufficient environment
- Hashimotos thyroiditis
- prior radioactive iodine treatment
- surgical ablation of Graves disease
- less common causes overtreatment of
hyperthyroidism with thionamides, transient
hypothyroidism owing to postpartum thyroiditis,
medications that alter the absorption or
metabolism of levothyroxine, and
pituitary/hypothalamic disease)
36Hypothyroidism in pregnancy
- diagnosis
- Symptoms masked by the hypermetabolic state of
pregnancy. - 20 to 30 overt hypothyroidism develop symptoms
- weight gain, lethargy, decrease in exercise
capacity, and intolerance to cold,constipation,
hoarseness, hair loss, brittle nails, dry skin,
goiter, or delay in the relaxation phase of the
deep tendon reflexes - Elevated serum TSH concentration
- Central hypothyroidism do not manifest an
elevated serum TSH level
37Hypothyroidism in pregnancy
- Pregnancy outcome
- depends on the severity of disease and adequacy
of treatment - Gestational hypertension in overtly hypothyroid
women (36) vs subclinical disease (25) or the
general population (8) - Overt hypothyroid vs subclinical disease,
- increased use of cesarean section because of
fetal distress - placental abruption, anemia, andpostpartum
hemorrhage increased rates of miscarriage,
preeclampsia,placental abruption, growth
restriction, prematurity and stillbirths - fetuses are at risk for impaired neurologic
development low-birth-weight neonates
38Hypothyroidism in pregnancy
- TSH can be elevated with or without suppressed
levels of free T4. - antithyroid autoantibodies (eg,
antithyroglobulin, antithyroid - peroxidase) are present
- elevated creatine phosphokinase, cholesterol, and
liver function tests - 5 to 8 prevalence of hypothyroidism in type I
diabetes - mellitus and women who have type I diabetes have
a 25 risk of developing postpartum thyroid
dysfunction
39Causes of hypothyroidism
- Worldwide, the most common is iodine deficiency.
- impaired neurologic development severe mental
retardation, deafness, - muteness, and pyramidal or extrapyramidal
syndromes - Hashimotos thyroiditis
- Idiopathic hypothyroidism atrophic thyroid gland
- and absent antithyroid antibodies.
- 131I treatment for Graves disease and
thyroidectomy - Drugs interfere with the metabolism of thyroid
hormones
40Subclinical hypothyroidism
- normal free T4 level
- elevated TSH above the upper limit of reference
range (4.510.0mIU/L) - thresholds based on gestational age.
- TSH in the first half of pregnancy is 3.0 mIU/L
- prevalence of subclinical hypothyroidism 25
- increased risk of placental abruption and preterm
birth - important to monitor TSH and free T4 levels.
- 25 progress to overt hypothyroidism each year
41Isolated maternal hypothyroxinemia
- normal TSH
- free T4 below 0.86 ng/dl.
- In the first half of pregnancy,
- prevalence 1.3.
- not associated with adverse perinatal outcome
42Guidelines for clinical management of
maternalhypothyroidism during pregnancy
- 1. Check serum TSH level as soon as pregnancy is
confirmed. - 2. For newly diagnosed hypothyroid women, initial
levothyroxine dosage is based on severity of
hypothyroidism. For overt hypothyroidism,
administer 2 mcg/kg/d. If TSH is lt 10 mU/L,
initial dose of 0.1 mg/d may be sufficient. - 3. For previously diagnosed hypothyroid women,
monitor serum TSH every 34 weeks during first
half of pregnancy and every 6 weeks thereafter. - 4. Adjust levothyroxine dosage to maintain serum
TSH 2.5 mU/L. - 5. Monitor serum TSH and total T4 levels 34
weeks after every dosage adjustment. When
levothyroxine dosage achieves equilibrium, resume
monitoring TSH alone
Shane O. LeBeau, Endocrinol Metab Clin N Am 35
(2006) 117136
43Treatment
- 6. Levothyroxine ingestion should be separated
from prenatal vitamins containing iron, iron and
calcium supplements,and soy products by at least
4 hours to ensure adequate absorption. - 7. After delivery, reduce levothyroxine to
prepregnancy dosage, and check serum TSH in 6
weeks - adjusting levothyroxine
- 1. TSH lt 10 mU/L, increase 0.05 mg/d.
- 2. TSH 1020 mU/L, increase 0.075 mg/d.
- 3. TSH gt 20 mU/L, increase 0.1 mg/d.
- normal range for total T4 concentrations during
pregnancy is 1.5 times the nonpregnant - iodine prenatal vitamin 220 mg/day
44Postpartum thyroid disease
- Postpartum thyroiditis
- Dx documenting abnormal TSH (elevated or
suppressed) levels during the first year
postpartum in the absence of positive TSI or a
toxic nodule - hypo- or hyperthyroidism
- classic presentation
- transient hyperthyroid phase that occurs 6 weeks
to 6 months postpartum - followed by a hypothyroid phase that lasts for up
to 1 year postpartum
45Postpartum thyroiditis
- autoimmune disorder with a self-limited
hyperthyroid phase - within one year after parturition.
- Presentations
- Transient hyperthyroidism alone
- Transient hypothyroidism alone
- Transient hyperthyroidism followed by
hypothyroidism and then recovery. - can also occur after spontaneous or induced
abortion - 3 to 16 percent
- higher, up to 25 percent, in women with type 1
diabetes mellitus ,and in women with positive
antithyroid antibodies (normal thyroid function)
46Postpartum thyroiditis
- like painless thyroiditis
- variant form of chronic autoimmune thyroiditis
(Hashimoto's thyroiditis). - high serum concentrations of anti-peroxidase
antibodies - many eventually become hypothyroid or have a
goiter - high serum antithyroid antibody concentrations
early in pregnancy - decline later (as immunologic tolerance increases
during pregnancy) - rise again after delivery
- subclinical thyroid autoimmune disease early in
pregnancy and soon after - Progression to permanent hypothyroidism
- related to higher TSH concentrations and the
antiperoxidase antibody titer - maternal age and female sex of the infant
- Postpartum thyroiditis is likely to recur after
subsequent pregnancies
47- distinguished from Graves' hyperthyroidism,
- hyperthyroidism in postpartum thyroiditis is
usually mild (both clinically and biochemically),
- thyroid enlargement is minimal
- Graves' ophthalmopathy is absent.
- by reevaluation in three to four weeks
postpartum thyroiditis improved - lymphocytic hypophysitis,
- TSH normal or low, low free T4
- postpartum thyroiditis, TSH elevated with
decreased FT4.
48Postpartum thyroiditis
- antithyroids no role.
- Hypothyroid may require treatment and some
- significant rate of residual hypothyroidism
- Recommendmaintain thyroxine until childbearing
is complete, with an attempt to wean off
medication 1 year after the last delivery - Postpartum--signs/symptoms of thyroid dysfunction
- symptoms mimic normal postpartum changes
- TSH, free T4, and antithyroid antibodies levels
- postpartum depression and postpartum thyroiditis
49Postpartum Graves disease
- 60 Graves disease in the reproductive years
postpartum onset - euthyroid patients with Graves disease with TSI
- increased risk of developing recurrent Graves
disease if antithyroid medication was withheld - TSIs differentiate postpartum Graves disease
from postpartum thyroiditis with a hyperthyroid
component.
50Thyroid cancer
- Thyroid tumors most common endocrine neoplasms.
- thyroid cancer accounts for 1 of all cancers. ¾
women 1/2 reproductive years. - biopsy ,Serum TSH and free T4 levels,ultrasonograp
hy Fine needle aspiration - Radionucleotide scanning is contraindicated
during pregnancy - malignant or suspicious for papillary cancer,
surgery at the earliest safe period - no evidence that pregnancy causes a reactivation
of thyroid cancer or that exposure to radioactive
iodine poses a risk to future pregnancies - maintained on thyroid replacement therapy with
monitoring of TSH and free T4 levels every 8
weeks.
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52Euthyroidism with autoimmune thyroid disease
- increased risk for spontaneous miscarriage,
subclinical hypothyroidism, and postpartum
thyroiditis - Increase in serum TSH levels
- most normal
- presence of antithyroid antibodies
- lack of thyroidal reserve in response to the
stimulatory effects of pregnancy.
53Euthyroidism with autoimmune thyroid disease
- recommend initiating levothyroxine therapy in
women with antithyroid antibodies - before pregnancy
- TSH level greater than 2.5 mU/L.
- Serum TSH should be monitored throughout
pregnancy in all antithyroid antibodypositive
women - maintain the TSH concentration at 2.5 mU/L or
less.
54CLINICAL PRACTICE GUIDELINEManagement of Thyroid
Dysfunction during Pregnancyand Postpartum An
Endocrine Society ClinicalPractice Guideline
- 1. HYPOTHYROIDISM AND PREGNANCY MATERNAL
- AND FETAL ASPECTS
- 1.1.1. maternal hypothyroidism should be
avoided.Targeted case finding is recommended at
the first prenatalvisit or at diagnosis of
pregnancy - 1.1.2. If hypothyroidism diagnosed before
pregnancy, adjust preconception T4 dose to reach
a TSH 2.5 U/ml before pregnancy. - 1.1.3. T4 dose incremented by 46 wk gestation
and 3050 increase in dosage. - 1.1.4. If overt hypothyroidism is diagnosed
during pregnancy, thyroid function tests should
be normalized as rapidly as possible. - The T4 dosage should be titrated to rapidly
,maintain serum TSH 2.5 U/ml in the first
trimester (or 3 U/ml in the second and third
trimesters) or to trimester-specific normal TSH
ranges. - Thyroid function tests remeasured within 3040 d.
Abalovich et al. Guideline Thyroid Dysfunction
during and after Pregnancy J Clin Endocrinol
Metab, August 2007, 92(8) (Supplement)S1S47
55- 1.1.5. Women with thyroid autoimmunity who are
euthyroid in the early stages of pregnancy are at
risk of developing hypothyroidism and should be
monitored for elevation of TSH above the normal
range - 1.1.6. Subclinical hypothyroidism associated
with an - adverse outcome for both the mother and
offspring. - T4 treatment - improve obstetrical outcome but
has not been proved to modify long-term
neurological development in the offspring. - Recommends T4 replacement in women with
subclinical hypothyroidism. - 1.1.7. After delivery, most hypothyroid women
need a - decrease in the T4 dosage they received during
pregnancy
56- 2. MANAGEMENT OF MATERNAL HYPERTHYROIDISM
MATERNAL (A) AND FETAL (B) ASPECTS - 2.1.a.1. subnormal serum TSH
- hyperthyroidism must be distinguished from both
normal physiology during pregnancy and
hyperemesis gravidarum - Differentiation of Graves disease from
gestational thyrotoxicosis by evidence of
autoimmunity, a goiter, and presence of TRAb. - 2.1.a.2. For overt hyperthyroidism due to Graves
disease or hyperfunctioning thyroid nodules, - ATD therapy should be either initiated (for
those with new diagnoses) or adjusted (for those
with a prior history) - maintain the maternal thyroid hormone levels for
free T4 in the upper nonpregnant reference range.
- 2.1.a.3. methimazole may be associated with
congenital anomalies, propylthiouracil should be
used as a first-line drug, - especially during first-trimester organogenesis.
- Methimazole may be prescribed if propylthiouracil
is not available or if a patient cannot tolerate
or has an adverse response to propylthiouracil
57- 2.1.a.4. Subtotal thyroidectomy for maternal
Graves disease if - 1) a patient has a severe adverse reaction to ATD
therapy, - 2)persistently high doses of ATD are required
- 3) a patient is not adherent to ATD therapy and
has uncontrolled hyperthyroidism. - optimal timing of surgery is in the second
trimester. - 2.1.a.5. no evidence that treatment of
subclinical hyperthyroidism improves pregnancy
outcome - 2.1.b.1 TRAb (either TSH receptor-stimulating or
binding antibodies) freely cross the placenta
and can stimulate the fetal thyroid. - These antibodies should be measured before
pregnancy or by the end of the second trimester
in mothers with current Graves disease, with a
history of Graves disease and treatment with
131I or thyroidectomy, or with a previous neonate
with Graves disease. - Women who have a negative TRAb and do not require
ATD have a very low risk of fetal or neonatal
thyroid dysfunction.
58- 2.1.b.2. 131I should not be given to a woman who
is or may be pregnant. - radiation danger to the fetus, including thyroid
destruction if treated after the 12th week of
gestation. - There are no data for or against recommending
termination of pregnancy after 131I exposure - 2.1.b.3. In women with elevated TRAb or in women
treated with ATD, fetal ultrasound should be
performed to look for evidence of fetal thyroid
dysfunction - growth restriction, hydrops, presence of goiter,
or cardiac failure. - 2.1.b.4. Umbilical blood sampling should be
considered only if the diagnosis of fetal thyroid
disease is not reasonably certain from the
clinical data and if the information gained would
change the treatment. - 2.1.b.5. All newborns of mothers with Graves
disease should be evaluated for thyroid
dysfunction and treated if necessary
59- 3. GESTATIONAL HYPEREMESIS AND HYPERTHYROIDISM
- 3.1. Thyroid function tests should be measured in
all patients with hyperemesis gravidarum (5
weight loss, dehydration, and ketonuria) - 3.2. Few women with hyperemesis gravidarum will
require ATD treatment. - Overt hyperthyroidism believed due to coincident
Graves disease should be treated with ATD. - Gestational hyperthyroidism with clearly elevated
thyroid hormone levels (free T4 above the
reference range or total T4 150 of top normal
pregnancy value and TSH 0.1 U/ml) and evidence
of hyperthyroidism may require treatment as long
as clinically necessary - 4. AUTOIMMUNE THYROID DISEASE AND MISCARRIAGE
- 4.1. universal screening for antithyroid
antibodies and possible treatment cannot be
recommended at this time.
60- 5. THYROID NODULES AND CANCER
- 5.1. Fine-needle aspiration (FNA) cytology should
be performed for thyroid nodules larger than 1
cm. - Ultrasound-guided FNA minimizing inadequate
sampling. - 5.2. When nodules are discovered in the first or
early second trimester to be malignant on
cytopathological analysis or exhibit rapid
growth, - surgery should be offered in the second trimester
before fetal viability. - For papillary cancer or follicular neoplasm
without evidence of advanced disease - prefer to wait until the postpartum period for
definitive surgery - reassured that most well differentiated thyroid
cancers are slow growing - surgical treatment soon after delivery is
unlikely to adversely affect prognosis
61- 5.3. administer thyroid hormone to achieve a
suppressed but detectable TSH in pregnant women
with a previously treated thyroid cancer or an
FNA positive for or suspicious for cancer and
those who elect to delay surgical treatment until
postpartum. - High-risk patients benefit from a greater degree
of TSH suppression - free T4 or total T4 levels should ideally not be
increased above the normal range for pregnancy. - 5.4. RAI administration with 131I should not be
given to women who are breastfeeding. - pregnancy should be avoided for 6 months to 1 yr
in women with thyroid cancer who receive
therapeutic RAI doses to ensure stability of
thyroid function and confirm remission of thyroid
cancer.
62- 6. IODINE NUTRITION DURING PREGNANCY
- 6.1. Women of childbearing age average iodine
intake 150 g/d. - pregnancy and breastfeeding women should increase
intake to 250 g - 6.2. Iodine intake during pregnancy and
breastfeeding should not exceed twice the daily
recommended nutritional intake for iodine, i.e.
500 g iodine per day - 6.3. To assess the adequacy of the iodine intake
during pregnancy in a population, urinary iodine
concentration should be measured in a cohort of
the population. - Urinary iodine concentration should ideally range
between 150 and 250 g/liter. - 6.4. To reach the daily recommended nutrient
intake for iodine, multiple means must be
considered, tailored to the iodine intake level
in a given population. - 1) countries with iodine sufficiency and/or with
a well established universal salt iodization
(USI) program, - 2) countries without a USI program or an
established USI program where the coverage is
known to be only partial, and finally - 3) remote areas with no accessible USI program
and difficult socioeconomic conditions.
63- 7. POSTPARTUM THYROIDITIS
- 7.1. There are insufficient data to recommend
screening of all women for PPT. - 7.2. Women known to be thyroid peroxidase
antibody positive should have a TSH performed at
3 and 6 months postpartum - 7.3. The prevalence of PPT in women with type 1
diabetes is 3-fold greater than in the general
population. - Postpartum screening (TSH determination) is
recommended for women with type 1 diabetes
mellitus at 3 and 6 months postpartum - 7.4. Women with a history of PPT have a markedly
increased risk of developing permanent primary
hypothyroidism in the 5- to 10-yr period after
the episode of PPT. - An annual TSH level should be performed in these
women.
64- 7.5. Asymptomatic women with PPT who have a TSH
above the reference range but less than 10 U/ml
and who are not planning a subsequent pregnancy
do not necessarily require intervention but
should be remonitored in 48 wk. - Symptomatic women and women with a TSH above
normal and who are attempting pregnancy should be
treated with levothyroxine. - 7.6. There is insufficient evidence to conclude
whether an association exists between postpartum
depression and either PPT or thyroid antibody
positivity (in women who did not develop PPT). - women with postpartum depression should be
screened for hypothyroidism and appropriately
treated.
65- 8. SCREENING FOR THYROID DYSFUNCTION DURING
PREGNANCY - 1. Women with a history of hyperthyroid or
hypothyroid disease, PPT, or thyroid lobectomy. - 2. Women with a family history of thyroid
disease. - 3. Women with a goiter.
- 4. Women with thyroid antibodies (when known).
- 5. Women with symptoms or clinical signs
suggestive of thyroid underfunction or
overfunction, including anemia,elevated
cholesterol, and hyponatremia.
66- 6. Women with type I diabetes.
- 7. Women with other autoimmune disorders.
- 8. Women with infertility who should have
screening with TSH as part of their infertility
work-up. - 9. Women with previous therapeutic head or neck
irradiation. - 10. Women with a history of miscarriage or
preterm delivery.
67References
- 1. LeBeau Mandel.Thyroid Disorders During
Pregnancy.Endocrinol Metab Clin N Am 35 (2006)
117136. - 2. Neale et al. Thyroid Disease in Pregnancy.Clin
Perinatol 34 (2007) 543557. - 3. Abalovich et al. Guideline Thyroid
Dysfunction during and after Pregnancy. J Clin
Endocrinol Metab, August 2007, 92(8)
(Supplement)S1S47. - 4. Kronenber Williams Textbook of Endocrinology,
11th ed. - 5. Up To Date ver.15.1