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This chapter should be cited as follows:
Scheiber, M, Liu, J, Glob. libr. women's med.,
(ISSN: 1756-2228) 2011; DOI 10.3843/GLOWM.10340
This chapter was last updated:
June 2011

The Use of Gonadotropin-Releasing Hormone to Induce Ovulation

Authors

INTRODUCTION

Gonadotropin-releasing hormone (GnRH) was first isolated, characterized, and synthesized by Schally and Guillemin in 1971.1, 2, 3 However, it was the classic work by Knobil and co-workers demonstrating (1) that the pulsatile secretion of GnRH by the hypothalamus is the primary process controlling the menstrual cycle,4 and (2) that tonic GnRH stimulation causes downregulation of the pituitary GnRH receptor, that led to the widespread investigation of the therapeutic potentials of GnRH. Since that time, long-acting synthetic analogues of endogenous GnRH have gained widespread use in clinical gynecology for the treatment of pelvic pathology such as leiomyomas and endometriosis and as adjunctive therapy for use in ovulation induction with gonadotropins.

Since 1980, pulsatile GnRH has also been used with considerable success to stimulate the release of follicle-stimulating hormone (FSH) and luteinizing hormone (LH) from the pituitary gland for clinical ovulation induction.5, 6 This chapter reviews the physiology and rationale of ovulation induction with pulsatile GnRH, as well as patient selection and indications, therapy protocols, potential pitfalls, and expected outcomes.

PHYSIOLOGY

GnRH is a decapeptide that has been found in a number of mammals, including humans (Fig. 1). In postpubertal primates, GnRH is synthesized in the arcuate nucleus of the hypothalamus and is released in a pulsatile fashion and transported via the portal circulation to the anterior pituitary, where it stimulates the release of FSH and LH from gonadotropes. Immunohistochemical studies suggest that GnRH cells have an origin in the olfactory pit7 and migrate during early development to their final destination in the hypothalamus by approximately 11 weeks' gestation.8 The GnRH gene sequences were first isolated in 1984,9 and the human gene was localized to the short arm of chromosome 8 (Fig. 2).10 The GnRH decapeptide results from the post-translational processing of a larger 92 amino acid polypeptide and is frequently released in tandem with the GnRH-associated peptide (GAP). GAP may play a role in prolactin regulation. GnRH is rapidly degraded in the peripheral circulation, with a half-life of 2–8 minutes.11

Fig. 1. The amino acid sequence of the decapeptide gonadotropin-releasing hormone (GnRH), first isolated, characterized, and synthesized in 1971.

Fig. 2. Human GnRH gene consisting of four exons located on the short arm of chromosome 8. Exon I encodes a 5´ untranslated region. Exon II encodes GnRH and includes part of GAP. Exon III encodes GAP. Exon IV encodes the remainder of GAP and an untranslated region. (Zacur HA, Smith YR: Gonadotropin-releasing hormone and analogues in ovulation induction. In Wallach EE, Zacur HA [eds]: Reproductive Medicine and Surgery, pp 639–648. St. Louis, Mosby-Year Book, Inc., 1995; as modified from Sherwood NM, Lovejoy DA, Coe IR: Endocr Rev 14:241, 1993.)

A major advance in our understanding of GnRH physiology came in 1978, when Knobil and co-workers4 demonstrated that monkeys with lesions localized to the arcuate region had no detectable endogenous GnRH or gonadotropin release. Continuous replacement of exogenous GnRH in these monkeys led to gonadotropic desensitization resulting from a loss of GnRH receptors on the surface of the gonadotropes. However, exogenous replacement of GnRH in a pulsatile pattern, without varying the frequency or amplitude of administration, resulted in reinitiation of normal menstrual cycles characterized by orderly follicular development and a spontaneous midcycle LH surge. The findings that pulsatile administration of fixed doses of exogenous GnRH in the follicular phase of the primate menstrual cycle could lead to ovulation (and that overstimulation causes pituitary downregulation and unresponsiveness) form the basis for the clinical applications of GnRH use today.

Several features unique to the GnRH system make its pulsatile administration for ovulation induction theoretically advantageous compared to stimulation with either clomiphene citrate or exogenous gonadotropins. First, the GnRH receptors on pituitary gonadotropes increase in response to episodic GnRH stimulation. This 'self-priming' function allows an enhanced LH and FSH response to a steady dose of GnRH.12 Second, the feedback communication between the ovary and the pituitary remains intact, thereby allowing physiologic modulation of the cycle response and decreasing the risk of ovarian hyperstimulation or multiple pregnancy. Finally, for patients in whom fertility is a concern, GnRH has no antiestrogenic effects on the endometrium, thus providing a more receptive environment for implantation.

INDICATIONS AND PATIENT SELECTION

Given the aforementioned physiologic considerations, it follows reasonably that the women most likely to benefit from ovulation induction with pulsatile GnRH are those with an ovulatory defect resulting from deficient GnRH secretion. Thus, patients with hypogonadotropic hypogonadism will have the highest response rates. This group includes women with primary GnRH deficiency (e.g. Kallmann syndrome) as well as those with an intact hypothalamus but decreased GnRH release (e.g. hypothalamic amenorrhea). The success of GnRH stimulation in these patients led the Food and Drug Administration (FDA) to approve the use of intravenous (IV) pulsatile GnRH for ovulation induction in women with primary hypothalamic amenorrhea.

Ovaluation induction with pulsatile GnRH has also been used in many other settings. It has been used as a therapeutic modality in women with disordered endogenous GnRH secretion, such as polycystic ovary syndrome (PCOS), hyperandrogenic anovulation, and late-onset congenital adrenal hyperplasia, who are resistant to ovulation induction with clomiphene citrate. As will be discussed below, however, ovulation and pregnancy success rates in these groups are much lower than in women with hypogonadotrophic hypogonadism. Women with anovulation secondary to hyperprolactinemia respond similarly to those with GnRH deficiency, but the relative ease of administration and efficacy of the specific dopamine agonists make hyperprolactinemia a relatively rare indication for pulsatile GnRH. More logically, GnRH has also been used with success for ovulation induction in unusual causes of hypogonadotropic hypogonadism, such as the sequelae of treatment for cranial tumors13, 14 or amenorrheic lactating postpartum women.15

Depending on an infertile couple's history, documentation of tubal patency, normal uterine anatomy, and normal sperm parameters may be indicated before embarking on a course of pulsatile GnRH therapy. For women with anovulation resulting from conditions other than hypogonadotropic hypogonadism, a trial of clomiphene citrate is usually warranted before attempted ovulation induction with GnRH.

CLINICAL USE AND PROTOCOLS

Protocols using pulsatile GnRH and resulting in successful ovulatory responses and clinical pregnancies have been reported with varied doses, frequencies, and routes of administration; these will each be discussed later in more detail. All the clinical methods share in common the delivery of the pulsatile GnRH via a small, portable, programmable infusion pump. Several pumps are available in the United States, and all store a reservoir of GnRH solution and deliver a fixed or variable volume at specified intervals (e.g. Zyklomat, Ferring Laboratories, Ridgewood, New Jersey, USA; Auto Syringe, Auto Syringe Inc, Hooksett, New Hampshire, USA; Lutrepulse, Ortho Pharmaceutical, Raritan, New Jersey, USA). These pumps are similar to those used for insulin or tocolytic therapy, and most deliver the pulse over a 1-minute period.

Route of administration

Multiple routes of GnRH administration are available. Absorption occurs after IV, subcutaneous (SC), intramuscular (IM), nasal, and sublingual administration.16, 17, 18 Considerable debate exists over the preferred route of pulsatile GnRH administration for ovulation induction. Several centers have reported successful pregnancies using the SC administration of pulsatile GnRH.5, 19, 20, 21, 22 Most centers, however, have reported superior ovulation and pregnancy rates, as well as lower spontaneous abortion rates with IV administration.23, 24, 25, 26, 27, 28

The pharmacokinetic data clearly suggest the superiority of the IV route.23, 29 IV administration of pulsatile GnRH results in a well-defined episodic release of LH and FSH, whereas SC administration of identical GnRH pulses can result in prolonged absorption with a slower sustained rise in LH and FSH without a normal pulsatile pattern and a slower return to baseline (Fig. 3). Advocates of SC administration stress the relative convenience and safety of this route and save IV administration only for those subjects who fail SC therapy. Subsequent to the higher ovulatory rates, however, the FDA has approved only the IV route for pulsatile GnRH administration.

Fig. 3. LH and FSH levels in the same woman after 5-μg pulses of GnRH every 90 minutes administered either intravenously or subcutaneously. LRF, LH-releasing factor. (Liu JH, Yen SSC: The use of gonadotropin-releasing hormone for the induction of ovulation. Clin Obstet Gynecol 27:975, 1984; as modified from Reid RL, Leopold GR, Yen SSC: Induction of ovulation and pregnancy with pulsatile luteinizing hormone-releasing factor: Dosage and mode of delivery. Fertil Steril 36:553, 1981.)

At our institution, we favor the IV route of administration. Using sterile technique, a 22-gauge, 1 1/4-inch Teflon catheter is inserted into a vein in the nondominant forearm. Microbore plastic extension tubing (with a dead space less than 1 mL) is used to connect the catheter to the pump reservoir. Setups will vary depending on the pump and reservoir system chosen. A three-way stopcock between the reservoir and the extension tubing is often useful for refilling the reservoir or removing air from the line in certain setups. In our experience, patients tolerate the IV setup very well, and initial lines are often left in place for an entire cycle. A few programs leave the same peripheral IV in for several cycles,27 whereas others recommend changing the IV site every 3–7 days.30 Infection rates are generally low (see Complications section), and patient acceptance has been quite high in our experience.

Pulse frequency

The pulse frequency of endogenous GnRH in normal women during regular ovulatory menstrual cycles ranges from approximately 95 minutes in the early follicular phase to approximately 60–70 minutes in the periovulatory period.31, 32, 33 Luteal-phase pulses are of decreasing frequency but higher amplitude.

Based on Knobil's work in the monkey, original pulsatile GnRH ovulation induction in humans was largely performed with a fixed pulse frequency.5, 24 Excellent rates of ovulation (90–100%) and pregnancy have been reported with the use of fixed follicular-phase pulse frequencies of every 90 minutes26 and every 60 minutes,34 with little difference in steroid response, ovulation rates, or pregnancy rates being demonstrated between these two regimens.35 When pulse frequency was extended to 120 minutes, ovulation rates fell to approximately 70%.36 A 60-minute follicular-phase frequency has been shown more effective than a 120-minute frequency at inducing a spontaneous LH surge and ovulation in women with hypothalamic amenorrhea.37

In an effort to mimic the physiologic pulsations of GnRH in the normal menstrual cycle, some centers use a varying pulse frequency. A regimen using a 90-minute pulse frequency in the first week of folliculogenesis, followed by an increase in frequency to every 60 minutes in the midfollicular phase of the induced cycle, followed by a return to slower pulse frequency in the luteal phase, has been well described.27 The literature to date supports a follicular-phase pulse frequency of 90 minutes or less to achieve maximum spontaneous ovulation rates, and further studies need to be performed to determine whether there is an added benefit to cycle-specific, nonfixed frequency regimens.

Pulse dosage

Ovulation can be effectively induced over a range of GnRH doses. The optimal dose depends somewhat on the route of administration, because the SC route requires higher doses than the IV route. Studies have shown that a 1-μg pulse of IV GnRH will result in peak concentrations of GnRH within 4 minutes with levels between 200 and 260 pg/mL.38 These values correspond to the lower range of normal reported for pituitary portal blood concentrations (40–2000 pg/mL) in humans.39

Martin and associates27 elegantly defined the hormonal effects of varying IV pulse dosage at optimal pulse intervals. At a dosage of 25 ng/kg (1.25 μg/pulse for a 50-kg patient), the mean peak estradiol level was lower than in normal spontaneous cycles, corpus luteum function (as defined by integrated progesterone levels) was lower than normal, and ovulatory rates were only 80%. At 75 ng/kg (3.75 μg/pulse for a 50-kg patient), midcycle estradiol and progesterone levels were indistinguishable from normal cycles, and the ovulatory rate was 95%. At 100 ng/kg (5 μg/pulse for a 50-kg patient), high ovulatory rates were maintained (93%), but peak estradiol and integrated progesterone levels were exaggerated compared to normal cycles (Fig. 4).

Fig. 4. Serum levels of estradiol (E2) and progesterone (P) (mean ± SEM) in women receiving varying doses of IV pulsatile GnRH. Day 0 represents the midcycle surge, and mean ± SEM values in 62 normal ovulatory cycles are represented by the shaded areas. The data represent 10 cycles at 25 ng/kg, 31 cycles at 75 ng/kg, and 25 cycles at 100 ng/kg. (Martin K, Santoro N, Hall J et al: Clinical Review 15: Management of ovulatory disorders with pulsatile gonadotropin-releasing hormone. J Clin Endocrinol Metab 71:1081A, 1990.)

Thus, we recommend a starting dose for IV therapy of 75 ng/kg/pulse (approximately 3.5–5.0 μg/pulse). For women who do not respond to this pulse dose, the dose can be incrementally increased up to 10–20 μg/pulse. We administer our pulses in a 0.9% sodium chloride solution containing 10 μg/mL GnRH and 30 units of heparin/mL. When tailoring optimal dosage regimens, allowances should be made for considerable individual differences in GnRH requirements. Obese patients and those with PCOS may require much higher doses than average.

Clinical monitoring and luteal-phase support

The clinical monitoring of induced cycles varies with the setting in which therapy takes place, available clinical resources, and the comfort level of the practitioner and patient. Many centers combine serum estradiol and transvaginal ultrasound monitoring with urine ovulation prediction kits for timing of intercourse. A presumptive diagnosis of ovulation is made by clinical or ultrasonographic findings (e.g. disappearance of a dominant follicle with free pelvic fluid on ultrasound, LH surge determined by urine monitoring, elevated progesterone, clear rise in basal body temperature). Others take a more simple approach and use only cycle length and basal body temperature charting as an index of ovulation.

Most patients ovulate within 10–20 days of initiation of IV pulsatile GnRH therapy. Cycle variance results largely from the length of the early follicular phase. Women with absolute GnRH deficiencies tend to have longer follicular phases, because the pituitary must be primed for several days before active secretion of FSH and LH.

At our center, for the first treatment cycle, we prefer a combination of ultrasound and urine LH monitoring. During subsequent cycles, usually only LH monitoring is necessary. Serial ultrasound examinations are performed starting about day 10, and urine LH testing is initiated when the mean ultrasound diameter of the lead follicle is 15 mm. Sexual intercourse, or intrauterine insemination in couples with male-factor infertility, is timed by the urinary LH surge. In our experience, the lack of a spontaneous LH surge is rare. This is an important advantage of GnRH-stimulated cycles because it is the administration of human chorionic gonadotropin (hCG) that may play a critical role in the development of ovarian hyperstimulation syndrome in patients undergoing stimulation with gonadotropins. However, in patients with a lead follicle of 23 mm or greater and no spontaneous surge, ovulation may be induced by the IM injection of 5000 units of hCG.

Luteal-phase support of the corpus luteum is essential to the outcome of a GnRH-induced cycle. Three methods are frequently used in clinical practice, but no prospective data exist to suggest the superiority of one method over the other. If the cycle stimulation resulted in the ovulation of a healthy follicle, successful cycle support can be achieved by continuing pulsatile GnRH administration at the same dose and frequency used in the first part of the cycle.40 Other groups have reported achieving successful clinical pregnancies by slowing the pulse frequency to every 4 hours in the luteal phase, with no apparent shortening of the cycle.41 Similar clinical results can be achieved by discontinuing the GnRH pump after ovulation and administering 1500–2000 U of exogenous hCG every 3 days for four doses starting 2 days after presumed ovulation. This method is more convenient than continuation of the pump, but it does not allow for multiple monthly cycles using the same catheter, an option that some centers offer.

Pulsatile gonadotropin-releasing hormone and polycystic ovary syndrome

Patients with PCOS or other variants of hyperandrogenic oligo-ovulation present a special challenge for ovulation induction with GnRH. The disordered release of endogenous GnRH and LH in this subpopulation is often exaggerated by pulsatile GnRH therapy. Ovulatory rates in women with PCOS treated with pulsatile GnRH alone are as low as 40–60% per cycle.42 However, the addition of GnRH agonist (GnRHa) therapy to downregulate the pituitary and reduce ambient testosterone levels before initiating pulsatile GnRH therapy dramatically improves the outcome in these patients. Filicori and colleagues,43 in a small study, initially showed an increase in ovulatory cycles from 38 to 90% in PCOS patients pretreated with GnRHa. Subsequently, they published the results of 228 GnRH-induced cycles in women with multifollicular ovary, PCOS, and other forms of hyperandrogenic anovulation.34 Seventy-four per cent of post-GnRHa cycles were ovulatory compared to 59% of 104 cycles in the same groups of patients without GnRHa pretreatment. In PCOS patients alone, pretreatment with GnRHa improved ovulatory rates from 49% to 71%.

In a small study, pretreatment with GnRHa was shown to be superior to pretreatment with an estrogen-gestagen compound in terms of resultant ovulatory GnRH-induced cycles.44 Pretreatment with GnRHa also reduces the risk of multiple pregnancy in patients with PCOS undergoing ovulation induction with pulsatile GnRH.28

Despite GnRHa pretreatment, luteal-phase steroid secretion remains abnormal after GnRH-induced ovulation in women with PCOS, and elevated spontaneous abortion rates have been reported in those cycles resulting in pregnancy.28 Continuous pulsatile GnRH therapy in women with PCOS has been suggested to improve the endocrine milieu. In women with PCOS treated with 100 ng/kg of IV pulsatile GnRH during consecutive cycles, first cycles were characterized by elevated levels of LH and luteal-phase estradiol compared to second cycles, which better approximated levels found in normal, eumenorrheic women.45 In another study, however, a suboptimal endocrine pattern and a lower ovulatory rate were found when a second post-GnRHa cycle occurred without an initial repeat of analog suppression.43 Table 1 summarizes selected series studying ovulation induction with GnRH in women with PCOS.19, 26, 43, 46, 47, 48, 49, 50, 51, 52

Table 1. Outcomes with pulsatile GnRH therapy in women with PCOS in selected studies

Study

No. of cycles

GnRH dose (μg)

Frequency (min)

Route

Ovulatory cycles (%)

Pregnancy rate (%)

Saffan19

5

20

120

SC

40

0

Eshel52

108

15

90

SC

48

21

Hurwitz46

12

20–40

120–400

SC

17

0

Coelingh-Bennick47

42

10–20

90

IV

69

28

Ory48

6

90

IV

83

0

 

Burger49

85

5–40

60–120

IV

87

6

Wilson50

9

5–40

90

IV

0

0

Surrey51

9

5

90

IV

22

0

   Post-GnRHa

7

 

 

 

28

0

Filicori43

24

5

60

IV

38

8

   Post-GnRHa

21

 

 

 

90

38

Jansen26

14

2.5–5

60–120

IV

50

7


GnRH, gonadotropin-releasing hormone; GnRHa, GnRH agonist; PCOS, polycystic ovary syndrome; SC, subcutaneous; IV, intravenous.
(Modified from Santoro N, Elzahr D: Pulsatile gonadotropin-releasing hormone therapy for ovulatory disorders. Clin Obstet Gynecol 27:975,1984.)

 

In summary, women with PCOS constitute a more challenging population than those with hypothalamic amenorrhea for induction of ovulation with GnRH. For clomiphene-resistant women, however, pulsatile GnRH still represents a safe and relatively effective option that the clinician should consider before pursuing gonadotropin therapy. Pretreatment with GnRHa maximizes cycle potential in women with PCOS.

 

EXPECTED OUTCOMES

For women with hypogonadotropic hypogonadism, ovulation can be expected to occur in more than 90% of cycles (Table 2). Rates as low as 80% are reported from the earliest studies, but many of these stimulated cycles were performed with SC therapy and suboptimal pulse frequencies. In fact, ovulatory rates are so high in women with hypogonadotropic hypogonadism, that a failure in the delivery system should be considered in those women who do not ovulate. As discussed above, ovulatory rates are much lower in women with PCOS. In a review of 600 GnRH-induced cycles, decreased success was noted in overweight patients as well as those with elevated baseline LH, testosterone, and insulin levels.34

Table 2. Outcome with pulsatile GnRH therapy for ovulation induction in selected studies


Study

Indications

No. of patients

No. of cycles

GnRH dose (μg)

Frequency (min)

Route

Ovulatory cycles (%)

Pregnancy rate per ovulatory cycle (%)

Filicori34

HH, HA,

292

600

1.25–20

60–120

IV

75

23

 

PCOS, others

 

 

 

 

 

 

 

Liu41

HH, HA

17

45

1–10

60–240

IV

82

30

 

PCOS, others

 

 

 

 

 

 

 

Martin53

HA

41

118

3–15

60–240

IV

93

31

Filicori28

HH, HA, PCOS

114

187

2.5–5

60

IV

76

32

Santoro35

HA

7

20

5

60–240

IV

100

30

Jansen26

HH, HA

26

79

2.5

60

IV

97

34

Braat54

HH, HA

49

272

2–100

60–120

IV

90

23

Skarin22

HA

24

67

1–40

60

SC

96

28


HH, hypogonadotropic hypogonadism; HA, hypothalamic amenorrhea; PCOS, polycystic ovary syndrome; SC, subcutaneously; IV, intravenously

 

Pregnancy rates per GnRH-induced cycle for hypogonadotropic patients range from 18 to 32%, with slightly higher rates per ovulatory cycle (see Table 2). Life-table analysis has been performed in a number of studies. Martin and colleagues27 reported the cumulative conception rate using life-table analysis for 21 patients with idiopathic hypogonadotropic hypogonadism and hypothalamic amenorrhea. The cumulative chance of conceiving over six GnRH-induced cycles was 94%. Braat and co-workers54 reported a cumulative conception rate of 93% after 12 cycles, with a mean conception rate of 22.5% per cycle. Homburg and colleagues55 reported cumulative pregnancy rates of 93–100% at 6 months in women with idiopathic hypogonadotropic hypogonadism, amenorrhea related to low weight, and organic pituitary disease. In women with PCOS, the cumulative pregnancy rates fell to 74% at 6 months. All of these reported pregnancy rates compare favorably to the 73% 6-month cumulative pregnancy rate seen in normal, fertile women.56, 57

One retrospective study compared exogenous gonadotropin stimulation (30 patients and 111 cycles) to pulsatile GnRH therapy (41 patients and 118 cycles) for ovulation induction in hypogonadotropic amenorrhea.53 Overall ovulatory rates (93% vs. 97%) and pregnancy rates per cycle (29% vs. 25%) were not significantly different between the two groups. Life-table analysis, however, revealed a higher cumulative 6-month pregnancy rate for the GnRH group (96%) than the exogenous gonadotropin group (72%). To date, no randomized clinical trial has been performed comparing the two methods of therapy, but the life-table analyses clearly reveal the therapeutic efficacy of pulsatile GnRH therapy in the select group of patients with hypogonadotropic hypogonadism.

Miscarriage rates approximate 25–30% in GnRH-induced cycles.34, 53, 55 These rates tend to be lower in women with hypothalamic amenorrhea and higher in hyperandrogenic women with elevated body mass index. The miscarriage rate among women with PCOS who conceive during GnRH-induced cycles approximates 45%.34, 52

COMPLICATIONS

The overall incidence of complications with GnRH therapy is low. The risk of multiple gestation with pulsatile GnRH is greater than in the general population, but lower than that seen with exogenous gonadotropin therapy and comparable to that resulting from clomiphene citrate therapy. Rates of multiple gestation resulting from GnRH cycles is in the range of 4–8%.27, 34, 55, 53 Martin and co-workers53 reported more than two dominant follicles on ultrasound in 48% of gonadotropin-treated cycles compared to 19% of pulsatile GnRH-induced cycles, whereas three or more dominant follicles were seen in 17% vs. 5%, respectively. Homburg and associates55 and Filicori and colleagues34 reported a less than 1% incidence of triplets resulting from GnRH-induced cycles.

Mild ovarian hyperstimulation has occasionally been reported with GnRH-induced cycles,58 but resolves quickly upon discontinuation of the therapy, perhaps because the prolonged stimulus of exogenous hCG is rarely present. Moderate or severe ovarian hyperstimulation, however, is extraordinarily rare. This is in contrast to the reported experience with exogenous gonadotropins plus hCG with 23% of cycles resulting in mild to severe, and occasionally life-threatening, hyperstimulation syndrome.27

Infectious complications are also rare, even with prolonged indwelling IV catheter placement. Superficial phlebitis at IV sites and cellulitis at the site of SC catheters have been reported.59, 60 The largest prospective study to date followed 230 catheters for 1958 catheter days.61 Just 11% of all catheter tips cultured positive, and only 2% of 195 blood cultures were positive. All positive blood cultures were obtained from patients with catheters in place for only 4–7 days. No positive blood cultures were obtained from patients with 97 catheters in place for more than seven days. Two of the four positive blood cultures grew Staphylococcus epidermidis and were thought to be possible contaminants. None of the four patients with positive blood cultures were clinically ill, none received antibiotics, and three had follow-up blood cultures within 10 days, all of which were negative.

The data suggest that the use of IV administration is associated with a low incidence of infectious complications. Nevertheless, for women with cardiac valvular disease (e.g. mitral valve prolapse) or any prosthetic device, it may be preferable to use the SC route of administration to minimize the theoretic risk of endocarditis.

The potential of antibody formation with GnRH therapy apparently exists, but has not been extensively studied. A 3% rate of GnRH antibody formation during 3 weeks to 9 months of SC GnRH therapy in 141 men and 22 women has been reported,62 but the clinical significance of these findings remains unclear.

COST

The cost of ovulation induction with GnRH varies from institution to institution and depends largely on the expense of the monitoring performed. Martin and associates27 estimated the range of costs for GnRH cycles compared to exogenous gonadotropin cycles. They estimated that a pulsatile GnRH cycle costs $495–3180, whereas an exogenous gonadotropin cycle costs between $700 and $5795, depending on the cost of the drug and the type of monitoring used. However, because of the relative risks of hyperstimulation and multiple gestation associated with each method, it is reasonable to assume that most treatment cycles would be in the low range of the GnRH scale (with a minimum of clinical monitoring necessary) and the higher end of the gonadotropin scale (with frequent ultrasound and serum estradiol evaluation necessary).

FUTURE CONSIDERATIONS

The success of pulsatile IV GnRH therapy in inducing ovulation has led to consideration of its utility for in vitro fertilization techniques. Supraphysiologic doses of IV pulsatile GnRH (10 μg/pulse) at 60–120-minute intervals has been reported to override successfully the normal estradiol feedback mechanisms and induce multiple follicular development in normal, eumenorrheic women.63 During these stimulated cycles, two to five follicles of mature size on ultrasound were induced in all six subjects. Mean peak estradiol levels were 585 pg/mL. In addition, we have had a successful pregnancy result from in vitro fertilization after oocyte aspiration from a GnRH-stimulated cycle (abstract presented 1998 ASRM Annual Meeting).

Another use for GnRH analogue therapy is the induction of final follicular maturation or ovulation triggering in cycles of controlled ovarian stimulation either for in vitro fertilization or intrauterine insemination. This is usually accomplished as noted above by a trigger shot of hCG that will bind to the shared LH receptor and mimic the LH surge. However, hCG has a much longer half-life and binds to the receptor for considerably longer than LH, thereby increasing the risk of prolonged ovarian stimulation resulting in ovarian hyperstimulation syndrome (OHSS). Several published reports have demonstrated the ability of GnRH agonsists to induce a spontaneous LH surge leading to ovulation in ovulation induction cycles or final follicular maturation in IVF cycles. This can be accomplished with a reduction in the incidence of OHSS compared to hCG-triggering, and may represent another useful role for GnRH analogues in assisted reproduction.64, 65, 66

SUMMARY

From this overview, it is apparent that pulsatile IV GnRH represents a reliable, acceptable, safe, and effective means of physiologically inducing ovulation in anovulatory women. Patients with hypogonadotropic hypogonadism constitute a small subset of the total infertile population. Yet, for this group of women, pulsatile GnRH therapy essentially restores normal ovulatory and cumulative conception rates with extremely low risks of ovarian hyperstimulation and multiple pregnancy. Women with anovulation resulting from other disorders, such as PCOS, may also benefit from ovulation induction with GnRH. However, ovulation and pregnancy rates are lower than those seen with hypogonadotropic hypogonadism, and a trial of clomiphene citrate should be undertaken before attempting ovulation induction with GnRH. Pretreatment with GnRHa improves the outcome for women with PCOS.

Effective therapy can be administered by either the SC or IV route, although the pharmacologic data as well as our own experience support the superiority of IV administration. With this route, patient acceptance is high and infectious complications are low. The optimal physiologic dose for initial ovulation induction with pulsatile IV GnRH is 75 ng/kg/pulse administered every 60–90 minutes. Outpatient clinical monitoring (and, therefore, cycle cost) can be kept to a minimum while patient safety is assured. Spontaneous ovulation is the norm, and luteal-phase support with either continued GnRH or exogenous hCG is mandatory.

It is unclear why ovulation induction with pulsatile GnRH has not enjoyed the widespread use in the United States that it has in Europe as an alternative to exogenous gonadotropin therapy in anovulatory women. It is hoped, however, that its worldwide success will lead to increased usage in the United States and will stimulate further research into its use. Specific projects that need to be performed prospectively include a study to determine whether a variable pulse frequency is superior to a fixed frequency, a randomized clinical trial comparing GnRH therapy to exogenous gonadotropins, and a study examining the benefit of supraphysiologic doses of pulsatile GnRH to be used for multiple follicular development for the assisted reproductive technologies.

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