Role of growth hormone in ART cycles in poor responders: A literature review

Garima Kapoor; Shahida Naghma

doi:10.4103/fsr.fsr_17_22

View/Download PDF

Buy Reprints

PDF

Translate this page into:

Review Article

9 (

); 87-96

doi:

10.4103/fsr.fsr_17_22

Role of growth hormone in ART cycles in poor responders: A literature review

Garima Kapoor¹, Shahida Naghma²

1Department of Obstetrics & Gynaecology, VMMC & Safdarjung Hospital, New Delhi, India

2Sir Gangaram Hospital, New Delhi, India

Address for correspondence: Dr. Shahida Naghma, C1, B Block, Heritage Green Apartments, Chandan Hula, New Delhi-110074, India. E-mail: garimak79@yahoo.co.in

Received: 2022-07-25, Accepted: 2022-10-27, Published: 2022-12

Licence

This is an open access journal, and articles are distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 License, which allows others to remix, tweak, and build upon the work non-commercially, as long as appropriate credit is given and the new creations are licensed under the identical terms.

Disclaimer:
This article was originally published by Wolters Kluwer - Medknow and was migrated to Scientific Scholar after the change of Publisher.

Abstract

Growth hormone (GH) has been used as an adjunct in the field of female infertility treatment for more than 25 years, although, apart from treating women with GH deficiency its role has not yet been clarified. In the current shift of trend of delaying marriage and childbearing due to career and various other reasons, many women across the world are opting for assisted reproductive techniques (ART). This poses a challenge to the ART experts due to diminished ovarian reserve with advancing age in women. Over the years, the definition of poor responder has also evolved and after the Bologna criteria in 2011 and Poseidon classification, most of the recent studies have used a uniform criterion to define poor responders. The current review recruited studies conducted over the past decade, to ensure uniform criterion for poor responders. After a thorough literature search, 12 studies were selected for review based on the selection criteria a total of 1774 women were included in the intervention group while 3167 women were included in the control group. The review lead us to the conclusion that GH adjuvant therapy in poor responders reduced the dose/duration of gonadotropin used, increased endometrial thickness, improved the number of M II oocytes retrieved, embryos formed, clinical pregnancy rate. However, it has not shown to improve live birth rates in ART cycles. Since there is some evidence that GH adjuvant therapy may benefit young Poor Ovarian Response (POR), more number of large clinical trials need to be performed for further subgroup analysis and benefitting these women seeking ART.

Keywords

embryo quality

growth hormone

IVF

ovarian reserve

poor responder

Show Related Articles from PubMed

INTRODUCTION

Infertility affects around 8% to 10% of couples worldwide, out of the 60 to 80 million couple affected, nearly 15% to 20% are from India.^[1] There is a trend to delay marriage and childbearing and many women across the world are opting for assisted reproductive techniques (ART). This poses a challenge to the ART experts due to diminished ovarian reserve with advancing age in women.^[2,3,4,5,6] Several studies have reported that ovarian reserve diminishes earlier in Indian women.^[7,8] While, various adjuvants and therapies have been described in literature and used by experts for poor responders. However, most are without any proven benefits.^[2,3,5,6,9]

Growth hormone (GH) has been used extensively in ART procedures, both in normal and poor responders. However, its use has been off label except in rare condition of GH deficiency. As shown in animal models, GH induces the production of Insulin like growth factor-1 (IGF-I), which helps in ovarian estrogen production and follicular development. It also stimulates granulosa cells and increases gonadotropin secretions.^{[2,3,5,6,9,10]} Its role in POR is based on increased number of granulosa follicle stimulating hormone (FSH) and Leutinizing hormone (LH) receptors and enhanced mitochondrial activity.

While, there has been a considerable interest in the role of GH in poor responders, the literature is diverse, in terms of criteria used for poor responders, regimes of GH administration, and it is effect on the results of the ART cycle.

The definition of poor responder has also evolved and after the Bologna criteria in 2011 and Poseidon classification, most of the recent studies have used a uniform criteria to define poor responders.

MATERIALS AND METHODS

An online search was conducted on articles related to use of growth hormone (GH) in poor responders on PubMed, Google, Google scholar, Medline, Embase, Global health, Cochrane library. Search words “growth hormone,” “poor responders,” “poor,” “ovarian reserve,” “inadequate,” and “suboptimal” were used. The studies which met the following criteria were recruited for analysis:

Inclusion criteria

Used GH in the previous or the current cycle along with gonadotropins in poor responders undergoing in vitro fertilization (IVF)/intracytoplasmic injection (ICSI) and were controlled with poor responder women without use of GH in IVF/ICSI.
Used clinical pregnancy as an endpoint.

Exclusion criteria

Studies older than 10 years.

The current review recruited studies conducted over the past decade, to ensure uniform criterion for poor responders.

Outcome measures and definitions

The studies were evaluated for no. of oocytes (MII) retrieved, no. of embryos available for transfer, clinical pregnancy, live birth (if data available), miscarriage rates (Figure 1).

Clinical pregnancy: Presence of cardiac activity on ultrasound.

Live birth: Pregnancy delivered live beyond 24 weeks of gestation.

Miscarriage: Fetal loss before 20 weeks of gestation.

RESULTS

The literature search revealed 766 articles after the search words, which were narrowed down to 22 articles. Based on the selection criteria, only 12 studies were selected for review. A total of 1722 women were included in the intervention group while 3097 women were included in the control group. The main characteristics of the studies are given in Table 1 and the results in Table 2.

Most of the studies referred to Bologna criterion^[3,4,5,9,11] for defining poor responders. Bologna criteria define poor responders with any two of the following:

Age >40 years or any other factor for poor ovarian reserve.
Previous poor ovarian response (≤3 oocytes on ART cycles).
Poor ovarian reserve test (antral follicle count <5–7, anti-Mullerain hormone <0.5–1.1 ng/ml).

Zhu et al.^[3] and Cai et al.,^[5] further classified them into Poseidon group 3 and 4. Several studies have used the European Institute of Embryology & Infertility 2011 criterion^[2,6,10,11] for defining poor responders.

The European Institute for Embryology and Infertility in 2011 gave the following definition of POR as follows (having at least two of the three following criteria):

Age over 40 years,
The evidences of POR as having a maximum of three oocyte following induction protocol), and
Low ovarian reserve score (AFC less than 5–7, AMH less than 0.5–1.1 ng/ml).

While most of the studies were randomized clinical trials,^{[2,3,4,6,9,10,12,13]} while one of it was a retrospective study.^[5] Many studies had a small sample size.^{[2,4,6,9,10,11,12,13]}

DISCUSSION

Poor responders remain one of the most challenging situations, now, with women delaying marriage and childbearing, it is becoming increasingly more prevalent in ART cycles. The current review intends to explore the role of GH in ART cycle.

The current data provides evidence, that supplementation of GH, might improve oocyte retrieved, number of embryos obtained for embryo transfer, clinical pregnancy, however, there was no increase in the live birth rate.

The studies are heterogenous in terms of protocol, dose, and type of GH used. Choe et al.^[12] have used sustained release GH, Noeman et al.^[13] have used recombinant GH. Irrespective of the dose/protocol used, most of the studies have demonstrated that use of GH decreases the dose/duration of gonadotropins.^[2,3,6,9,10] The number of oocytes retrieved and embryos formed in GH treated cycle are significantly more.^[2,6,9,10] GH improves oocyte quality by upregulating GH receptors on the oocytes and enhancement of its mitochondrial activity. This scientific evidence may support of the use of GH adjuvant therapy in poor responders.

Most of the studies failed to show any improvement in the clinical pregnancy rate with GH adjuvant therapy.^{[2,3,5,6,9,10,12]} Li et al.^[4] demonstrated a clinically significant increase in clinical pregnancy rate in women treated with GH. This could be explained by a smaller sample size in the study, and hence, it needs to be validated on a larger number of participants.

While some studies showed a higher endometrial thickness in women treated with GH,^[4,9] it did not translate to higher clinical pregnancies.^{[2,3,5,6,9,10,12,13]}

Zhu et al.^[3] did a subgroup analysis and the results revealed that GH treatment significantly increased the number of day 3 embryos obtained in the subgroup of young PORs along with the long down-regulation protocol (63.11% vs. 49.35%; P = 0.004). GH treatment also reduced the risk of miscarriage in young PORs when used along with GnRH antagonist protocol (0.00% vs. 12%; P = 0.023).

The mechanism by which adjunct GH treatment improves IVF outcomes:

It helps gonadotropin in follicle recruitment and development.
It enhances oocyte maturation. It upregulates IGF-1 synthesis. Serum IGF-1 and IGFBP-3 increase following exogenous GH administration and lead to improved ovarian follicular maturation and steroidogenesis.^{[2,3,5,6,9,10]}

No difference was observed in the miscarriage rate in both the treated and control group.^{[2,3,4,5,6,9,10,11,12,13]}

Choe et al.,^[12] used sustained release GH (20 mg three times: mid-luteal, late-luteal, menstrual cycle day 2) instead of recombinant GH to reduce the number of injections for patient convenience. However, the study failed to demonstrate any effect on number of MII oocytes retrieved, embryos available for transfer, Clinical Pregnancy Rate (CPR), or live births. Maybe, more experience is needed with the dosing and timing of sustained release preparation.

Norman et al.^[13] conducted a multicentered double-blind, placebo controlled, randomized clinical trial comparing human GH to placebo with maximum stimulation in ART cycle. They recruited 62 for GH and 51 in control group. The study failed to demonstrate any effect of GH adjuvant therapy on CPR, live birth rates (LBR). This study was however, criticized because of the small sample size, failure to achieve randomization due to patient preference, frozen embryos were not utilized, and definition of poor responders was not as per the standard definitions.

A previous meta-analysis by Yu et al.^[16] concluded that GH supplementation for IVF/ICSI in POR increases the number of MII oocyte, 2PN, and obtained embryos. However, it did not increase implantation rate and clinical pregnancy rates. The studies selected were much older (1995, 2006–2013) and hence, were more heterogenous as well as had differences in methodology. The current review has included more recent studies, with a more uniform definition of POR.

Lacunae

The studies available in the literature have not explored the long-term outcomes of GH on the women or their off springs. Most of the studies have not performed the cost-effective analysis of GH administration in the ART cycles, considering its added costs and doubtful benefits in increasing the live birth rates. Some studies,^[3,4] have not included the outcomes of cryopreserved embryos, which may influence the cumulative LBR in GH treated cycles leading to its underestimation. Many have a small sample size^{[2,4,6,9,10,12,13]} hence, are underpowered to reach a statistically significant conclusion. One was retrospective,^[5] leading to an inherent bias.

CONCLUSIONS AND RECOMMENDATIONS

GH adjuvant therapy in poor responders reduced the dose/duration of gonadotropin used, increased endometrial thickness, improved the number of M II oocytes retrieved, embryos formed, clinical pregnancy rate, however, it has not shown to improve live birth rates in ART cycles.

Large clinical trials need to be performed for further subgroup analysis, as there is some evidence that GH adjuvant therapy may benefit young POR.

Financial support and sponsorship

Nil.

Conflicts of interest

The authors report no conflicts of interest.

Commentary

Drs Kapoor and Nagma are to be commended for attempting to make sense of the literature concerning the role of growth hormone (GH) in the management of poor ovarian response (POR). They demonstrate the shortcomings in published studies, which make it difficult to understand the true role, if any, of this intervention. A major issue is the lack of an agreed preparation and dose of GH. Perhaps even importantly, how does one judge how much GH to give to a particular patient? As we are not treating a GH deficiency (other than in cases of hypopituitarism), so we do not know whether we can and should titrate the dose, or just use a standard dose in all cases. The growing acceptance of the Poseidon classification holds out some promise for future research, but studies so far suffer from a lack of standardised definition of POR. Taking a ‘generous’ view of the evidence, it is possible that GH use in women with POR may be associated with a reduced need for gonadotropins, and hence a saving in the cost of gonadotropins. However, this could easily be offset by the cost of GH itself. This underscores the importance of considering not only just clinical effectiveness, but also cost-effectiveness of treatments. Pending stronger evidence of a benefit in the chance of live birth, it appears that clinicians do not have a strong reason to prescribe GH to women with POR and normal pituitary function.

Dr Raj Mathur

REFERENCES

Katole A, Saoji AV. Prevalence of primary infertility and its associated risk factors in urban population of central India: a community-based cross-sectional study. Indian J Community Med. 2019;44:337-41.
[Google Scholar]
Safdarian L, Aghahosseini M, Alyasin A, . Growth hormone (GH) improvement of ovarian responses and pregnancy outcome in poor ovarian responders: a randomized study. Asian Pac J Cancer Prev. 2019;20:2033-37.
[Google Scholar]
Zhu J, Wang Y, Chen L, Liu P, Li R, Qiao J. Growth hormone supplementation may not improve live birth rate in poor responders. Front Endocrinol (Lausanne). 2020;11:1.
[Google Scholar]
Li J, Chen Q, Wang J, Huang G, Ye H. Does growth hormone supplementation improve oocyte competence and IVF outcomes in patients with poor embryonic development? A randomized controlled trial. BMC Pregnancy Childbirth. 2020;20:310.
[Google Scholar]
Cai MH, Gao LZ, Liang XY, Fang C, Wu YQ, Yang X. The effect of growth hormone on the clinical outcomes of poor ovarian reserve patients undergoing in vitro fertilization/intracytoplasmic sperm injection treatment: a retrospective study based on POSEIDON criteria. Front Endocrinol (Lausanne). 2019;10:775.
[Google Scholar]
Bassiouny YA, Dakhly DMR, Bayoumi YA, Hashish NM. Does the addition of growth hormone to the in vitro fertilization/intracytoplasmic sperm injection antagonist protocol improve outcomes in poor responders? A randomized, controlled trial. Fertil Steril. 2016;105:697-702.
[Google Scholar]
Iglesias C, Banker M, Mahajan N, Herrero L, Meseguer M, Garcia-Velasco Juan. Ethnicity as a determinant of ovarian reserve: differences in ovarian aging between Spanish and Indian women. Fertil Steril 2014. 2014;102:244-49.
[Google Scholar]
Palgamkar JB, Jindal DK, Sawkar SV, Deshmukh SD, Katakdhond MS, Ishwar CP. Anti-mullerian hormone levels in Indian women seeking infertility treatment: are Indian women facing early ovarian senescence? J Hum Reprod Sci. 2021;14:380-5.
[Google Scholar]
Dakhly DMR, Bassiouny YA, Bayoumi YA, Hassan MA, Gouda HM, Hassan AA. The addition of growth hormone adjuvant therapy to the long down regulation protocol in poor responders undergoing in vitro fertilization: randomized control trial. Eur J Obstet Gynecol Reprod Biol. 2018;228:161-5.
[Google Scholar]
Bayoumi YA, Dakhly DM, Bassiouny YA, Hashish NM. Addition of growth hormone to the microflare stimulation protocol among women with poor ovarian response. Int J Gynaecol Obstet. 2015;131:305-8.
[Google Scholar]
Balasubramanyam S. Sequential use of testosterone gel and growth hormone in expected poor responders and those with previous poor assisted reproductive technology outcomes: a pilot study. Int J Infertil Fetal Med. 2017;8:1-4.
[Google Scholar]
Choe SA, Kim MJ, Lee HJ, . Increased proportion of mature oocytes with sustained-release growth hormone treatment in poor responders: a prospective randomized controlled study. Arch Gynecol Obstet. 2018;297:791-6.
[Google Scholar]
Norman RJ, Alvino H, Hull LM, . Human growth hormone for poor responders: a randomized placebo-controlled trial provides no evidence for improved live birth rate. Ann Rheum Dis. 2019;38:908-15.
[Google Scholar]
Nisha E, Sunitha HB, Vidya VB, Guddy KM. Efficacy of growth hormone in improving the pregnancy rate in poor responders in ART. Int J Reprod Contracept Obstet Gynecol. 2017;6:2883-6.
[Google Scholar]
Regan SLP, Knight PG, Yovich JL, Arfuso F, Dharmarajan A. Growth hormone during in vitro fertilization in older women modulates the density of receptors in granulosa cells, with improved pregnancy outcomes. Fertil Steril. 2018;110:1298-1310.
[Google Scholar]
Yu X, Ruan J, He LP, . Efficacy of growth hormone supplementation with gonadotrophins in vitro fertilization for poor ovarian responders: an updated meta-analysis. Int J Clin Exp Med. 2015;8:4954-67.
[Google Scholar]