ABSTRACT

The purpose of writing this review is to provide an update on recent advances in pregnancy and lactation-associated osteoporosis (PLO) research and summarize the current evidence for specific treatments. PLO is a transient and rare form of osteoporosis that affects women of childbearing age during the third trimester of pregnancy and post-partum. Though the pathophysiology of the PLO is poorly understood, several case series, case studies, and fewer cohort studies are available highlighting the role of pregnancy and lactation apart from conventional risk factors in the progression of PLO. Approximately 300 research and review articles related to PLO have been read from 1996 to 2023 which include several case studies, case series, cohort studies, meta-analyses, and narrative reviews from PubMed, Embase, Scopus, Google Scholar, World Health Organization regional databases. Common clinical manifestations include lower back and hip pain and rarely vertebral compression fractures. During pregnancy and lactation, women undergo reversible changes in mineral homeostasis and skeletal metabolism. Increased calcium absorption and urinary excretion during pregnancy and increased bone resorption along with renal calcium reabsorption in lactation are the main maternal metabolic adaptations that support the skeletal growth and development of the fetus and newborn respectively. Management of the PLO depends upon proper diagnosis and prognosis using biochemical bone turnover markers and bone histomorphometry. Conventional methods include calcium and vitamin D supplementation, giving up breastfeeding, physiotherapy, supportive braces, and bed rest. Bisphosphonates, denosumab, and teriparatide are commonly prescribed medications, assuring the recovery of bone mineral density besides certain side effects. Considering the transient nature, and underreporting of the cases, treatment recommendations should be personalized based on the parity, duration of lactation, presence or absence of fractures, societal status, age, ethnicity, and race.

Keywords: Osteoporosis, pregnancy, lactation, PTHrP, prolactin, teriparatide, bisphosphonates

Introduction

Osteoporosis is manifested by weakening of bone tissue, and disruption of bone microarchitecture leading to compromised bone strength, low bone mineral density (BMD), and an increase in fracture risk. It is estimated that there are more than 200 million osteoporosis affected people worldwide (1). Risk factors responsible for escalating the incidences of osteopenia and osteoporosis include pre-existing low BMD, aging, low calcium intake, smoking, low body mass index, estrogen deficiency, poor health, personal and family history of low trauma fractures due to osteoporosis, pregnancy and lactation (2,3).

Among all, conditions of osteopenia [T-score - between -1 and -2.50 standard deviation (SD)] and osteoporosis (T-score <-2.5 SD) are more prevalent in perimenopausal and postmenopausal women (4-6). The global prevalence of osteoporosis in women (perimenopausal and postmenopausal) is 23.1%, in premenopausal women between 2-4.7%, and in women below 40 years of age between 0.9-3% (7-9).

Pregnancy and lactation-associated osteoporosis (PLO) is a transient pathophysiological state characterized by back and hip pain, loss of height, lower BMD, and deteriorated bone micro-architecture. It is seldom presented with vertebral compression fractures. It is considered a rare form of osteoporosis however; the actual number of cases may be much higher due to less number of studies, poor awareness, and under-diagnosis. This may result in a poor prognosis of the disease (10,11). The PLO onset time is the third trimester of pregnancy to the early postpartum period during lactation (12). In the third trimester of pregnancy and during lactation, the skeleton experiences accelerated bone remodeling to meet growing calcium demands for fetal and neonatal skeletogenesis, apart from increased intestinal calcium absorption and urinary calcium excretion during pregnancy. This causes increased calcium release from the maternal skeleton leading to PLO (13).

In contrast to developed nations, the prevalence of PLO in developing countries could be more due to under-diagnosis, under-treatment, lack of awareness, multiparity along with prolonged lactation period, and malnutrition (11,14-16). The PLO can be more severe if the pre-pregnancy period has been with poor general nutrition including low calcium intake in the diet, low BMD along with positive family health history for osteoporosis (17). Though, bone loss associated with pregnancy and breastfeeding is transient and recovers fully at the same rate after weaning. However, in some cases, the skeletal calcium storehouse was depleted during lactation at the microstructural level and not fully replenished afterward (18,19).

Recent studies showed that frequent multiple pregnancies or multiparity and breastfeeding for longer duration is positively associated with vertebral fracture risks (14,20). In the case of multiparity, it has been observed that PLO with vertebral fractures may occur in any number of pregnancies (21). On the contrary, in one prospective cohort study which was carried out over 10 to 16 years of follow-up, parity and lactation each showed largely no correlation with the risk of osteoporotic fragility fractures, morphometric or morphological vertebral fractures, and changes in areal bone mineral density (22). Some studies also suggest that the patterns of parity and length of lactation have little or no impact on fracture risk or of pre- and post-menopausal women (23,24) instead length of lactation can provide protection against hip fracture in middle-aged and older women (25). One plausible explanation for this is that pregnancy and lactation may not be the risks for developing osteoporosis in long term.

A timely diagnosis of PLO and proper treatment can ensure a substantial recovery. To maintain skeletal homeostasis and normal during pregnancy and lactation, several preventive measures and management strategies can be suggested after reviewing biochemical and physiological parameters and BMD T-score. Some Food and Drug Administration (FDA)-approved drugs that are commonly prescribed are bisphosphonates, teriparatide, and denosumab. Currently, these drugs are prescribed along with calcium and vitamin D supplements for the management of osteoporosis in lactating females (26,27). The present review provides a holistic definition of PLO and discusses the likely mechanism involved in its onset, systematic investigations, and diagnostic tools with a brief discussion on the management of the disease. This present review is an effort to emphasize the significance of maintaining bone health in pregnant and lactating females and the need for carrying out epidemiological studies to arrive at conclusions necessary for setting up and/or updating guidelines.

Pathophysiology of PLO

In an adult, 99% of calcium is present in the bones as hydroxyapatite crystals [Ca₁₀(PO₄)₆(OH)₂] and the remaining 1% calcium is localized in the extracellular fluid and in the cell’s cytoplasm either in ionized form or bound to albumin and in other chemical complexes (28). It is the ionized form that is physiologically relevant and is maintained in the narrow range of 4.65 to 5.25 mg/dL (1.16 to 1.31 mM). Calcium homeostasis is essential to life and is precisely regulated by the calciotropic action of four hormones: hypercalcemic factors -parathyroid hormone (PTH), parathyroid-hormone related peptide (PTHrP), and 1,25-dihydroxycholecalciferol (1,25-DHC popularly known as calcitriol) and the hypocalcemic factor calcitonin (CT). Calcium homeostasis is achieved by: 1) the absorption of the mineral by the small intestine; 2) bone formation and resorption, and 3) urinary and fecal excretion and renal reabsorption.

Mammals are viviparous, and have evolved costly postnatal care in terms of energy expenditure. Maternal physiology has developed a variety of reproductive adaptations. To fulfill the calcium requirement for the skeletal growth of the developing fetus and the newborn, maternal bone metabolism and mineral homeostasis comes into effect.

Bone is the major storage site for minerals and proteins in the body and is continuously renewed by a process called skeletal remodeling throughout one’s life span. A bone remodeling cycle involves the action of the osteoblasts or the bone-forming cells, which are responsible for the secretion of bone matrix proteins and bone mineralization; while osteoclasts are responsible for resorption by dissolving extracellular matrix and demineralization; whereas, post-mitotically converted osteoblasts or osteocytes send mechano-sensory signals (29).

At term, ~30 g of calcium gets accumulated in the skeleton of the newborn (13). About 80% of this accretion takes place during the third trimester at which time maximum fetal skeletal growth occurs. The maternal serum ionized calcium concentration remains unchanged throughout pregnancy. During pregnancy, intestinal calcium absorption gets doubled and urinary excretion is increased with a moderate increase in bone turnover (30). PTH level declines below normal in the first two trimesters and then rises to mid-normal in the third trimester in women with adequate calcium intake. CT, PTHrP, calcitriol, estradiol, progesterone, prolactin (PL), and placental lactogen all increase during pregnancy. All of these hormones directly or indirectly contribute to elevated maternal intestinal calcium absorption through active and passive pathways (31). In vitro and in vivo animal studies confirm that both PTH and PTHrP modulate the transplacental flux of calcium to the fetus and their production is regulated by calcium-sensing receptor (32,33). Under the condition of insufficient maternal intestinal calcium absorption, unable to fulfill the combined calcium requirements of the mother and fetus, the maternal skeleton experiences increased resorption during the third trimester (13).

After birth, neonatal mineral homeostasis becomes progressively efficient due to metabolic adaptations involving bone, intestine, kidneys, and liver (30,34). Generally, a lactating female transfers 200-300 mg of calcium/day from breast milk (35). During lactation, ionized calcium and total calcium remain normal to the non-pregnant values. Renal calcium reabsorption and to a larger extent calcium ion mobilization from the bone through increased resorption enhance calcium in the milk. The hormonal milieu is generally characterized by low estradiol and progesterone, increased PTHrP, PL, and oxytocin. PTH level falls to the lower end of the normal range, whereas calcitriol and CT fall within the normal range. These hormonal changes affect calcium metabolism and lead to changes in the bone remodeling process, eventually the rate of bone resorption increases (30,36,37). Bone resorption is independent of maternal calcium intake during lactation and causes a 5-10% loss of trabecular mineral content in order to deliver calcium to milk (31). Bone resorption mainly promotes the activation of osteoclasts and affects the BMD of breastfeeding women (38).

During lactation resorption of bone occurs mainly by two pathways:

(i) Upregulated Osteoclast-mediated Bone Resorption

In upregulated osteoclast-mediated bone resorption, serum levels of PTH and PTHrP have been reported to increase during lactation (39,40). Elevated PTH level promotes osteoclastogenesis followed by an increase in bone resorption, and serum calcium levels which in turn reduces bone mass (40).

(ii) Osteocytic Osteolysis

It is a phenomenon when osteocytes behave like osteoclasts to resorb minerals from bone matrix. Negative feedback by CT or a high-calcium diet can suppress osteocytic osteolysis. Low-calcium diet, and PTH are the positive modulators of this process during late pregnancy (41,42).

There is a “Brain-Breast-Bone-Circuit” which gets activated by suckling (39). PL hormone secreted by anterior pituitary lactotrophs causes a decrease in the levels of Gonadotropin-Releasing Hormone (GnRH) which leads to low circulating levels of follicle stimulating hormone, and luteinizing hormone and subsequently low concentrations of estrogen and progesterone (43). PTH level helps osteoblasts to increase the secretion of receptor activator of nuclear factor kappa B ligand (RANKL) and reduce the formation of an antiresorptive cytokine, osteoprotegerin (also known as osteoclastogenesis inhibitory factor) (44). PL is an important regulator of the bone remodeling process. It has mainly two receptor isoforms, namely prolactin receptors (PRLR) short and long, expressed in osteoblasts but not in osteoclasts. In an in vitro study, it was found that the PL hormone upregulated the expression of various osteoclastogenic modulators such as monocyte chemo-attractant protein-1, cyclooxygenase-2, tumor necrosis factor-alpha, interleukin-1 and ephrin-B1 which eventually lead to increased skeletal resorption during lactation (45). The accessory parathyroid gland in the breast produces abundant PTHrP which enters the maternal circulation, binds with its receptor present on osteoclasts, and accelerates the process of bone matrix resorption (36). Suckling activates the PTHrP expression and release (39). Thus, both PL and PTHrP are responsible for maternal skeletal calcium release (46). At the basolateral side of epithelial cells of mice mammary glands, PTHrP helps in the transcellular flux of calcium in milk (43). The calcium then reaches the neonatal circulation and gets immobilized along with collagen and other non-collagenous bone matrix proteins as a result of bone modeling.

Approximately, 6% loss in occurs during 6 months of exclusive breastfeeding, and this loss causes microarchitectural deterioration, though the bone loss is normally silent and does not lead to fragility fractures (10,36,47). Irrespective of the duration of lactation, the length of postpartum amenorrhea is an important determinant of bone loss (30). The rate of bone loss differs by skeletal sites (42), and the resorption rate is higher from the trabecular-rich spine and hip as compared to that of the appendicular skeleton (30,40).

Management of Pregnancy and Lactation Associated-osteoporosis

Biochemical Markers of Bone Turnover

Several changes have been observed in calcium metabolism and bone remodeling during pregnancy and lactation, and it is now important to understand the severity level of osteoporosis using several bone resorption and bone formation markers in serum and urine. These biochemical markers have been used to gain a better understanding of the bone turnover dynamics during pregnancy and lactation (Table 1). Changes in the levels of PTH and 1,25-dihydroxyvitamin D do not play a role in reflecting the degree of bone loss during pregnancy (30,55) and during lactation (61). However, circulating level of calcitriol increases during the first trimester of pregnancy and influences the intestinal absorption of calcium (55). Serum concentrations of PTHrP increase during pregnancy which eventually results in bone resorption and increased urinary levels of pyridinoline and deoxypyridinoline significantly in the second and third trimesters (55). Increased levels of serum PTHrP and PL and decreased levels of estradiol are reported to be associated with lactation-induced bone loss during the first 6 months of exclusive breastfeeding (30). Increased bone resorption was studied by observing the increase in serum C telopeptide of type I collagen (CTX) which was twofold higher in lactating females than those of non-pregnant females, serum N-telopeptide of type I collagen (NTX) and urinary deoxypyridinoline also increases (13). Bone specific alkaline phosphatase and osteocalcin concentrations were higher in the lactating group than those in the control group (57).

Table 1

During lactation, progressive loss of BMD can be assessed by dual-energy X-ray absorptiometry (DXA), and changes in bone histomorphometry can be assessed with the help of micro-computed tomography. High resolution-peripheral quantitative computed tomography is widely used for microarchitectural deterioration of bone tissue in breastfeeding females (Table 1) (58,62).

Prevention

Guidelines of various agencies worldwide (Table 2) recommend regular intake of calcium (1500 mg per day) through diet and/or with oral supplements during pregnancy and lactation. Similarly, for vitamin D, diet is sufficient but if deficiency occurs supplements of vitamin D (1000-2000 IU per day) can be recommended (68). In developed countries like the USA, there are several programs being run to fulfill the dietary need of pregnant and lactating females by considering the need of each socioeconomic group (64). In the developing world, where PLO is underestimated, under-diagnosed, and under-treated, such programs need to be developed and are necessary to run with proper assessment of socioeconomic status and needs of pregnant and lactating females. Assessment of biochemical bone turnover markers during pregnancy and after should be carried out at regular time intervals. If required, DXA or pQCT can be recommended for BMD assessment postnatally. If the symptoms of osteoporosis appear, weaning off breastfeeding should be the first recommendation. However, it is important to mention here that all the above-mentioned guidelines are for general requirements of calcium and vitamin D during pregnancy and lactation and are not specific to PLO.

Table 2

Therapeutic Interventions

The majority of case studies have reported that BMD recovers spontaneously after breastfeeding females have given up lactation within a year after weaning if no other causes are involved (69-71). On the other hand, secondary causes of PLO should be identified and treated. Some conservative strategies for the management of PLO include weaning off, calcium and vitamin D supplementation as per the above-mentioned guidelines (Table 2), avoiding lifting heavy weights, and physiotherapy (72,73). Patients with severe cases of osteoporosis (BMD T-score <-2.5 SD) or with vertebral compression fractures may be advised for using supporting vertebral corsets and bed rest to relieve back and hip pain (72,74). Along with weaning, certain medications can be given to treat these cases, though; no specific treatment guidelines have been developed for PLO as yet. PLO patients have commonly been treated either with anti-resorptive agents like bisphosphonates or anabolic agents like teriparatide depending on the severity of the case or the stage of the disease and sometimes these are used in combination or in a sequential manner (Table 3).

Table 3

Bisphosphonates

Bisphosphonates are nitrogen-containing anti-resorptive compounds which show strong binding affinity to bone and are the most commonly used drugs. They inhibit the proliferation of osteoclasts, promote osteoclasts apoptosis, and modulate the bone turnover process so as to promote mineralization density (89). Commonly used bisphosphonates are alendronate, zoledronate and risedronate (49,90).

Therapeutic safety considerations of bisphosphonates treatment include complications of the upper gastrointestinal tract, fever, joint pain, transplacental transport, etc. (49,91,92). Data from animal and clinical studies suggest that they circulate in maternal serum, subsequently reach the placental barrier, and may have negative effects on pregnancy outcomes (early delivery, low birth weights, hypocalcaemia, and skeletal retardations of the newborns) (91,93). Generally, these drugs accumulate in the skeleton after their administration due to their high affinity with hydroxyapatite crystals (89,92).

Denosumab

Denosumab is a type of humanized monoclonal antibody which suppresses the RANKL-RANK signaling pathway of osteoclastogenesis. Denosumab binds to RANKL and prevents it from activating RANK thus helping in the suppression of bone resorption (94).

Accumulation of denosumab in breast milk has not been reported yet, but the drug can cross the placenta and affect fetal bone development (95). It can be used either alone or in combination with teriparatide as sequential therapy during lactation with satisfactory clinical efficacy (21).

Teriparatide

An osteoanabolic recombinant formulation, teriparatide shares similarities with the first 34 amino acids of PTH. Numerous case reports and cohort studies on the treatment with teriparatide of PLO patients belonging to different ethnicities and races are available (Table 3). It has been used to treat cases of PLO with a remarkable increase in the BMD at the lumbar spine, femoral neck, and hip with no new fracture and reduction in bone resorption markers (26,85,96-98).

This drug is commonly used due to its clinical efficacy and short half-life. However, the potential side effect is the risk of bone tumors, which is dependent on the dosage of teriparatide (21).

Other Anabolic Medications

Romosozumab and abaloparatide are two more FDA-approved anabolic interventions for the management of osteoporosis (99). Abaloparatide shares 76% homology to PTHrP and selectively activates PTHR1 favoring bone formation (100). Romosozumab is a monoclonal antibody that targets sclerostin secreted by osteocytes. The canonical Wnt/b-catenin pathway plays a crucial role in osteoblasts proliferation and differentiation. Sclerostin suppresses the canonical Wnt/b-catenin pathway by binding to low density lipoprotein receptor-related protein 5/6 (LRP5/6) co-receptors (101). Romosozumab binds to sclerostin and prevents inhibition of bone formation with mild adverse events (102).

Various clinical studies highlight the role of romosozumab and abaloparatide in improving BMD and bone turnover markers and a concomitant relief from back pain with no further fractures in postmenopausal osteoporosis (100,103,104). A 23.6% increase in lumbar spine, a 6.2% increase in femoral neck, and an 11.2% increase in total hip BMD of a 34-year-old woman who presented with severe low back pain and multiple vertebral fractures after she received romosozumab for 12 months has been reported (88). There were no reports on abaloparatide treatment of PLO women.

Kyphoplasty and Vertebroplasty

Kyphoplasty and vertebroplasty were reported for treating pregnancy and lactation-associated osteoporotic vertebral fragility fractures and compression fractures with other therapeutic interventions. Kyphoplasty and vertebroplasty are a very successful treatments for short-term pain relief for vertebral fractures (59,74,105,106).

Conclusion and Future Perspective

PLO is a rare disease and the number of cases is low, possibly due to underreporting and ignorance in the population about the situation mainly in the developing world. This calls for the need to reassess the societal status of the population while formulating new guidelines and public health policies. Further investigations into the correlation between pregnancy, lactation, and BMD, and subsequent risk of osteoporosis will provide new opportunities for early intervention, timely management, and prevention of PLO.

Treatment recommendations should be personalized based on number of parities, duration of lactation, presence or absence of fractures, societal status, age, ethnicity and race. By integrating the systems biology with P4 (predictive, preventive, personalized and participatory) medicine care social, psychological, economic and healthcare related burden can be reduced towards a more productive society.

Acknowledgments: We thank Dr. MD. Arshad and Dr. Rahul Gupta for critical reading of the manuscript and providing valuable suggestions.

Ethics

Authorship Contributions

Concept: N.M., M.G., Design: N.M., M.G., Literature Search: N.M., H.M., M.G., Writing: N.M., H.M., M.G.

Conflict of Interest: No conflict of interest was declared by the authors.

Financial Disclosure: ICMR; file No. 3/1/3(24)/Endo-fellowship/22-NCD-III to HM.

References

Kanis, JA. Assessment of Osteoporosis at the Primary Health Care Level. WHO Collaborating Centre for Metabolic Bone Diseases. University of Sheffield Medical School: Printed by the University of Sheffield; 2008. p. 6.

Kanis JA, McCloskey EV. Risk factors in osteoporosis. Maturitas 1998;30:229-33.

O’Sullivan SM, Grey AB, Singh R, Reid IR. Bisphosphonates in pregnancy and lactation-associated osteoporosis. Osteoporos Int 2006;17:1008-12.

Finkelstein JS, Brockwell SE, Mehta V, Greendale GA, Sowers MR, Ettinger B, et al. Bone mineral density changes during the menopause transition in a multiethnic cohort of women. J Clin Endocrinol Metab 2008;93:861-8.

Shariati-Sarabi Z, Rezaie HE, Milani N, Rezaie FE, Rezaie AE. Evaluation of Bone Mineral Density in Perimenopausal Period. Arch Bone Jt Surg 2018;6:57-62.

Management of osteoporosis in postmenopausal women: the 2021 position statement of The North American Menopause Society. Menopause 2021;28:973-97.

Sang JH, Hwang I, Han H, Lee W, Kim T, Lee H, et al. Prevalence of Osteoporosis and Osteopenia in Women in Gumi Gyeongbuk Province. J Korean Soc Menopause 2012;18:28-35.

Kaushal N, Vohora D, Jalali RK, Jha S. Prevalence of osteoporosis and osteopenia in an apparently healthy Indian population - a cross-sectional retrospective study. Osteoporos Sarcopenia 2018;4:53-60.

Salari N, Ghasemi H, Mohammadi L, Behzadi MH, Rabieenia E, Shohaimi S, et al. The global prevalence of osteoporosis in the world: a comprehensive systematic review and meta-analysis. J Orthop Surg Res 2021;16:609.

Hellmeyer L, Hadji P, Ziller V, Wagner U, Schmidt S. Osteoporose in der Schwangerschaft. Geburtshilfe Frauenheilkd 2004;64:38-45.

Stumpf UC, Kurth AA, Windolf J, Fassbender WJ. Pregnancy-associated osteoporosis: an underestimated and underdiagnosed severe disease. A review of two cases in short- and long-term follow-up. Adv Med Sci 2007;52:94-7.

Cerit ET, Cerit M. A case of pregnancy and lactation associated osteoporosis in the third pregnancy; robust response to teriparatide despite delayed administration. Bone Rep 2020;13:100706.

Kovacs CS. Maternal Mineral and Bone Metabolism During Pregnancy, Lactation, and Post-Weaning Recovery. Physiol Rev 2016;96:449-547.

Panahi N, Ostovar A, Fahimfar N, Gharibzadeh S, Shafiee G, Heshmat R, et al. Grand multiparity associations with low bone mineral density and degraded trabecular bone pattern. Bone Rep 2021;14:101071.

Kaya AE, Doğan O, Başbuğ A, Sönmez CI, Sungur MA, Ataoğlu S. An Evaluation of the Association of Reproductive History and Multiple Births during Adolescence with Postmenopausal Osteoporosis. Geburtshilfe Frauenheilkd 2019;79:300-7.

Lee EN. Effects of Parity and Breastfeeding Duration on Bone Density in Postmenopausal Women. Asian Nurs Res (Korean Soc Nurs Sci) 2019;13:161-7.

Di Gregorio S, Danilowicz K, Rubin Z, Mautalen C. Osteoporosis with vertebral fractures associated with pregnancy and lactation. Nutrition 2000;16:1052-5.

Kovacs CS. The Skeleton Is a Storehouse of Mineral That Is Plundered During Lactation and (Fully?) Replenished Afterwards. J Bone Miner Res 2017;32:676-80.

Grizzo FMF, Alarcão ACJ, Dell’ Agnolo CM, Pedroso RB, Santos TS, Vissoci JRN, et al. How does women’s bone health recover after lactation? A systematic review and meta-analysis. Osteoporos Int 2020;31:413-27.

Bolzetta F, Veronese N, De Rui M, Berton L, Carraro S, Pizzato S, et al. Duration of breastfeeding as a risk factor for vertebral fractures. Bone 2014;68:41-5.

Qian Y, Wang L, Yu L, Huang W. Pregnancy- and lactation-associated osteoporosis with vertebral fractures: a systematic review. BMC Musculoskelet Disord 2021;22:926.

Cooke-Hubley S, Gao Z, Mugford G, Kaiser SM, Goltzman D, Leslie WD, et al. Parity and lactation are not associated with incident fragility fractures or radiographic vertebral fractures over 16 years of follow-up: Canadian Multicentre Osteoporosis Study (CaMos). Arch Osteoporos 2019;14:49.

Mori T, Ishii S, Greendale GA, Cauley JA, Ruppert K, Crandall CJ, et al. Parity, lactation, bone strength, and 16-year fracture risk in adult women: findings from the Study of Women’s Health Across the Nation (SWAN). Bone 2015;73:160-6.

Crandall CJ, Liu J, Cauley J, Newcomb PA, Manson JE, Vitolins MZ, et al. Associations of Parity, Breastfeeding, and Fractures in the Women’s Health Observational Study. Obstet Gynecol 2017;130:171-80.

Bjørnerem A, Ahmed LA, Jørgensen L, Størmer J, Joakimsen RM. Breastfeeding protects against hip fracture in postmenopausal women: the Tromsø study. J Bone Miner Res 2011;26:2843-50.

Hong N, Kim JE, Lee SJ, Kim SH, Rhee Y. Changes in bone mineral density and bone turnover markers during treatment with teriparatide in pregnancy- and lactation-associated osteoporosis. Clin Endocrinol (Oxf) 2018;88:652-8.

Treurniet S, Bevers MSAM, Wyers CE, Micha D, Teunissen BP, Elting MW, et al. Bone Microarchitecture and Strength Changes During Teriparatide and Zoledronic Acid Treatment in a Patient with Pregnancy and Lactation-Associated Osteoporosis with Multiple Vertebral Fractures. Calcif Tissue Int 2023;112:621-7.

Hernández-Castellano LE, Hernandez LL, Bruckmaier RM. Review: Endocrine pathways to regulate calcium homeostasis around parturition and the prevention of hypocalcemia in periparturient dairy cows. Animal 2020;14:330-8.

Prideaux M, Findlay DM, Atkins GJ. Osteocytes: The master cells in bone remodelling. Curr Opin Pharmacol 2016;28:24-30.

Kalkwarf HJ, Specker BL. Bone mineral changes during pregnancy and lactation. Endocrine 2002;17:49-53.

Kovacs CS, Kronenberg HM. Maternal-fetal calcium and bone metabolism during pregnancy, puerperium, and lactation. Endocr Rev 1997;18:832-72.

VanHouten J, Dann P, McGeoch G, Brown EM, Krapcho K, Neville M, et al. The calcium-sensing receptor regulates mammary gland parathyroid hormone-related protein production and calcium transport. J Clin Invest 2004;113:598-608.

Ardeshirpour L, Dann P, Pollak M, Wysolmerski J, VanHouten J. The calcium-sensing receptor regulates PTHrP production and calcium transport in the lactating mammary gland. Bone 2006;38:787-93.

Sanz-Salvador L, García-Pérez MÁ, Tarín JJ, Cano A. Bone metabolic changes during pregnancy: a period of vulnerability to osteoporosis and fracture. Eur J Endocrinol 2015;172:R53-65.

Heringhausen J, Montgomery KS. Continuing education module-maternal calcium intake and metabolism during pregnancy and lactation. J Perinat Educ 2005;14:52-7.

Kovacs CS. The role of PTHrP in regulating mineral metabolism during pregnancy, lactation, and fetal/neonatal development. Clin Rev Bone Miner Metab 2014;12:142-64.

Canul-Medina G, Fernandez-Mejia C. Morphological, hormonal, and molecular changes in different maternal tissues during lactation and post-lactation. J Physiol Sci 2019;69:825-35.

Grimes JP, Wimalawansa SJ. Breastfeeding and postmenopausal osteoporosis. Curr Womens Health Rep 2003;3:193-8.

Wysolmerski JJ. Interactions between breast, bone, and brain regulate mineral and skeletal metabolism during lactation. Ann. N Y Acad Sci 2010;1192:161-9.

Miyamoto T, Miyakoshi K, Sato Y, Kasuga Y, Ikenoue S, Miyamoto K, et al. Changes in bone metabolic profile associated with pregnancy or lactation. Sci Rep 2019;9:6787.

Qing H, Ardeshirpour L, Pajevic PD, Dusevich V, Jähn K, Kato S, et al. Demonstration of osteocytic perilacunar/canalicular remodeling in mice during lactation. J Bone Miner Res 2012;27:1018-29.

Ryan BA, Kovacs CS. The puzzle of lactational bone physiology: osteocytes masquerade as osteoclasts and osteoblasts. J Clin Invest 2019;129:3041-4.

VanHouten JN, Wysolmerski JJ. Low estrogen and high parathyroid hormone-related peptide levels contribute to accelerated bone resorption and bone loss in lactating mice. Endocrinology 2003;144:5521-9.

Ma YL, Cain RL, Halladay DL, Yang X, Zeng Q, Miles RR, et al. Catabolic effects of continuous human PTH (1--38) in vivo is associated with sustained stimulation of RANKL and inhibition of osteoprotegerin and gene-associated bone formation. Endocrinology 2001;142:4047-54.

Macari S, Sharma LA, Wyatt A, da Silva JM, Dias GJ, Silva TA, et al. Lactation induces increases in the RANK/RANKL/OPG system in maxillary bone. Bone 2018;110:160-9.

Sowers M. Pregnancy and lactation as risk factors for subsequent bone loss and osteoporosis. J Bone Miner Res 1996;11:1052-60.

Kyvernitakis I, Reuter TC, Hellmeyer L, Hars O, Hadji P. Subsequent fracture risk of women with pregnancy and lactation-associated osteoporosis after a median of 6 years of follow-up. Osteoporos Int 2018;29:135-42.

Scioscia MF, Vidal M, Sarli M, Guelman R, Danilowicz K, Mana D, et al. Severe Bone Microarchitecture Impairment in Women With Pregnancy and Lactation-Associated Osteoporosis. J Endocr Soc 2021;5:bvab031.

Li LJ, Zhang J, Gao P, Lv F, Song YW, Chang XY, et al. Clinical characteristics and bisphosphonates treatment of rare pregnancy- and lactation-associated osteoporosis. Clin Rheumatol 2018;37:3141-50.

Black AJ, Topping J, Durham B, Farquharson RG, Fraser WD. A detailed assessment of alterations in bone turnover, calcium homeostasis, and bone density in normal pregnancy. J Bone Miner Res 2000;15:557-63.

Ulrich U, Miller PB, Eyre DR, Chesnut CH 3rd, Schlebusch H, Soules MR. Bone remodeling and bone mineral density during pregnancy. Arch Gynecol Obstet 2003;268:309-16.

Naylor KE, Iqbal P, Fledelius C, Fraser RB, Eastell R. The effect of pregnancy on bone density and bone turnover. J Bone Miner Res 2000;15:129-37.

More C, Bhattoa HP, Bettembuk P, Balogh A. The effects of pregnancy and lactation on hormonal status and biochemical markers of bone turnover. Eur J Obstet Gynecol Reprod Biol 2003;106:209-13.

Møller UK, Við Streym S, Mosekilde L, Rejnmark L. Changes in bone mineral density and body composition during pregnancy and postpartum. A controlled cohort study. Osteoporos Int 2012;23:1213-23.

Paoletti AM, Orrù M, Floris L, Guerriero S, Ajossa S, Romagnino S, et al. Pattern of bone markers during pregnancy and their changes after delivery. Horm Res 2003;59:21-9.

Butscheidt S, Tsourdi E, Rolvien T, Delsmann A, Stürznickel J, Barvencik F, et al. Relevant genetic variants are common in women with pregnancy and lactation-associated osteoporosis (PLO) and predispose to more severe clinical manifestations. Bone 2021;147:115911.

Carneiro RM, Prebehalla L, Tedesco MB, Sereika SM, Hugo M, Hollis BW, et al. Lactation and bone turnover: a conundrum of marked bone loss in the setting of coupled bone turnover. J Clin Endocrinol Metab 2010;95:1767-76.

Bjørnerem Å, Ghasem-Zadeh A, Wang X, Bui M, Walker SP, Zebaze R, et al. Irreversible Deterioration of Cortical and Trabecular Microstructure Associated With Breastfeeding. J Bone Miner Res 2017;32:681-7.

Sánchez A, Zanchetta MB, Danilowicz K. Two cases of pregnancy- and lactation- associated osteoporosis successfully treated with denosumab. Clin Cases Miner Bone Metab 2016;13:244-6.

Cohen A, Kamanda-Kosseh M, Dempster DW, Zhou H, Müller R, Goff E, et al. Women With Pregnancy and Lactation-Associated Osteoporosis (PLO) Have Low Bone Remodeling Rates at the Tissue Level. J Bone Miner Res 2019;34:1552-61.

Glerean M, Plantalech L. Osteoporosis en embarazo y lactancia [Osteoporosis in pregnancy and lactation]. Medicina (B Aires) 2000;60:973-81.

Ó Breasail M, Prentice A, Ward K. Pregnancy-Related Bone Mineral and Microarchitecture Changes in Women Aged 30 to 45 Years. J Bone Miner Res 2020;35:1253-62.

U.S. Department of Agriculture and U.S. Department of Health and Human Services. Dietary Guidelines for Americans, 2020-2025. 9th Edition. December 2020. visited on: April19, 2024.

https://www.cdc.gov/breastfeeding/breastfeeding-special-circumstances/diet-and-micronutrients/maternal-diet.html

Available from: URL: https://iris.who.int/bitstream/handle/10665/85313/9789241504935_eng.pdf?sequence=1 Accessed April 19, 2024.

Available from: URL: https://main.mohfw.gov.in/sites/default/files/9147562941489753121.pdf Accessed April 20, 2024.

https://nhm.gov.in/images/pdf/programmes/maternal-health/guidelines/National_Guidelines_for_Calcium_Supplementation_During_Pregnancy_and_Lactation.pdf

Kominiarek MA, Rajan P. Nutrition Recommendations in Pregnancy and Lactation. Med Clin North Am 2016;100:1199-215.

Sowers M, Corton G, Shapiro B, Jannausch ML, Crutchfield M, Smith ML, et al. Changes in bone density with lactation. JAMA 1993;269:3130-5.

Phillips AJ, Ostlere SJ, Smith R. Pregnancy-associated osteoporosis: does the skeleton recover? Osteoporos Int 2000;11:449-54.

Iwamoto J, Sato Y, Uzawa M, Matsumoto H. Five-year follow-up of a woman with pregnancy and lactation-associated osteoporosis and vertebral fractures. Ther Clin Risk Manag 2012;8:195-9.

Prevention and management of osteoporosis. World Health Organ Tech Rep Ser 2003;921:1-164.

Gehlen M, Lazarescu AD, Hinz C, Boncu B, Schmidt N, Pfeifer M, et al. Schwangerschaftsassoziierte Osteoporose [Pregnancy and lactation-associated osteoporosis]. Z Rheumatol 2017;76:274-8.

Bonacker J, Janousek M, Kröber M. Pregnancy-associated osteoporosis with eight fractures in the vertebral column treated with kyphoplasty and bracing: a case report. Arch Orthop Trauma Surg 2014;134:173-9.

Butscheidt S, Delsmann A, Rolvien T, Barvencik F, Al-Bughaili M, Mundlos S, et al. Mutational analysis uncovers monogenic bone disorders in women with pregnancy-associated osteoporosis: three novel mutations in LRP5, COL1A1, and COL1A2. Osteoporos Int 2018;29:1643-51.

Eroglu S, Karatas G, Aziz V, Gursoy AF, Ozel S, Gulerman HC. Evaluation of bone mineral density and its associated factors in postpartum women. Taiwan J Obstet Gynecol 2019;58:801-4.

Gehlen M, Lazarescu AD, Hinz C, Schwarz-Eywill M, Pfeifer M, Balasingam S, et al. Long-term outcome of patients with pregnancy and lactation-associated osteoporosis (PLO) with a particular focus on quality of life. Clin Rheumatol 2019;38:3575-83.

Bazgir N, Shafiei E, Hashemi N, Nourmohamadi H. Woman with Pregnancy and Lactation-Associated Osteoporosis (PLO). Case Rep Obstet Gynecol 2020;2020:8836583.

Jia P, Wang R, Yuan J, Chen H, Bao L, Feng F, et al. A case of pregnancy and lactation-associated osteoporosis and a review of the literature. Arch Osteoporos 2020;15:94.

Jun Jie Z, Ai G, Baojun W, Liang Z. Intertrochanteric fracture in pregnancy- and lactation-associated osteoporosis. J Int Med Res 2020;48:300060519858013.

Wang G, Bai X. Barton Fracture of the Distal Radius in Pregnancy and Lactation-Associated Osteoporosis: A Case Report and Literature Review. Int J Gen Med 2020;13:1043-9.

Lampropoulou-Adamidou K, Trovas G, Triantafyllopoulos IK, Yavropoulou MP, Anastasilakis AD, Anagnostis P, et al. Teriparatide Treatment in Patients with Pregnancy- and Lactation-Associated Osteoporosis. Calcif Tissue Int 2021;109:554-62.

Lee S, Hong N, Kim KJ, Park CH, Lee J, Rhee Y. Bone Density After Teriparatide Discontinuation With or Without Antiresorptive Therapy in Pregnancy- and Lactation-Associated Osteoporosis. Calcif Tissue Int 2021;109:544-53.

Stumpf U, Kraus M, Hadji P. Influence of denosumab on bone mineral density in a severe case of pregnancy-associated osteoporosis. Osteoporos Int 2021;32:2383-7.

Hadji P, Mouzakiti N, Kyvernitakis I. Effect of Teriparatide on Subsequent Fracture and Bone Mineral Density in 47 Women with Pregnancy- and Lactation-associated Osteoporosis and Vertebral Fractures. Geburtshilfe Frauenheilkd 2022;82:619-26.

Iio K, Kondo E, Shibata E, Wada T, Uchimura T, Kinjo Y, et al. Long-Term Tocolysis With Magnesium Sulfate as a Risk Factor for Low Bone Mass: A Case Series. J Med Cases 2022;13:47-50.

Jadhav A, Jadhav S, Varma A. Pregnancy- and Lactation-Associated Osteoporotic Vertebral Fracture: A Case Report. Cureus 2022;14:e31322.

Kaneuchi Y, Iwabuchi M, Hakozaki M, Yamada H, Konno SI. Pregnancy and Lactation-Associated Osteoporosis Successfully Treated with Romosozumab: A Case Report. Medicina (Kaunas) 2022;59:19.

Drake MT, Clarke BL, Khosla S. Bisphosphonates: mechanism of action and role in clinical practice. Mayo Clin Proc 2008;83:1032-45.

Davey MR, De Villiers JT, Lipschitz S, Pettifor JM. Pregnancy- and lactation-associated osteoporosis. J Endocrinol Metab Diabetes South Africa 2012;17:149-53.

Patlas N, Golomb G, Yaffe P, Pinto T, Breuer E, Ornoy A. Transplacental effects of bisphosphonates on fetal skeletal ossification and mineralization in rats. Teratology 1999;60:68-73.

Stathopoulos IP, Liakou CG, Katsalira A, Trovas G, Lyritis GG, Papaioannou NA, et al. The use of bisphosphonates in women prior to or during pregnancy and lactation. Hormones (Athens) 2011;10:280-91.

Khosla S, Bilezikian JP, Dempster DW, Lewiecki EM, Miller PD, Neer RM, et al. Benefits and risks of bisphosphonate therapy for osteoporosis. J Clin Endocrinol Metab 2012;97:2272-82.

Hanley DA, Adachi JD, Bell A, Brown V. Denosumab: mechanism of action and clinical outcomes. Int J Clin Pract 2012;66:1139-46.

Boyce RW, Varela A, Chouinard L, Bussiere JL, Chellman GJ, Ominsky MS, et al. Infant cynomolgus monkeys exposed to denosumab in utero exhibit an osteoclast-poor osteopetrotic-like skeletal phenotype at birth and in the early postnatal period. Bone 2014;64:314-25.

Choe EY, Song JE, Park KH, Seok H, Lee EJ, Lim SK, et al. Effect of teriparatide on pregnancy and lactation-associated osteoporosis with multiple vertebral fractures. J Bone Miner Metab 2012;30:596-601.

Coskun Benlidayi I, Sarpel T, Guzel R. Short-term treatment experience with teriparatide in pregnancy- and lactation-associated osteoporosis. J Obstet Gynaecol 2014;34:736.

Polat SB, Evranos B, Aydin C, Cuhaci N, Ersoy R, Cakir B. Effective treatment of severe pregnancy and lactation-related osteoporosis with teriparatide: case report and review of the literature. Gynecol Endocrinol 2015;31:522-5.

Chang B, Quan Q, Li Y, Qiu H, Peng J, Gu Y. Treatment of Osteoporosis, with a Focus on 2 Monoclonal Antibodies. Med Sci Monit 2018;24:8758-66.

100

Miller PD, Hattersley G, Riis BJ, Williams GC, Lau E, Russo LA, et al. Effect of Abaloparatide vs Placebo on New Vertebral Fractures in Postmenopausal Women With Osteoporosis: A Randomized Clinical Trial. JAMA 2016;316:722-33

101

Li X, Zhang Y, Kang H, Liu W, Liu P, Zhang J, et al. Sclerostin binds to LRP5/6 and antagonizes canonical Wnt signaling. J Biol Chem 2005;280:19883-7.

102

Kobayakawa T, Suzuki T, Nakano M, Saito M, Miyazaki A, Takahashi J, et al. Real-world effects and adverse events of romosozumab in Japanese osteoporotic patients: A prospective cohort study. Bone Rep 2021;14:101068.

103

Cosman F, de Beur SJ, LeBoff MS, Lewiecki EM, Tanner B, Randall S, et al. Clinician’s Guide to Prevention and Treatment of Osteoporosis. Osteoporos Int 2014;25:2359-81.

104

McClung MR, Grauer A, Boonen S, Bolognese MA, Brown JP, Diez-Perez A, et al. Romosozumab in postmenopausal women with low bone mineral density. N Engl J Med 2014;370:412-20.

105

Bayram S, Ozturk C, Sivrioglu K, Aydinli U, Kucukoglu S. Kyphoplasty for pregnancy-associated osteoporotic vertebral fractures. Joint Bone Spine 2006;73:564-6.

106

Kim HW, Song JW, Kwon A, Kim IH. Percutaneous vertebroplasty for pregnancy-associated osteoporotic vertebral compression fractures. J Korean Neurosurg Soc 2010;47:399-402.

Osteoporosis in Pregnant and Lactating Females: An Update

ABSTRACT

Introduction

References