1. Pharmacologic Options for Osteoporosis Prevention and Treatment
Alireza Khabbazi, MD

2. BONE PHYSIOLOGY Most common bone disease in humans Characterized by:
Low bone mass
Microarchitectural deterioration
Compromised bone strength
Increased risk for fracture

3. BONE PHYSIOLOGY Bone Resorption Bone Formation
Osteoclast
Bone Formation
Osteoblast
Bone Multicellular Unit (BMU)
Positive < age 30
Negative > age 30

4. Remodeling (Resorption)
Bone Multicellular Unit (BMU)
Lining cells

5. Remodeling (Resorption)
Bone Multicellular Unit (BMU)
Lining cells

6. Remodeling (Resorption)
Lymphocyte
Bone Multicellular Unit (BMU)
RANKL
CSF
RANK 
Macrophage

7. Remodeling (Resorption)
Lymphocyte
PTH Vit D
Bone Multicellular Unit (BMU)
RANKL
CSF
RANK 
IL1, TNFα, IL6, IL11
Macrophage
RANKL
Osteoblast

8. Remodeling (Resorption)
Lymphocyte
PTH Vit D
Bone Multicellular Unit (BMU)
RANKL
CSF
RANK 
IL1, TNFα, IL6, IL11
Macrophage
RANKL
Preosteoclast
Osteoblast

9. Remodeling (Resorption)
Lymphocyte
PTH Vit D
Bone Multicellular Unit (BMU)
RANKL
CSF
RANK 
IL1, TNFα, IL6, IL11
Macrophage
RANKL
Preosteoclast
RANKL
RANK 
IL1,TNFα,IL6
Osteoclast
Osteoblast

10. Remodeling (Resorption)
Lymphocyte
PTH Vit D
Bone Multicellular Unit (BMU)
RANKL
CSF
RANK 
IL1, TNFα, IL6, IL11
Macrophage
RANKL
Preosteoclast
RANKL
RANK 
IL1,TNFα,IL6
Osteoclast
Osteoblast
Cathepsin K

11. Remodeling (Formation)
Lymphocyte
IL1
Estrogen
OPG
Osteoclast inhibition
RANKL
RANK 
IL1,TNFα,IL6
Osteoblast

12. Remodeling (Formation)
Lymphocyte -
IL1
Estrogen
OPG
Osteoclast inhibition
RANKL
RANK 
IL1,TNFα,IL6
Osteoblast

13. Remodeling (Formation)
Lymphocyte -
PTH Vit D
IL1
Estrogen
Mechanical stimuli
Estrogen
OPG
Androgen
IGF
Osteoclast inhibition
RANKL
RANK 
IL1,TNFα,IL6
Osteoblast stimulation
Osteoblast

14. Remodeling (Formation)
Osteoblast proliferation

15. Remodeling (Formation)
Lining cells
Osteocyte
Osteoid

16. Etiology and pathogenesis of Osteoporosis

17. Pathogenesis
Hyperparathyroidism Estrogen deficiency Inflammation Low Vitamin D, Ca Low physical activity Androgen deficiency Drugs toxins
PTH Vit D
Estrogen
PTH Vit D
Lymphocyte
Progestrone
Estrogen
IL1 TNFα IL6 IL11
OPG
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast
Osteoblast
Osteoblast
Cathepsin K

18. Pathogenesis
Hyperparathyroidism Estrogen deficiency Inflammation Low Vitamin D, Ca Low physical activity Androgen deficiency Drugs toxins
PTH Vit D
Estrogen
PTH Vit D
Lymphocyte
Progestrone
Estrogen
IL1 TNFα IL6 IL11
OPG
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast
Osteoblast
Osteoblast
Cathepsin K

19. Pathogenesis
Hyperparathyroidism Estrogen deficiency Inflammation Low Vitamin D, Ca Low physical activity Androgen deficiency Drugs toxins
PTH Vit D
Estrogen
PTH Vit D
Lymphocyte
Progestrone
Estrogen
IL1 TNFα IL6 IL11
OPG
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast
Osteoblast
Osteoblast
Cathepsin K

20. Pathogenesis
Hyperparathyroidism Estrogen deficiency Inflammation Low Vitamin D, Ca Low physical activity Androgen deficiency Drugs toxins
PTH Vit D
Estrogen
PTH Vit D
Lymphocyte
Progestrone
Estrogen
IL1 TNFα IL6 IL11
OPG
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast
Osteoblast
Osteoblast
Cathepsin K

21. Pathogenesis
Hyperparathyroidism Estrogen deficiency Inflammation Low Vitamin D, Ca Low physical activity Androgen deficiency Drugs toxins
PTH Vit D
Estrogen
PTH Vit D
Lymphocyte
Progestrone
Estrogen
IL1 TNFα IL6 IL11
OPG
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast
Osteoblast
Osteoblast
Cathepsin K

22. Pathogenesis
Hyperparathyroidism Estrogen deficiency Inflammation Low Vitamin D, Ca Low physical activity Androgen deficiency Drugs toxins
PTH Vit D
Estrogen
PTH Vit D
Lymphocyte
Progestrone
Estrogen
IL1 TNFα IL6 IL11
OPG
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast
Osteoblast
Osteoblast
Cathepsin K

23. Pathogenesis
Hyperparathyroidism Estrogen deficiency Inflammation Low Vitamin D, Ca Low physical activity Androgen deficiency Drugs toxins
PTH Vit D
Estrogen
PTH Vit D
Lymphocyte
Progestrone
Estrogen
IL1 TNFα IL6 IL11
OPG
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast
Osteoblast
Osteoblast
Cathepsin K

24. Pathogenesis
Hyperparathyroidism Estrogen deficiency Inflammation Low Vitamin D, Ca Low physical activity Androgen deficiency Drugs toxins
PTH Vit D
Estrogen
PTH Vit D
Lymphocyte
Progestrone
Estrogen
IL1 TNFα IL6 IL11
OPG
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast
Osteoblast
Osteoblast
Cathepsin K

25. Drugs used for osteoporosis treatment

26. Treatment _ + + _ _ + _ + _ Odanacatib Denosumab Strontium
Teriparatide
SERMs _
PTH
Biphosphonates
Estrogen
Calcitonine +
PTH Vit D
Ca, Vit D
Lymphocyte +
Exercise
Estrogen
IL1 TNFα IL6 IL11
OPG
Progestrone _ _ + _
Androgen
IGF
RANKL
RANK
IL1,TNFα,IL6
Osteoclast +
Osteoblast _
Osteoblast
Cathepsin K

27. Drugs used for osteoporosis
Antiresorptive drugs
- Bisphosphonates
- Calcitonin
- Estrogen
- SERM’s
- Denosumab
Bone formation stimulators
- PTH (Teriparatide)
Dual action
- Strontium

28. Vitamin D and calcium

29. Vitamin D and calcium
Daily 800 IU of vitamin D is associated with a reduction in hip fractures of 30% and in nonvertebral fractures of 14%
Fall reduction in the elderly
Therapeutic dose of vitamin D: unit

30. Vitamin D and calcium Calcium: 1000-1300mg
Avoid taking more than 500 mg of calcium in one dose.
Take one dose before bedtime to prevent bone loss at night. If more is needed, take several doses throughout the day.
Calcium supplements should be taken with meals to boost their absorption.

31. Vitamin D and calcium
Certain substances can hinder absorption of calcium: foods rich in fibres and fat, zinc, iron, spinach, coffee, alcohol and antacids. Therefore, calcium should not be taken together with these.
Calcium may interfere with certain drugs, including: thyroid medications, tetracycline, anticonvulsants and corticosteroids. Therefore, these should always be taken separately.

32. Vitamin D and calcium
There is no need to worry about development of kidney stones if the correct dosage in the suitable form of calcium is taken together with sufficient fluid.
Calcium supplements can cause gas, abdominal distension and constipation in some individuals. In this situation, it is reasonable to switch to a different preparation.

33. Bisphosphonates

34. Bisphosphonates
The most commonly prescribed therapy for OP prevention and management
Mechanism: inhibits bone resorption by attaching to bony surfaces undergoing active resorption and inhibiting action of osteoclasts - - -
Farensyl pyrophosphate synthase
GTPase
Attachment of osteoclast

35. Bisphosphonates-place in treatment
Prevention and treatment of postmenopausal osteoporosis
Osteoporosis in men
Prevention and treatment of GIOP

36. Bisphosphonates
Alendronate use for 10 years cause a continuous increase in vertebral (13.7%) and hip trochanter (10.3%) bone mineral density (BMD)
Decrease incidence of vertebral, hip, and all non-vertebral fractures by 50%
90% reduction of multiple radiographic vertebral fractures at year 3

37. Bisphosphonates-Adverse events
Gastrointestinal problems, such as difficulty swallowing, gastric ulcers, and inflammation of the esophagus.
Hypocalcemia (18%)
Hypophosphatemia (10%)
Musculoskeletal pain, cramps

38. Bisphosphonates-Adverse events
Atrial fibrillation (3-50/100000): zoledronic acid
Osteonecrosis of the jaw (1/100000): IV bisphosphonates
Atypical femur fracture

39. Bisphosphonates-Contraindications
Abnormalities of the esophagus which delay esophageal emptying, such as stricture or achalasia
Inability to stand or sit upright for at least 30 minutes
Patients at increased risk of aspiration
Hypocalcemia
Pregnancy
Renal insufficiency (Not recommended if CrCl < ml/min)

40. Bisphosphonates-Dosing
Alendronate: 10 mg/day or 70 mg once weekly at least 30 minutes before eating or drinking
Risedronate: 5 mg/day, 35 mg once weekly, or 150 mg once monthly
Ibandronate: 150 mg once monthly at least 60 minutes before eating or drinking
Zoledronate: 5 mg administered intravenously (IV) once yearly

41. Bisphosphonates-Duration of therapy
The optimal duration: 5 years
Repair (up to 12 months)
Rebuilding (6–36 months)
Maintenance (24–60 months)
After 7 years of therapy the bone mass still increased by about 1% a year. However, a drug holiday after 5 years of alendronate therapy is advisable to avoid any possible microdamage accumulation, at least in low-risk patients.

42. Other medications

43. Raloxifene
Mechanism: tissue-selective activity, acts as an estrogen agonist on bone
- Estrogen antagonist on breast, uterus
Approved only for the prevention and treatment of postmenopausal osteoporosis.

44. Raloxifene Reduce the incidence of vertebral fractures by 30-50%
Reduction of the risk of invasive breast cancer in postmenopausal women with osteoporosis
Reduction in the risk of invasive breast cancer in postmenopausal women at high risk of invasive breast cancer.

45. Raloxifene: Adverse events
Frequency > 10%
Hot flashes
Arthralgia
Sinusitis
Frequency 1-10%
Chest pain
Insomnia
Migraines
Peripheral edema
Diaphoresis
An increased risk of DVT: risk is similar to reported risk of HRT

46. Raloxifene: Containdications
History of DVT/PTE or at high risk
Cardiovascular disease
History of uterine/cervical carcinoma
Discontinue at least 72 hours prior to and during prolonged immobilization

47. Raloxifene-Dosing For prevention and treatment
60 mg PO once daily
Can be taken any time of day without regard to meals

48. Calcitonin Approved for treatment of postmenopausal osteoporosis
Mechanism:
Peptide composed of 32 amino acids which binds to osteoclasts and inhibits bone resorption

49. Calcitonin-Dosing Nasal 200 international units daily
Contraindications
Clinical allergy to calcitonin-salmon
Precautions
Nasal ulcerations
Tachyphylaxis (parenteral dosage forms)
Drug interactions (DI)
No formal studies designed to evaluate DI

50. Teriparatide Prevention and treatment of postmenopausal osteoporosis
Treatment of osteoporosis in men
Treatment of GIOP

51. Teriparatide
The BMD of the lumbar spine increased by 12.2% in the women receiving teriparatide and by 5.6% in the women receiving alendronate (at 14 months)
Teriparatide was found to reduce vertebral fractures by 65% and nonvertebral fractures by 53%
Body et al. 2002

52. Teriparatide-Place in Therapy
Women or men with severe osteoporosis and at least one fragility fracture
Patients who are refractory to or unable to tolerate bisphosphonate
In patients considered to be
bisphosphonate failures PTH may be
started approximately 3 months after
bisphosphonates are discontinued

53. Teriparatide-Adverse events
Hypercalcemia (11%)
Dizziness (9%)
Leg cramps (3%)
Hyperuricemia
Increased risk of osteosarcoma (rats)

54. Teriparatide-Dosing
20 µg daily as a daily subcutaneous injection for a maximum 2 years
Anti resorptive therapy may be considered after discontinuation of PTH to maintain gains in BMD acquired with PTH alone in those at high risk for subsequent fracture

55. Teriparatide-contraindicated
Patients with an increased risk of osteosarcoma
Paget’s disease of bone
Prior radiation therapy to skeleton
unexplained elevations of ALP
Bone metastases
Hypercalcemia
History of skeletal malignancy
Pregnancy/nursing

56. Denosumab
Reduces bone resorption by preventing RANK ligand, which is produced by the osteoblast, from attaching to its receptor on the osteoclast
The BMD increase 3-6.7% in the spine and % at the hips (1 years)
The BMD increase up to 18.5% in the spine and 8.2% at the hips (6 years)
Mc Clung et al. 2006
Papapoulos et al. 2013

57. Denosumab
A 3-year study of postmenopausal women with osteoporosis with the use of denosumab versus placebo - 68% relative decrease in the risk of new radiographic vertebral fracture - 40% relative decrease in the risk of hip fracture - 20% relative decrease in the risk of nonvertebral fracture

58. Denosumab Approval for the treatment of OP in
- Postmenopausal women with a high
risk of fracture, such as those with a
history of fracture, women with
multiple risk factors for fracture
- Patients who failed or are intolerant of
other available therapies

59. Denosumab
The recommended dosing of denosumab is 60 mg subcutaneously every 6 months.
Unlike the bisphosphonates, denosumab may be used in those with renal impairment provided that monitoring of calcium, phosphorus, and magnesium is carried out

60. Denosumab-adverse events
Back pain (34.7%)
Musculoskeletal pain (7.6%)
High cholesterol (7.2%)
Cystitis (5.9%)

61. Strontium
Consisting of two atoms of stable strontium and an organic moiety (ranelic acid)
Strontium (2 gm/d) for three years:
- Increased in BMD at the LS as 8%
- Decrease in risk of new vertebral
fractures, hip fracture and non-
vertebral fracture by 40%, 40% and
15% respectively

62. Strontium
Diarrhea
Drug rash with eosinophilia systemic symptoms and Stevens-Johnson syndrome (very rarely)
Thromboembolic events
Cardiovascular risk
Strontium should be used with caution in patients who have had a thrombosis, and the treatment must be stopped in prolonged decubitus situations and in
patients with skin reactions
Strontium should not be be used in patients with IHD, peripheral arterial diseases, CVA, un controlled HTN

63. Odanakatib Selective catepsin K inhibitor Dose: 50 mg/week PO
In a phase III trial the BMD of the lumbar spine increased by 5.5% and the hip increased by 3.2%
Engelke et al. J Bone Miner Res. 2014

64. Monoclonal antibody against Sclerostin

65. Who should be treated
All postmenopausal women who have had an osteoporotic vertebral fracture
T-score ≤-2
T-score from -1.5 to -2 plus at least one of the following risk factors for fracture: thinness, history of fragility fracture (other than skull, facial bone, ankle, finger, and toe) since menopause, and history of hip fracture in a parent.

66. Who should be treated-NOF guideline
Postmenopausal women and men age 50 and older who present with
- T ≤-2.5 at the femoral neck or spine
- Hip or vertebral fracture
- T= -1.0 to -2.5 at the femoral neck or
spine and a 10-year probability of a hip
fracture ≥3% or a 10-year probability
of a major osteoporosis-related fracture
≥20%

67. FRAX

68. Selection of drug
Bisphosphonates recommended as first-line therapy for postmenopausal osteoporosis.
Oral bisphosphonates are preferred
For individuals with gastrointestinal intolerance: IV bisphosphonates

69. Selection of drug
Raloxifene was reserved for patients who cannot tolerate any bisphosphonates or for women with osteoporosis and increased risk of invasive breast cancer.

70. Selection of drug
Denosumab could be used as initial therapy in certain patients at high risk for fracture, such as older patients who have difficulty with the dosing requirements of oral bisphosphonates.
Denosumab may have a role in patients who are intolerant of or unresponsive to other therapies and in those with impaired renal function.

71. Selection of drug
Teriparatide should be reserved for treating women at high fracture risk, including those with very low bone mineral density (T-score worse than -3.0) with a previous vertebral fracture.

72. Follow up strategies
Repeat DXA every 2 year using the same machine and technician if possible
The lowest significant change is 3-4% at spine, 4-6% at hip and 2% at elbow
If desired response not achieved
- Re-evaluate the adherence to
treatment regimen
- Reconsider secondary OP
- Consider changing patient medication

73. Combination therapy
Combination of bisphosphonate-raloxifene therapy is not recommended as the additional BMD benefits are small and there is no proven additional fracture benefit.
Combination therapy using PTH with raloxifene may enhance the bone forming effects of PTH.

74. Combination therapy
Combination of PTH with alendronate blunts the effect of PTH and is not recommended
Teriparatide combined with denosumab increased BMD more than either agent alone and more than has been reported with other approved
Tsai JN, Uihlein AV, Lee H, et al. Teriparatide and denosumab, alone or combined, in women with postmenopausal osteoporosis: the DATA randomised
trial. Lancet 2013; 382:50–56.