Vitamin D Deficiency and Related Disorders

Updated: Sep 08, 2022
  • Author: Vin Tangpricha, MD, PhD; Chief Editor: Romesh Khardori, MD, PhD, FACP  more...
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Overview

Practice Essentials

Vitamin D deficiency can result from inadequate exposure to sunlight; malabsorption; accelerated catabolism from certain medications; and, in infants, the minimal amount of vitamin D found in breast milk. In children, vitamin D deficiency can result in rickets, which presents as bowing of the legs; in adults, it results in osteomalacia, which presents as a poorly mineralized skeletal matrix. See the image below.

Findings in patients with rickets. Findings in patients with rickets.

Signs and symptoms

Vitamin D deficiency is often clinically silent. Manifestations are as follows:

  • Children are often found to have started walking late or prefer to sit down for prolonged periods

  • Adults can experience chronic muscle aches and pains

Physical findings in severe vitamin D deficiency are as follows:

  • In children, bowing in the legs

  • In adults, periosteal bone pain, best detected with firm pressure on the sternum or tibia

See Clinical Presentation for more detail.

Diagnosis

Measurement of serum 25-hydroxyvitamin D (25[OH]D) is the best test to determine vitamin D status. Levels of 25(OH)D are interpreted as follows [1] :

  • 21-29 ng/mL (52.5-72.5 nmol/L): Vitamin D insufficiency

  • < 20 ng/mL (< 50 nmol/L): Vitamin D deficiency

Although not always required for the diagnosis of vitamin D insufficiency, measurement of the serum parathyroid hormone (PTH) level may help establish the diagnosis of vitamin D insufficiency. PTH levels are often elevated in patients with vitamin D insufficiency, indicating secondary hyperparathyroidism.

Screening for vitamin D deficiency is recommended only in those individuals who are at high risk for vitamin D deficiency, including the following [2] :

  • Patients with osteoporosis

  • Patients with a malabsorption syndrome

  • Black and Hispanic individuals

  • Obese persons (body mass index >30 kg/m2) [3]

  • Patients with disorders that affect the metabolism of vitamin D and phosphate (eg, chronic kidney disease)

See Workup for more detail.

Management

Recommended treatment for vitamin D–deficient patients up to 1 year of age is as follows [2] :

  • 2000 IU/day of vitamin D2 or D3 for 6 weeks or

  • 50,000 IU of vitamin D2 or D3 once weekly for 6 weeks

  • When the serum 25(OH)D level exceeds 30 ng/mL, provide maintenance treatment of 400-1000 IU/day

Recommended treatment for vitamin D–deficient patients 1–18 years of age is as follows [2] :

  • 2000 IU/day of vitamin D2 or D3 for at least 6 weeks or

  • 50,000 IU of vitamin D2 once weekly for at least 6 weeks

  • When the serum 25(OH)D level exceeds 30 ng/mL, provide maintenance treatment of 600-1000 IU/day

Recommended treatment for vitamin D–deficient adults is as follows [2] :

  • 50,000 IU of vitamin D2 or D3 once weekly for 8 weeks or

  • 6000 IU/day of vitamin D2 or D3 for 8 weeks

  • When the serum 25(OH)D level exceeds 30 ng/mL, provide maintenance treatment of 1500-2000 IU/day

Recommended treatment for vitamin D–deficient patients who are obese, have a malabsorption syndrome, or are taking medication that affects vitamin D metabolism, is as follows [2] :

  • At least 6000-10,000 IU of vitamin D daily

  • When the serum 25(OH)D level exceeds 30 ng/mL, provide maintenance treatment of 3000-6000 IU/day

If the 25(OH)D concentration remains persistently low despite several attempts at correction with oral vitamin D, a trial of ultraviolet B light therapy (ie, by tanning lamps) may be considered to improve vitamin D status.

Prevention

Unprotected sun exposure is the major source of vitamin D for both children and adults. [2] Provision of vitamin D from sunlight is as follows:

  • Sensible sun exposure, especially between the hours of 10 am and 3 pm, produces vitamin D in the skin that may last twice as long in the blood compared with ingested vitamin D [4]

  • Full-body sun exposure producing slight pinkness in light-skinned persons results in vitamin D production equivalent to ingesting 10,000-25,000 IU [5]

  • Increased skin pigmentation, aging, and sunscreen use reduce the skin’s vitamin D3 production

Recommended dietary intake of vitamin D for patients at risk of vitamin D deficiency is as follows [2] :

  • In infants and children up to 1 year old, at least 400 IU/day, to maximize bone health

  • In children and adolescents 1-18 years of age, at least 600 IU/day to maximize bone health

  • In adults 19-50 years of age, at least 600 IU/day to maximize bone health and muscle function

  • Raising the serum 25(OH)D level consistently above 30 ng/mL may require vitamin D intake of at least 1000 IU/day

  • Whether recommended levels of vitamin D intake will provide all the potential nonskeletal health benefits associated with vitamin D is currently unknown

Most dietary sources of vitamin D do not contain sufficient amounts of the vitamin to satisfy daily requirements. The following foods contain the indicated amounts of vitamin D, as reported by the US Department of Agriculture's (USDA's) Nutrient Data Laboratory:

  • Fortified milk (8 oz) - 100 IU

  • Fortified orange juice (8 oz) [6] - 100 IU

  • Fortified cereal (1 serving) - 40-80 IU

  • Pickled herring (100 g) - 680 IU

  • Canned salmon with bones (100 g) - 624 IU

  • Mackerel (100 g) - 360 IU

  • Canned sardines (100 g) - 272 IU

  • Codfish (100 g) - 44 IU

  • Swiss cheese (100 g) - 44 IU

  • Raw shiitake mushrooms (100 g) - 76 IU

  • Most multivitamins (1 tab) - 400 IU

See Treatment and Medication for more detail.

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Background

Vitamin D deficiency in children can manifest as rickets (it is the most common cause of nutritional rickets), which presents as bowing of the legs. Vitamin D deficiency in adults results in osteomalacia, which presents as a poorly mineralized skeletal matrix. These adults can experience chronic muscle aches and pains (see the images below). [7] (See Presentation and Prognosis.)

Findings in patients with rickets. Findings in patients with rickets.
Radiograph in a 4-year-old girl with rickets depic Radiograph in a 4-year-old girl with rickets depicts bowing of the legs caused by loading.
Anteroposterior and lateral radiographs of the wri Anteroposterior and lateral radiographs of the wrist of an 8-year-old boy with rickets demonstrates cupping and fraying of the metaphyseal region.

Vitamin D is important for calcium homeostasis and for optimal skeletal health. The major function of vitamin D is to increase the efficiency of calcium absorption from the small intestine. Heaney and colleagues demonstrated that maximum calcium absorption occurs at levels of 25-hydroxyvitamin D (25[OH]D) greater than 32 ng/mL. [8] (See Pathophysiology and Etiology.)

Vitamin D also enhances the absorption of phosphorus from the distal small bowel. Adequate calcium and phosphorus absorption from the intestine is important for proper mineralization of the bone. The second major function of vitamin D is involvement in the maturation of osteoclasts, which resorb calcium from the bones. (See Pathophysiology and Etiology.)

The term vitamin D refers to either vitamin D2 or vitamin D3. Vitamin D3, also known as cholecalciferol, is either made in the skin or obtained in the diet from fatty fish. Vitamin D2, also known as ergocalciferol, is obtained from irradiated fungi, such as yeast. Vitamin D2 and vitamin D3 are used to supplement food products or are contained in multivitamins. (See Treatment and Medication.)

Past studies suggested that vitamin D3 may be more effective than vitamin D2 in establishing normal vitamin D stores. [9, 10] However, a study by Holick and colleagues demonstrated that vitamin D2 and vitamin D3 appear to be equipotent in raising 25(OH)D concentrations when they are given in daily doses of 1000 IU. [11]

Vitamin D deficiency during pregnancy affects offspring. In a community-based study of 901 mother and offspring pairs, researchers found that maternal vitamin D deficiency (serum 25-hydroxyvitamin D < 50 nmol/L) at 18 weeks' pregnancy was associated with impaired lung development at age 6 in offspring, neurocognitive difficulties at age 10, increased risk of eating disorders in adolescence, and lower peak bone mass at age 20. [12, 13, 14]

Findings suggest that vitamin D plays an active role in fetal development, particularly the development of the brain, lungs, and bones.

Physiology

The production of vitamin D3 in the skin involves a series of reactions initiating with 7-dehydrocholesterol. Upon exposure to ultraviolet B (UVB) radiation between the wavelengths of 290-315 nm, 7-dehydrocholesterol is converted to previtamin D3, which is then converted to vitamin D3 after a thermally induced isomerization reaction in the skin. From the skin, newly formed vitamin D3 enters the circulation by binding to vitamin D binding protein (DBP). In order to become active, vitamin D requires 2 sequential hydroxylations to form 1,25-dihydroxyvitamin D (1,25[OH]2 D).

Vitamin D is initially hydroxylated in the 25 position by the hepatic microsomal and/or mitochondrial enzyme vitamin D 25-hydroxylase. The second hydroxylation occurs in the kidney and is performed by the P450 enzyme 25-hydroxyvitamin D-1 alpha-hydroxylase.

Upon entering the cell, the 1,25(OH)2 D hormone binds to the vitamin D receptor (VDR). The bound vitamin D receptor then forms a heterodimer with the retinoic acid X receptor (RXR). This heterodimer then goes to the nucleus to bind deoxyribonucleic acid (DNA) and increases transcription of vitamin D–related genes.

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Pathophysiology

Inadequate circulating 25(OH)D is associated with elevated parathyroid hormone (PTH); this condition is called secondary hyperparathyroidism. The rise in PTH may result in increased mobilization of calcium from the bone, which leads to decreased mineralization of the bone.

Of note, prolonged exposure to the sun does not cause vitamin D toxicity. This is because after prolonged UVB radiation exposure, the vitamin D made in the skin is further degraded to the inactive vitamin D metabolites tachysterol and lumisterol.

As strongly suggested by genetic, molecular, cellular, and animal studies, extraskeletal effects related to vitamin D signaling include roles in cell proliferation, immune and muscle function, skin differentiation, and reproduction, with vitamin D having vascular and metabolic actions as well. Observational studies have pointed to a relationship between poor vitamin D status and almost all diseases connected to these extraskeletal influences. However, while randomized, controlled trials and Mendelian randomization studies have indicated that vitamin D supplementation can lower the incidence of some disorders, only mixed conclusions on the matter have been reached globally. [15]

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Etiology

Vitamin D deficiency can result from the following:

  • Inadequate exposure to sunlight - This causes a deficiency in cutaneously synthesized vitamin D; adults in nursing homes or health care institutions are at a particularly high risk. [16]

  • Vitamin D malabsorption problems - People who have undergone resection of the small intestine are at risk for this condition; diseases associated with vitamin D malabsorption include celiac sprue, short bowel syndrome, [17] and cystic fibrosis. [18]

  • Minimal amounts of vitamin D in human breast milk - The American Academy of Pediatrics recommends vitamin D supplementation starting at age 2 months for infants fed exclusively with breast milk. [19]

  • Medications - Some medications are associated with vitamin D deficiency; drugs such as Dilantin, phenobarbital, and rifampin can induce hepatic p450 enzymes to accelerate the catabolism of vitamin D.

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Epidemiology

Occurrence in the United States

Vitamin D insufficiency is highest among people who are elderly, institutionalized, or hospitalized. In the United States, 60% of nursing home residents [20] and 57% of hospitalized patients [21] were found to be vitamin D deficient.

However, vitamin D insufficiency is not restricted to the elderly and hospitalized population; several studies have found a high prevalence of vitamin D deficiency among healthy, young adults. A study determined that nearly two thirds of healthy, young adults in Boston were vitamin D insufficient at the end of winter. [22]

An analysis of data on 2877 US children and adolescents (age, 6-18 y) from the National Health and Nutrition Examination Survey (NHANES) 2003-2006 indicated that, based on current Institute of Medicine Committee guidelines, about 10.3% of this population (an estimated 5.5 million) had inadequate vitamin D (25(OH)D) levels (< 16 ng/mL), and 4.6% (an estimated 2.5 million) had levels placing them at risk of frank deficiency (< 12 ng/mL). [23, 24] Adolescents (age, 14-18 y) and obese children had the highest risk of 25(OH)D deficiency and inadequacy, and these risks were also higher among girls than boys (of any age and body mass index) and among nonwhite children. [24]

Vitamin D status may fluctuate throughout the year, with the highest serum 25(OH)D level occurring after the summer and the lowest serum 25(OH)D concentrations after winter. A study by Shoben at el demonstrated that mean serum 25(OH)D concentrations can vary as much as 9.5 ng/mL. Factors such as male sex, higher latitude, and greater physical activity levels were found to be associated with greater differences in serum 25(OH)D concentrations in winter and summer. [25]

International occurrence

Similar rates of vitamin D deficiency have been reported in Europe [26] and Canada. A greater prevalence of vitamin D deficiency exists in Middle Eastern countries. A study of 316 young adults aged 30-50 years from the Middle East showed that 72.8% had 25(OH)D values of less than 15 ng/dL (that is, severely deficient). This was significantly more common in women than in men (83.9% vs 48.5%, respectively). The difference between sexes probably reflects the cultural and religious practices leading to less skin exposure in women than in men. [27, 28, 29, 30]

Race-related demographics

Darker skin interferes with the cutaneous synthesis of vitamin D. A study by Holick and coauthors demonstrated that non-Hispanic black subjects require 6 times the amount of UV radiation necessary to produce a serum vitamin D concentration similar to that found in non-Hispanic white subjects. [31] The explanation for the increased radiation necessary to increase vitamin D levels is that melanin absorbs ultraviolet radiation.

The decreased efficacy of vitamin D production by darker-pigmented skin explains the higher prevalence of vitamin D insufficiency among darker-skinned adults. Dawson-Hughes and colleagues demonstrated that in Boston, 73% of elderly black subjects were vitamin D insufficient, compared with 35% of elderly non-Hispanic whites. [32]

In a large survey of 1500 healthy black women younger than 50 years, 40% were vitamin D deficient (25[OH]D < 16ng/mL), compared with 4% of 1400 white women in that study. [33]

Age-related demographics

Vitamin D production in the skin declines with advancing age, making elderly populations more dependent on dietary vitamin D. For the average older person, higher dietary intake of vitamin D may be required to achieve optimal serum levels of 25(OH)D. [34]

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Prognosis

The treatment of vitamin D insufficiency can decrease the risk of hip and nonvertebral fractures. [35, 36] A meta-analysis by Boonen et al of postmenopausal women and of men aged 50 years or older reporting a risk of hip fracture found that oral vitamin D supplementation reduced the risk of hip fractures by 18% when vitamin D and calcium were taken together. [37] Most of the trials that demonstrated the antifracture efficacy of vitamin D used approximately 800 IU of vitamin D3. The minimum 25(OH)D level at which antifracture efficacy was observed was 30 ng/ml (74 nmol/L), suggesting a threshold for optimal levels of 25(OH)D for fracture protection.

Results from another meta-analysis, evaluating the efficacy of oral vitamin D supplementation in the prevention of hip and other nonvertebral bone fractures in individuals aged 65 years or older, indicated that vitamin D offers dose-dependent fracture protection. [38] The analysis, by Bischoff-Ferrari et al, took into account 12 double-blind, randomized, controlled trials (RCTs) for nonvertebral fractures (n = 42,279) and 8 RCTs for hip fractures (n = 40,886), comparing the results obtained from the use of oral vitamin D (with or without calcium) with those derived from the administration of calcium alone and from placebo use.

In this study, doses of more than 400 IU/day were found to reduce fractures by at least 20% in individuals aged 65 years or older. [38] In contrast to the Boonen study, the investigators maintained that these effects were independent of calcium supplementation.

Vitamin D insufficiency contributes to osteoporosis by decreasing intestinal calcium absorption. [8, 39] Treatment of vitamin D deficiency has been shown to improve bone mineral density. [40, 41] An analysis of the Third National Health and Nutrition Examination Survey (NHANES III) demonstrated a positive correlation between circulating 25(OH)D levels and bone mineral density. [42]

Vitamin D supplementation has been associated with a reduction in falls and improved muscle strength in the elderly. A meta-analysis demonstrated that vitamin D supplementation resulted in a reduction in falls of about 22% in ambulatory and institutionalized elderly subjects, as compared with controls. [43, 44] Another meta-analysis examining muscle strength associated with vitamin D supplementation found significant improvement in reduced postural sway, timed up-and-go test results, and lower extremity strength in a pooled analysis of 13 studies. [45]

Epidemiologic data suggest that vitamin D deficiency places adults at risk for developing cancer [46, 47, 48, 49, 50] ; these apparently include breast, colon, and prostate cancer. [51, 52] Several studies using cultured cancer cells in mice models have also supported the notion that vitamin D prevents the growth of cancers. [53] Larger, randomized clinical trials are underway in humans to establish the role of vitamin D in the prevention of cancers.

Vitamin D insufficiency may increase the risk for type I and type II diabetes mellitus. [34, 54] In NHANES III, lower vitamin D status was associated with higher fasting glucose and 2-hour glucose after an oral glucose tolerance test. [55] Furthermore, vitamin D supplementation in adults has been associated with improved insulin sensitivity in several small, case-control studies. [54]

Joergensen et al determined that vitamin D deficiency in type 1 diabetes may predict all causes of mortality but not development of microvascular complications. [56] The contribution of vitamin D deficiency to mortality must be mediated by nonvascular mechanisms.

A study by Li et al indicated that vitamin D deficiency (serum 25-hydroxyvitamin D < 12 ng/mL) is related to an increased stroke risk in adults, with an association also found between higher vitamin D levels and a reduced stroke risk. The study, on adults aged 20 years or older, found that evidence for the relationship between high serum 25-hydroxyvitamin D levels and decreased stroke risk was particularly strong among females below age 50 years. [57]

Low levels of vitamin D have also been linked to increased cardiovascular disease (CVD) biomarkers in older adults. In an observational study of 957 hypertensive older adults, vitamin D deficiency (< 25 nmol/L) was associated with higher levels of biomarkers linked with CVD and conditions such as multiple sclerosis and rheumatoid arthritis. [58, 59, 60] Individuals deficient in vitamin D had significantly higher levels of the inflammatory biomarkers interleukin-6 (IL-6) and C-reactive protein (CRP), and higher IL-6:IL-10 and CRP:IL-10 ratios compared with subjects who had serum vitamin D levels > 75 nmol/L. [58, 59]

A meta-analysis evaluated the effect of vitamin D supplementation (using a mean supplementation dosage of about 500 IU daily) on all-cause mortality in 18 randomized controlled trials and found a 7% relative risk reduction for death. [61] Severe vitamin D deficiency (25(OH)D < 10 ng/mL) has been associated with increased in-hospital mortality in patients admitted for acute coronary syndrome. [62]

A Cochrane Review of 50 randomized, controlled trials that included more than 94,000 individuals, primarily elderly women, found that vitamin D3 supplementation decreased mortality. Other forms of vitamin D, including vitamin D2, calcitriol, and alpha-calcidiol, did not reduce mortality. [63]

A study by Manson et al to evaluate the efficacy of vitamin D supplementation and omega-3 fatty acids in lowering the risk of invasive cancer and cardiovascular disease found no such reduction associated with the administration of vitamin D. The report, which included 25,871 participants (males aged 50 years or older and females aged 55 years or older) and had a median follow-up period of 5.3 years, determined that compared with a placebo group, there was no decrease in the incidence of breast, prostate, or colorectal cancer, or in myocardial infarction, stroke, or cardiovascular-related death, among subjects who consumed 2000 IU per day in supplementary vitamin D. [64]

COVID-19

Low vitamin D in patients with coronavirus disease 2019 (COVID-19) reflects a heightened inflammatory state and possibly could be used as a surrogate marker for high risk of severe disease. [65]

A retrospective case-control study by Jude et al indicated that vitamin D deficiency can be linked to a greater likelihood of hospitalization in patients with COVID-19. Results from a primary cohort revealed that in hospitalized patients with COVID-19, the median serum level of 25(OH)D was 35.0 nmol/L, compared with 50.0 nmol/L in nonhospitalized individuals with COVID-19. The investigators suggested that the risk of hospitalization for COVID-19 could be reduced via widespread testing for and treatment of serum 25(OH)D insufficiency or deficiency. [66]

A retrospective observational study by De Smet et al indicated that patients with COVID-19 who have vitamin D deficiency at hospital admission have an almost four-fold greater chance of mortality from COVID-19. This increase occurred independently of age, ethnicity, the presence of chronic lung disease, or the degree of lung damage (as determined through chest computed tomography [CT] scan severity score). [67, 68]

A retrospective, single-institution study by Dror et al of hospitalized patients with COVID-19 found that those who had a 25(OH)D level of less than 20 ng/mL prior to infection with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the virus that causes COVID-19, had a 14-fold greater likelihood of severe or critical COVID-19 than did those who had a 25(OH)D level of 40 ng/mL or greater before infection. Moreover, the mortality rate during hospitalization in patients with pre-infection vitamin D deficiency was 25.6%, compared with 5.0% in those with 40 ng/mL or more of 25(OH)D. [69]

A study by Jolliffe et al indicated that in persons with suboptimal vitamin D status, providing vitamin D supplementation through a test-and-treat approach does not protect against COVID-19. The baseline prevalence of suboptimal vitamin D prevalence was high in the study group, which consisted of individuals aged 16 years or older. Results regarding the incidence and severity of acute COVID-19 or of prolonged COVID-19 symptoms did not differ significantly between individuals who were not offered supplementation and those who were, no matter whether lower- or higher-dose supplementation was provided. (However, the investigators stated that there was a low prevalence of profound vitamin D deficiency at baseline within the group, and that consequently the study could not determine whether persons with this status might benefit from supplementation.) [70]

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