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Template:Scurvy

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief:

Overview

Scurvy is a chronic deficiency disease of vitamin C, which is necessary for normal collagen formation in humans. L-ascorbic acid, the scientific name for vitamin c, is derived from the Latin name, scorbutus. Early symptoms of this disease are fatigue, weakness, and sore arms and legs. Without treatment, changes in hair, skin, and gums occur. [1] As scurvy worsens there can be personality changes, poor wound healing and ultimately leading to death due to bleeding or infection. Previously, this disease was common among pirates, sailors, and all others who were separated from the resources of vitamin c e.g. fruits and vegetables for extended periods. It takes a month with low or no vitamin c to cause symptoms. In infants, scurvy is sometimes referred to as Barlow's disease, named after Sir Thomas Barlow (1845–1945), [2] a British physician who described it. Other eponyms include Moeller's disease and Cheadle's disease. In the modern world, scurvy rarely presents in adults, infants and elderly are affected more. [3] [4] Vitamin C, a water soluble vitamin, can easily be destroyed by pasteurization. So bottle fed babies, not supplemented with adequate vitamin, can easily develop scurvy. For this reason, vitamin C is added to all approved baby formulas. If mothers take adequate amount of vitamin C, then breast milk is sufficient for the babies need of this vitamin.

Pathophysiology

Physiology

Vitamins are very important for the formation and normal functioning of enzymes that are responsible for multiple processes in the human body. Ascorbic acid is necessary for accelerating amidation reactions and hydroxylation in normal collagen synthesis. The hydroxylation of lysine and proline residues occurs in endoplasmic reticulum and leads to hydroxylysine and hydroxyproline, respectively. Enzymes responsible for these reactions are lysyl hydroxylase and prolyl hydroxylase. For healthy skin, bone, muscles, cartilage, blood vessels, and other connective tissues, the primary structure collagen protein is required with a proper synthesis and normal functioning.

Pathogenesis

Defective collagen leads to abnormalities in all connective tissue areas. In blood vessels, defective connective tissue leads to fragile capillaries and causes bruising, abnormal bleeding, and internal hemorrhages. Similarly, teeth loosen, bones are easily breakable, recurrence of fractures, and poor wound healing. Scurvy is fatal if left untreated.

Genetics

Scurvy is not a nutritional disorder exclusively. Some studies have shown evidence of genetic involvement. In the recent European history, the geographic variability of the higher mortality rate during famine and scurvy episodes can be explained by the genetic polymorphism of HFE and haptoglobin (Hp). HFE gene mutations occur in a genetic disorder, hereditary hemochromatosis, predominantly affects men and causes iron overload with a reduction in the stability of vitamin C. Hemochromatosis is associated with mutations in C282Y and H63D. [5] Hypoascorbemia is the true genetic disease defined as an "inborn error of metabolism", due to the absence of an active liver enzyme, L-gluconolactone oxidase. This is the enzyme used in the final step of converting glucose to ascorbic acid, therefore it blocks the endogenous formation of this important vitamin in man. [6] The absence of this enzyme is due to defected gene or hereditary lack of the gene. This disease is similar to other genetic metabolic disorders like alkaptonuria, galactosemia, albinism, and many others. [7]

Associated Conditions

Gross Pathology

Microscopic Pathology

Microscopically, it is similar to clinical manifestations. On punch biopsy, scurvy shows dilated hair follicles, perifollicular hemorrhage without inflammation, and corkscrew hairs causing keratin plugging. [8]

References

  1. Agarwal A, Shaharyar A, Kumar A, Bhat MS, Mishra M (2015). "Scurvy in pediatric age group - A disease often forgotten?". J Clin Orthop Trauma. 6 (2): 101–7. doi:10.1016/j.jcot.2014.12.003. PMC 4411344. PMID 25983516.
  2. Evans PR (1983). "Infantile scurvy: the centenary of Barlow's disease". Br Med J (Clin Res Ed). 287 (6408): 1862–3. doi:10.1136/bmj.287.6408.1862. PMC 1550031. PMID 6423046.
  3. Rajcáni J, Krobová J, Málková D (1975). "Distribution of Lednice (Yaba 1) virus in the chick embryo". Acta Virol. 19 (6): 467–72. PMID ZM, Sthoeger D. Harefuah. 1991;120(6):332 Sthoeger ZM, Sthoeger D. Harefuah. 1991;120(6):332 Check |pmid= value (help).
  4. Fowler NO, McCall D, Chou TC, Holmes JC, Hanenson IB (1976). "Electrocardiographic changes and cardiac arrhythmias in patients receiving psychotropic drugs". Am J Cardiol. 37 (2): 223–30. doi:10.1016/0002-9149(76)90316-7. PMID JS, Taylor CA, and Johnston CS. (2004). "Vi Hampl JS, Taylor CA, and Johnston CS. (2004). "Vi Check |pmid= value (help).
  5. Delanghe JR, De Buyzere ML, Speeckaert MM, Langlois MR (2013). "Genetic aspects of scurvy and the European famine of 1845-1848". Nutrients. 5 (9): 3582–8. doi:10.3390/nu5093582. PMC 3798922. PMID 24036531.
  6. Stone I (1966). "Hypoascorbemia, the genetic disease causing the human requirement for exogenous ascorbic acid". Perspect Biol Med. 10 (1): 133–4. doi:10.1353/pbm.1966.0037. PMID 6002772.
  7. Stone I (1966). "On the genetic etiology of scurvy". Acta Genet Med Gemellol (Roma). 15 (4): 345–50. doi:10.1017/s1120962300014931. PMID 5971711.
  8. Byard RW, Maxwell-Stewart H (2019). "Scurvy-Characteristic Features and Forensic Issues". Am J Forensic Med Pathol. 40 (1): 43–46. doi:10.1097/PAF.0000000000000442. PMID 30422823.