Abstract
Ultraviolet blood irradiation (UBI) was extensively used in the 1940s and 1950s to treat many diseases including septicemia, pneumonia, tuberculosis, arthritis, asthma and even poliomyelitis. The early studies were carried out by several physicians in USA and published in the American Journal of Surgery. However with the development of antibiotics, UBI use declined and it has now been called “the cure that time forgot”. Later studies were mostly performed by Russian workers and in other Eastern countries and the modern view in Western countries is that UBI remains highly controversial.
This chapter discusses the potential of UBI as an alternative approach to current methods used to treat infections, as an immune-modulating therapy and as a method for normalizing blood parameters. No resistance of microorganisms to UV irradiation has been reported, and multi-antibiotic resistant strains are as susceptible as their wild-type counterparts. Low and mild doses of UV kill microorganisms by damaging the DNA, while any DNA damage in host cells can be rapidly repaired by DNA repair enzymes. However the use of UBI to treat septicemia cannot be solely due to UV-mediated killing of bacteria in the blood-stream, as only 5–7% of blood volume needs to be treated with UV to produce the optimum benefit. UBI may enhance the phagocytic capacity of various phagocytic cells (neutrophils and dendritic cells), inhibit lymphocytes, and oxidize blood lipids. The oxidative nature of UBI may have mechanisms in common with ozone therapy and other oxygen therapies. There may be some similarities to extracorporeal photopheresis (ECP) using psoralens and UVA irradiation. However there are differences between UBI and ECP in that UBI tends to stimulate the immune system, while ECP tends to be immunosuppressive. With the recent emergence of bacteria that are resistant to all known antibiotics, UBI should be more investigated as an alternative approach to infections, and as an immune-modulating therapy.
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References
Frercksa J, Weberb H, Wiesenfeldt G (2009) Reception and discovery: the nature of Johann Wilhelm Ritter’s invisible rays. Stud Hist Philos Sci Part A 40:143–156
Bonnet A (1845) Traite des Maladies des Articulations. Bailliere, Paris
Barth J, Kohler U (1992) Photodermatologie in Dresden-ein historischer Abriss. Festschrift anlasslich des 75. Geburtstages von Prof. Dr. Dr. Dr. h.c. H.-E. Kleine-Natrop (1917–1985). Dresden
Downes A, Blunt TP (1877) Researches on the effect of light upon bacteria and other organisms. Proc R Soc Lond 26:488–500
Finsen NR (1901) Phototherapy. Edward Arnold, London
Ude WH (1929) Ultraviolet radiation therapy in erysipela. Radiology 13:504
Knott EK (1948) Development of ultraviolet blood irradiation. Am J Surg 76(2):165–171
Hancock VK, Knott EK (1934) Irradiated blood transfusion in the treatment of infections. Northwest Med 200(33)
Miley G, Christensen JA (1947) Ultraviolet blood irradiation further studies in acute infections. Am J Surg LxxIII(4):486–493
Miley G Uv irradiation non healing wounds. Am J Surg LXV(3):368–372, 1944
Miley GP (1946) Recovery from botulism coma following ultraviolet blood irradiation. Rev Gastroenterol 13:17–19
Miley GP, Seidel RE, Christensen JA (1946) Ultraviolet blood irradiation therapy of apparently intractable bronchial asthma. Arch Phys Med Rehabil 27:24–29
Miley G (1943) The control of acute thrombophlebitis with ultraviolet blood irradiation therapy. Am J Surg 60:354–360
Miley G (1944) Efficacy of ultraviolet blood irraidation therapy in the control of staphylococcemias. Am J Surg 64:313–322
Miley G (1944) Ultraviolet blood irraidation therapy in acute poliomyelitis. Arch Phys Ther 25:651–656
Miley G (1943) Disapperance of hemolytic staphylococcus aureus septicemia following ultraviolet blood irradiation therapy. Am J Surg 62:241–245
Miley G (1942) The knott technic of ultraviolet blood irradiation in acute pyogenic infections. New York state Med 42:38–46
Miley G (1944) Present status of ultraviolet blood irradiation (Knott technic). Arch Phys Ther 25:368–372
Miley G (1942) Ultravilet blood irradiation. Arch Phys Ther 536(23)
Miley G (1942) Ultraviolet blood irradiation therapy (knott technic) in acute pyogenic infections. Am J Surg 493(57)
Miley G (1943) The knott technic of ultraviolet blood irradiation as a control of infection in peritonitis. Rev Gastroenterol 1(10)
Miley GP, Seidel, R.E, Christensen, J.A (1943) Preliminary report of results observed in eighty cases of intractable bronchial asthma. Arch Phys Ther 533(24)
Barrett HA (1940) The irradiation of autotransfused blood by ultraviolet spectral energy. Result of therapy in 110 cases. Med clin N Am 721(24):1040
Barrett HA (1943) Five years’ experience with hemo-irradiation according to the Knott technic. Am J Surg 61(1):42–53
Rebbeck EW (1942) Double septicemia following prostatectomy treated by the knott technic of ultraviolet blood irradiation. Am J Surg 57(3):536–538
Rebbeck EW (1943) Preoperative hemo-irradiations. Am J Surg 61(2):259–265
Rebbeck EW (1941) Ultraviolet irradiation of autotransfused blood in the treatment of puerperal sepsis. Am J Surg 54(3):691–700
Rebbeck EW (1942) Ultraviolet irradiation of autotransfused blood in the treatment of postabortional sepsis. Am J Surg 55(3):476–486
Rebbeck EW (1943) Ultraviolet irradiation of blood in the treatment of escherichia coli septicemia. Arch Phys Ther 24:158–167
Olney RC (1946) Ultraviolet blood irradiation in biliary disease; Knott method. Am J Surg 72:235–237
Olney RC (1947) Ultraviolet blood irradiation treatment of pelvic cellulitis; Knott method. Am J Surg 74(4):440–443
Olney RC (1955) Treatment of viral hepatitis with the Knott technic of blood irradiation. Am J Surg 90(3):402–409
Kabat IA, Sysa J, Zakrzewska I, Leyko W (1976) Effect of UV-irradiation of shifts of energy-rich phosphate compounds: ADP, ATP and AXP in human red blood cells represented by a trigonometrical polynomial. Zentralbl Bakteriol Orig B 162(3–4):393–401
Vasil'eva ZF, Samoilova KA, Shtil'bans VI, Obolenskaia KD, Vitiuk NG (1991) Changes of immunosorption properties in the blood and its components at various times after UV-irradiation. Gematol Transfuziol 36(5):26–27
Samoilova KA, Snopov SA, Belisheva NK, Kukui LM, Ganelina IE (1987) Functional and structural changes in the surface of human erythrocytes after irradiation by different wave lengths of UV rays. III. The immediate effect of the autotransfusion of UV-irradiated blood. Tsitologiia 29(7):810–817
Snopov SA, Aritsishevskaia RA, Samoilova KA, Marchenko AV, Dutkevich IG (1989) Functional and structural changes in the surface of human erythrocytes following irradiation with ultraviolet rays of various wave lengths. V. Modification of the glycocalyx in autotransfusions of UV-irradiated blood. Tsitologiia 31(6):696–705
Ichiki H, Sakurada H, Kamo N, Takahashi TA, Sekiguchi S (1994) Generation of active oxygens, cell deformation and membrane potential changes upon UV-B irradiation in human blood cells. Biol Pharm Bull 17(8):1065–1069
Savage JE, Theron AJ, Anderson R (1993) Activation of neutrophil membrane-associated oxidative metabolism by ultraviolet radiation. J Invest Dermatol 101(4):532–536
Ivanov EM, Kapshienko IN, Tril NM (1989) Effect of the UV irradiation of autologous blood on the humoral link in the immune response of patients with chronic inflammatory processes. Vopr Kurortol Fizioter Lech Fiz Kult 1:45–47
Artiukhov VF, Gusinskaia VV, Mikhileva EA (2005) Level of nitric oxide and tumor necrosis factor-alpha production by human blood neutrophils under UV-irradiation. Radiats Biol Radioecol 45(5):576–580
Zor’kina AV, Inchina VI, Kostin Ia V (1996) Effect of UV-irradiation of blood on the course of adaptation to conditions of hypodynamia. Patol Fiziol Eksp Ter 2:22–24
Deeg HJ (1988) Ultraviolet irradiation in transplantation biology. Manipulation of immunity and immunogenicity. Transplantation 45(5):845–851
Arlett CF, Lowe JE, Harcourt SA et al (1993) Hypersensitivity of human lymphocytes to UV-B and solar irradiation. Cancer Res 53(3):609–614
Teunissen MB, Sylva-Steenland RM, Bos JD (1993) Effect of low-dose ultraviolet-B radiation on the function of human T lymphocytes in vitro. Clin Exp Immunol 94(1):208–213
Schieven GL, Ledbetter JA (1993) Ultraviolet radiation induces differential calcium signals in human peripheral blood lymphocyte subsets. J Immunother Emphasis Tumor Immunol 14(3):221–225
Spielberg H, June CH, Blair OC, Nystrom-Rosander C, Cereb N, Deeg HJ (1991) UV irradiation of lymphocytes triggers an increase in intracellular Ca2+ and prevents lectin-stimulated Ca2+ mobilization: evidence for UV- and nifedipine-sensitive Ca2+ channels. Exp Hematol 19(8):742–748
Pamphilon DH, Corbin SA, Saunders J, Tandy NP (1989) Applications of ultraviolet light in the preparation of platelet concentrates. Transfusion 29(5):379–383
Lindahl-Kiessling K, Safwenberg J (1971) Inability of UV-irradiated lymphocytes to stimulate allogeneic cells in mixed lymphocyte culture. Int Arch Allergy Appl Immunol 41(5):670–678
Slater LM, Murray S, Liu J, Hudelson B (1980) Dissimilar effects of ultraviolet light on HLA-D and HLA-DR antigens. Tissue Antigens 15(5):431–435
Aprile J, Deeg HJ (1986) Ultraviolet irradiation of canine dendritic cells prevents mitogen-induced cluster formation and lymphocyte proliferation. Transplantation 42(6):653–660
Kovacs E, Weber W, Muller H (1984) Age-related variation in the DNA-repair synthesis after UV-C irradiation in unstimulated lymphocytes of healthy blood donors. Mutat Res 131(5–6):231–237
Genter EI, Zhestianikov VD, Mikhel'son VM, Prokof’eva VV (1984) DNA repair in the UV irradiation of human peripheral blood lymphocytes (healthy donors and xeroderma pigmentosum patients) in relation to the dedifferentiation process in phytohemagglutinin exposure. Tsitologiia 26(5):599–604
Genter EI, Mikhel’son VM, Zhestianikov VD (1989) The modifying action of methylmethane sulfonate on unscheduled DNA synthesis in the UV irradiation of human peripheral blood lymphocytes. Radiobiologiia 29(4):562–564
Volgareva EV, Volgarev AP, Samoilova KA (1990) The effect of UV irradiation and of UV-irradiated autologous blood on the functional state of human peripheral blood lymphocytes. Tsitologiia 32(12):1217–1224
Deeg HJ, Aprile J, Graham TC, Appelbaum FR, Storb R (1986) Ultraviolet irradiation of blood prevents transfusion-induced sensitization and marrow graft rejection in dogs. Blood 67(2):537–539
Oluwole SF, Iga C, Lau H, Hardy MA (1985) Prolongation of rat heart allografts by donor-specific blood transfusion treated with ultraviolet irradiation. J Heart Transplant 4(4):385–389
Vasil’eva ZF, Shtil'bans VI, Samoilova KS, Obolenskaia KD (1989) The activation of the immunosorptive properties of blood during its UV irradiation at therapeutic doses. Biull Eksp Biol Med 108(12):689–691
Green MH, Waugh AP, Lowe JE, Harcourt SA, Cole J, Arlett CF (1994) Effect of deoxyribonucleosides on the hypersensitivity of human peripheral blood lymphocytes to UV-B and UV-C irradiation. Mutat Res 315(1):25–32
Samoilova KA, Obolenskaia KD, Freidlin IS (1987) Changes in the leukocyte phagocytic activity of donor blood after its UV irradiation. II. Simulation of the effect of the autotransfusion of UV-irradiated blood. Tsitologiia 29(9):1048–1055
Obolenskaia KD, Freidlin IS, Samoilova KA (1987) Changes in the leukocyte phagocytic activity of donor blood after its UV irradiation. I. Its relation to the irradiation dose and initial level of phagocytic activity. Tsitologiia 29(8):948–954
Simon JC, Tigelaar RE, Bergstresser PR, Edelbaum D, Cruz PD Jr (1991) Ultraviolet B radiation converts Langerhans cells from immunogenic to tolerogenic antigen-presenting cells. Induction of specific clonal anergy in CD4+ T helper 1 cells. J Immunol 146(2):485–491
Pamphilon DH, Potter M, Cutts M et al (1990) Platelet concentrates irradiated with ultraviolet light retain satisfactory in vitro storage characteristics and in vivo survival. Br J Haematol 75(2):240–244
Fiebig E, Lane TA (1994) Effect of storage and ultraviolet B irradiation on CD14-bearing antigen-presenting cells (monocytes) in platelet concentrates. Transfusion 34(10):846–851
Kahn RA, Duffy BF, Rodey GG (1985) Ultraviolet irradiation of platelet concentrate abrogates lymphocyte activation without affecting platelet function in vitro. Transfusion 25(6):547–550
Andreu G, Boccaccio C, Klaren J et al (1992) The role of UV radiation in the prevention of human leukocyte antigen alloimmunization. Transfus Med Rev 6(3):212–224
Tandy NP, Pamphilon DH (1991) Platelet transfusions irradiated with ultraviolet-B light may have a role in reducing recipient alloimmunization. Blood Coagul Fibrinolysis 2(2):383–388
Roshchupkin DI, Murina MA (1998) Free-radical and cyclooxygenase-catalyzed lipid peroxidation in membranes of blood cells under UV irradiation. Membr Cell Biol 12(2):279–286
Gorog P (1991) Activation of human blood monocytes by oxidized polyunsaturated fatty acids: a possible mechanism for the generation of lipid peroxides in the circulation. Int J Exp Pathol 72(2):227–237
Salmon S, Maziere JC, Santus R, Morliere P, Bouchemal N (1990) UVB-induced photoperoxidation of lipids of human low and high density lipoproteins. A possible role of tryptophan residues. Photochem Photobiol 52(3):541–545
Salmon S, Haigle J, Bazin M, Santus R, Maziere JC, Dubertret L (1996) Alteration of lipoproteins of suction blister fluid by UV radiation. J Photochem Photobiol B 33(3):233–238
Artyukhov VG, Iskusnykh AY, Basharina OV, Konstantinova TS (2005) Effect of UV irradiation on functional activity of donor blood neutrophils. Bull Exp Biol Med 139(3):313–315
Dong Y, Shou T, Zhou Y, Jiang S, Hua X (2000) Ultraviolet blood irradiation and oxygenation affects free radicals and antioxidase after rabbit spinal cord injury. Chin Med J 113(11):991–995
Calabrese EJ, Dhawan G, Kapoor R, Iavicoli I, Calabrese V (2015) HORMESIS: a fundamental concept with widespread biological and biomedical applications. Gerontology 62:530
Calabrese EJ (2014) Hormesis: from mainstream to therapy. J Cell Commun Signal 8(4):289–291
Zaky S, Kamel SE, Hassan MS et al (2011) Preliminary results of ozone therapy as a possible treatment for patients with chronic hepatitis C. J Altern Complement Med 17(3):259–263
Edelson RL (2014) Mechanistic insights into extracorporeal photochemotherapy: efficient induction of monocyte-to-dendritic cell maturation. Transfus Apher Sci 50(3):322–329
Child FJ, Ratnavel R, Watkins P et al (1999) Extracorporeal photopheresis (ECP) in the treatment of chronic graft-versus-host disease (GVHD). Bone Marrow Transplant 23(9):881–887
Atta M, Papanicolaou N, Tsirigotis P (2012) The role of extracorporeal photopheresis in the treatment of cutaneous T-cell lymphomas. Transfus Apher Sci 46(2):195–202
De Waure C, Capri S, Veneziano MA et al (2015) Extracorporeal Photopheresis for second-line treatment of chronic graft-versus-host diseases: Results from a health technology assessment in Italy. Value Health 18(4):457–466
Patel J, Klapper E, Shafi H, Kobashigawa JA (2015) Extracorporeal photopheresis in heart transplant rejection. Transfus Apher Sci 52(2):167–170
Reinisch W, Knobler R, Rutgeerts PJ et al (2013) Extracorporeal photopheresis (ECP) in patients with steroid-dependent Crohn’s disease: an open-label, multicenter, prospective trial. Inflamm Bowel Dis 19(2):293–300
Ludvigsson J, Samuelsson U, Ernerudh J, Johansson C, Stenhammar L, Berlin G (2001) Photopheresis at onset of type 1 diabetes: a randomised, double blind, placebo controlled trial. Arch Dis Child 85(2):149–154
Edelson R, Berger C, Gasparro F et al (1987) Treatment of cutaneous T-cell lymphoma by extracorporeal photochemotherapy. Preliminary results. N Engl J Med 316(6):297–303
Wollina U, Looks A, Meyer J et al (2001) Treatment of stage II cutaneous T-cell lymphoma with interferon alfa-2a and extracorporeal photochemotherapy: a prospective controlled trial. J Am Acad Dermatol 44(2):253–260
Niggli HJ, Rothlisberger R (1988) Cyclobutane-type pyrimidine photodimer formation and induction of ornithine decarboxylase in human skin fibroblasts after UV irradiation. J Invest Dermatol 91(6):579–584
Vendrell-Criado V, Rodriguez-Muniz GM, Lhiaubet-Vallet V, Cuquerella MC, Miranda MA (2016) The (6-4) Dimeric Lesion as a DNA Photosensitizer. Chem Phys Chem 17(13):1979–1982
Santella RM, Dharmaraja N, Gasparro FP, Edelson RL (1985) Monoclonal antibodies to DNA modified by 8-methoxypsoralen and ultraviolet A light. Nucleic Acids Res 13(7):2533–2544
Heald P, Rook A, Perez M et al (1992) Treatment of erythrodermic cutaneous T-cell lymphoma with extracorporeal photochemotherapy. J Am Acad Dermatol 27(3):427–433
Hart JW, Shiue LH, Shpall EJ, Alousi AM (2013) Extracorporeal photopheresis in the treatment of graft-versus-host disease: evidence and opinion. Ther Adv Hematol 4(5):320–334
Rowen RJ (1996) Ultraviolet blood irradiation therapy (Photo-Oxidation) the cure that time forgot. Int J Biosocial Med Research 14(2):115–132
Wu X, Hu X, Hamblin MR (2016) Ultraviolet blood irradiation: is it time to remember “the cure that time forgot”? J Photochem Photobiol B 157:89–96
Kraus CN (2008) Low hanging fruit in infectious disease drug development. Curr Opin Microbiol 11(5):434–438
Munoz-Price LS, Poirel L, Bonomo RA et al (2013) Clinical epidemiology of the global expansion of Klebsiella pneumoniae carbapenemases. Lancet Infect Dis 13(9):785–796
Yoneyama H, Katsumata R (2006) Antibiotic resistance in bacteria and its future for novel antibiotic development. Biosci Biotechnol Biochem 70(5):1060–1075
O'neill J (2015) Review on antimicrobial resistance: tackling a global health crisis. Initial Steps
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Hamblin, M.R. (2017). Ultraviolet Irradiation of Blood: “The Cure That Time Forgot”?. In: Ahmad, S. (eds) Ultraviolet Light in Human Health, Diseases and Environment. Advances in Experimental Medicine and Biology, vol 996. Springer, Cham. https://doi.org/10.1007/978-3-319-56017-5_25
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