Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

Keynote webinar | Spotlight on medication adherence

LIVE: Thursday 27th June 2024, 18:00-19:30 (CEST)
Join our expert panel to discover why you need to understand the drivers of non-adherence in your patients, and how you can optimize medication adherence in your clinics to drastically improve patient outcomes.
ADVANCED SEARCH
Log in
Top
Lasers in Medical Science
Published in: Lasers in Medical Science 2/2014

Open Access 01-03-2014 | Original Article

A literature review and novel theoretical approach on the optical properties of whole blood

Authors: Nienke Bosschaart, Gerda J. Edelman, Maurice C. G. Aalders, Ton G. van Leeuwen, Dirk J. Faber

Published in: Lasers in Medical Science | Issue 2/2014

Login to get access

Abstract

Optical property measurements on blood are influenced by a large variety of factors of both physical and methodological origin. The aim of this review is to list these factors of influence and to provide the reader with optical property spectra (250–2,500 nm) for whole blood that can be used in the practice of biomedical optics (tabulated in the appendix). Hereto, we perform a critical examination and selection of the available optical property spectra of blood in literature, from which we compile average spectra for the absorption coefficient (μa), scattering coefficient (μs) and scattering anisotropy (g). From this, we calculate the reduced scattering coefficient (μs′) and the effective attenuation coefficient (μeff). In the compilation of μa and μs, we incorporate the influences of absorption flattening and dependent scattering (i.e. spatial correlations between positions of red blood cells), respectively. For the influence of dependent scattering on μs, we present a novel, theoretically derived formula that can be used for practical rescaling of μs to other haematocrits. Since the measurement of the scattering properties of blood has been proven to be challenging, we apply an alternative, theoretical approach to calculate spectra for μs and g. Hereto, we combine Kramers–Kronig analysis with analytical scattering theory, extended with Percus–Yevick structure factors that take into account the effect of dependent scattering in whole blood. We argue that our calculated spectra may provide a better estimation for μs and g (and hence μs′ and μeff) than the compiled spectra from literature for wavelengths between 300 and 600 nm.
Appendix
Available only for authorised users
Literature
1.
McMurdy J, Jay G, Suner S, Crawford G (2009) Photonics-based in vivo total hemoglobin monitoring and clinical relevance. J Biophotonics 5:277–287
2.
Van den Bos R, Arends L, Kockaert M, Neumann M, Nijsten T (2009) Endovenous therapies of lower extremity varicosities: a meta-analysis. J Vasc Surg 49:230–239PubMed
3.
Horecker BL (1943) The absorption spectra of hemoglobin and its derivatives in the visible and near infra-red regions. J Biol Chem 148:173–183
4.
Zijlstra WG, Buursma A, van Assendelft OW (2000) Visible and near infrared absorption spectra of human and animal haemoglobin. VSP, Utrecht
5.
Data from Gratzer WB (Med. Res. Council Labs, Holly Hill, London) and Kollias N (Wellman Laboratories, Harvard Medical School, Boston) compiled and tabulated by Prahl S: http://​omlc.​ogi.​edu/​spectra/​, accessed 26 March 2013
6.
Yaroslavsky AN, Yaroslavsky IV, Goldbach T, Schwarzmaier HJ (1996) The optical properties of blood in the near infrared spectral range. Proc SPIE 2678:314–324
7.
Roggan A, Friebel M, Dorschel K, Hahn A, Muller G (1999) Optical properties of circulating human blood in the wavelength range 400–2500 nm. J Biomed Opt 4:36–46PubMed
8.
Friebel M, Roggan A, Muller G, Meinke M (2006) Determination of optical properties of human blood in the spectral range 250 to 1100 nm using Monte Carlo simulations with hematocrit-dependent effective scattering phase functions. J Biomed Opt 11:034021
9.
Friebel M, Helfmann J, Netz U, Meinke M (2009) Influence of oxygen saturation on the optical scattering properties of human red blood cells in the spectral range 250 to 2000 nm. J Biomed Opt 14:034001PubMed
10.
Meinke M, Muller G, Helfmann J, Friebel M (2007) Empirical model functions to calculate hematocrit-dependent optical properties of human blood. Appl Opt 46:1742–1753PubMed
11.
Steinke JM, Shepherd AP (1988) Diffuse model of the optical absorbance of whole blood. JOSA A 5:813–822
12.
Faber DJ, van Leeuwen TG (2009) Are quantitative attenuation measurements of blood by optical coherence tomography feasible? Opt Lett 34:1435–1437PubMed
13.
Enejder AMK, Swartling J, Aruna P, Andersson-Engels S (2003) Influence of cell shape and aggregate formation on the optical properties of flowing whole blood. Appl Opt 42:1384–1394PubMed
14.
Steenbergen W, Kolkman R, de Mul F (1999) Light-scattering properties of undiluted human blood subjected to simple shear. JOSA 16:2959–2967
15.
Friebel M, Helfmann J, Muller G, Meinke M (2007) Influence of shear rate on the optical properties of human blood in the spectral range 250 to 1100 nm. J Biomed Opt 12:054005PubMed
16.
Sakota D, Takatani S (2012) Quantitative analysis of optical properties of flowing blood using a photon-cell interactive Monte Carlo code: effects of red blood cells’ orientation on light scattering. J Biomed Opt 17:057007PubMed
17.
Faber DJ, Aalders MCG, Mik EG, Hooper BA, van Gemert MJC, van Leeuwen TG (2004) Oxygen saturation-dependent absorption and scattering of blood. Phys Rev Lett 93:028102PubMed
18.
Van der Pol E, Boïng AN, Harrison P, Sturk A, Nieuwland R (2012) Classification, functions and clinical relevance of extracellular vesicles. Pharmacol Rev 64:676–705PubMed
19.
Boulpaep EL (2009) Blood (chapter 18). In: Boron F, Boulpaep EL (eds) Medical physiology, 2nd edn. Saunders, Philadelphia, pp. 448–481
20.
Meinke M, Muller G, Helfmann J, Friebel M (2007) Optical properties of platelets and blood plasma and their influence on the optical behavior of whole blood in the visible to near infrared wavelength range. J Biomed Opt 12:014024PubMed
21.
Bosschaart N, Kok JH, Newsum AM, Ouweneel DM, Mentink R, van Leeuwen TG, Aalders MCG (2012) Limitations and opportunities of transcutaneous bilirubin measurements. Pediatrics 129:689–694PubMed
22.
Edelman G, Manti V, Ruth SM, van Leeuwen T, Aalders M (2012) Identification and age estimation of blood stains on colored backgrounds by near infrared spectroscopy. Forensic Sci Int 220:239–244PubMed
23.
Tsinopoulos SV, Euripides JS, Polyzos D (2002) Light scattering by aggregated red blood cells. Appl Opt 41:1408–1417PubMed
24.
Lee VS, Tarassenko L (1991) Absorption and multiple scattering by suspensions of aligned red blood cells. JOSA 8:1135–1141
25.
Steinke JM, Sheperd AP (1992) Effects of temperature on optical absorbance spectra of oxy-, carboxy-, and deoxyhemoglobin. Clin Chem 38:1360–1364PubMed
26.
Mordon S, Rochon P, Dhelin G, Lesage JC (2005) Dynamics of temperature dependent modifications of blood in the near-infrared. Lasers Surg Med 37:301–307PubMed
27.
Ergül Ö, Arslan-Ergül A, Gürel L (2010) Computational study of scattering from healthy and diseased red blood cells. J Biomed Opt 15:045004PubMed
28.
Serebrennikova YM, Smith JM, Huffman DE, Leparc GF, Garcia-Rubio LH (2008) Quantitative interpretations of visible-NIR reflectance spectra of blood. Opt Express 16:18215–18229PubMed
29.
Xu X, Lin J, Fu F (2011) Optical coherence tomography to investigate optical properties of blood during coagulation. J Biomed Opt 16:096002PubMed
30.
Friebel M, Meinke M (2006) Model function to calculate the refractive index of native hemoglobin in the wavelength range of 250–1100 nm dependent on concentration. Appl Opt 45:2838–2842PubMed
31.
Hale GM, Querry MR (1973) Optical constants of water in the 200-nm to 200-μm wavelength region. Appl Opt 12:555–563PubMed
32.
Duysens LMN (1956) The flattening of the absorption spectrum of suspensions, as compared to that of solutions. Biochim Biophys Acta 19:1–12PubMed
33.
Finlay JC, Foster TH (2004) Effect of pigment packaging on diffuse reflection spectroscopy of samples containing red blood cells. Opt Lett 29:965–967PubMed
34.
Reynolds LO, McCormick NJ (1980) Approximate two-parameter phase function for light scattering. JOSA 70:1206–1212
35.
Lucarni V, Saarinen JJ, Peiponen KE, Vartiainen EM (2005) Kramers-Kronig relations in optical materials research. Springer Series in Optical Sciences 110, IX
36.
Van de Hulst HC (1981) Light scattering by small particles. Dovers, Mineola
37.
Steinke JM, Shepard AP (1988) Comparison of Mie theory and the light scattering of red blood cells. Appl Opt 27:4027–4033PubMed
38.
Hespel L, Mainguy S, Greffet JJ (2001) Theoretical and experimental investigation of the extinction in a dense distribution of particles: nonlocal effects. JOSA A 18:3072–3076PubMed
39.
Khlebtsov NG, Maksimova IL, Tuchin VV, Wang LV (2002) Introduction to light scattering by biological objects. In: Tuchin VV (ed) Handbook of optical biomedical diagnostics. SPIE, Bellingham, pp 331–168
40.
Twersky V (1970) Absorption and multiple scattering by biological suspensions. JOSA 60:1084–1093
41.
Twersky V (1978) Acoustic bulk parameters in distributions of pair-correlated scatterers. JASA 64:1710–1719
42.
Ishimaru A, Kuga Y (1982) Attenuation constant of coherent field in a dense distribution of particles. JOSA 72:1317–1320
43.
Streekstra GJ, Hoeksra AG, Nijhof EJ, Heethaar RM (1993) Light scattering by red blood cells in ektacytometry: Fraunhofer versus anomalous diffraction. Appl Opt 32:2266–2272PubMed
44.
Percus JK, Yevick GJ (1958) Analysis of classical statistical mechanics by means of collective coordinates. Phys Rev 110:1–13
45.
Wertheim MS (1963) Exact solution of the Percus-Yevick integral equation for hard spheres. Phys Rev Lett 10:321–323
46.
Prahl S (2013) Mie scattering calculator. omlc.ogi.edu/calc/mie_calc.html. Accessed 26 June 2013
47.
Faber DJ, Mik EG, Aalders MC, van Leeuwen TG (2003) Light absorption of (oxy-)hemoglobin assessed by spectroscopic optical coherence tomography. Opt Lett 28:1436–1438PubMed
48.
Faber DJ, Mik EG, Aalders MC, van Leeuwen TG (2005) Toward assessment of blood oxygen saturation by spectroscopic optical coherence tomography. Opt Lett 30:1015–1017PubMed
49.
Bosschaart N, Aalders MCG, Faber DJ, Weda JJA, van Gemert MJC, van Leeuwen TG (2009) Quantitative measurements of absorption spectra in scattering media by low-coherence spectroscopy. Opt Lett 34:3746–3748PubMed
50.
Bosschaart N, Faber DJ, van Leeuwen TG, Aalders MCG (2011) Measurements of wavelength dependent scattering and backscattering coefficients by low-coherence spectroscopy. J Biomed Opt 16:030503PubMed
51.
Bosschaart N, Aalders MCG, van Leeuwen TG, Faber DJ (2012) Spectral domain detection in low-coherence spectroscopy. Biomed Opt Express 3:2263–2272PubMedPubMedCentral
52.
Bosschaart N, Faber DJ, van Leeuwen TG, Aalders MCG (2011) In vivo low-coherence spectroscopic measurements of local hemoglobin absorption spectra in human skin. J Biomed Opt 16:100504PubMed
53.
Kostinski AB (2001) On the extinction of radiation bya homogeneous but spatially correlated random medium. JOSA 18:1929–1933
54.
Twersky V (1975) Transparency of pair-correlated, random distributions of small scatterers, with applications to the cornea. JOSA 65:524–530
55.
Van Veen RLP, Verkruysse W, Sterenborg HJCM (2002) Diffuse-reflectance spectroscopy from 500 to 1060 nm by correction for inhomogeneously distributed absorbers. Opt Lett 27:246–248PubMed
56.
Svaasand LO, Fiskerstrand EJ, Kopstad G, Norvang LT, Svaasand EK, Nelson JS, Berns MW (1995) Therapeuatic response during pulsed laser treatment of port-wine stains: dependence on vessel diameter and depth in dermis. Lasers Med Sci 10:235–243
57.
Kalkman J, Bykov AV, Streekstra GJ, van Leeuwen TG (2012) Multiple scattering effects in Doppler optical coherence tomography of flowing blood. Phys Med Biol 57:1907–1917PubMed
Metadata
Title
A literature review and novel theoretical approach on the optical properties of whole blood
Authors
Nienke Bosschaart
Gerda J. Edelman
Maurice C. G. Aalders
Ton G. van Leeuwen
Dirk J. Faber
Publication date
01-03-2014
Publisher
Springer London
Published in
Lasers in Medical Science / Issue 2/2014
Print ISSN: 0268-8921
Electronic ISSN: 1435-604X
DOI
https://doi.org/10.1007/s10103-013-1446-7

Other articles of this Issue 2/2014

Lasers in Medical Science 2/2014 Go to the issue

Editorial

Ins and outs of endovenous laser ablation: afterthoughts

Original Article

Two-micron thulium laser resection of the distal ureter and bladder cuff during nephroureterectomy for upper urinary tract urothelial carcinoma

Original Article

Mechanism study of laser cochleostomy-induced early hearing loss in a rat model

Original Article

Melasma and laser treatment: an evidenced-based analysis

Original Article

Effect of CO2 laser on root caries inhibition around composite restorations: an in vitro study

Original Article

Protective effect of low-level laser therapy (LLLT) on acute zymosan-induced arthritis