Chlorophyll

    Researchedby:

    Fact-checked

    by:

    Last Updated: October 31, 2023

    Chlorophyll is the most abundant pigment on Earth, and is responsible for creating the green color in plants and algae. Despite years of use as a dietary supplement, there is very little human clinical research exploring the potential benefits of chlorophyll. In vitro and animal research suggest that chlorophyll and its derivatives may possess antioxidant, anti-inflammatory, and anti-cancer properties.

    What is chlorophyll?

    Chlorophyll is a naturally occurring pigment found in plants and algae that creates their characteristic green color. Its primary function is to facilitate photosynthesis, whereby sunlight is used to generate chemical energy for the plant.[4] There are several types of chlorophyll that are together considered the most abundant pigments on Earth, but chlorophyll a and b account for over 99% of naturally occurring chlorophyll.[5] Chlorophyll is a phytonutrient, meaning it is a biologically active but non-nutritive substance found in plants that may contribute to health. Some food sources particularly rich in chlorophyll include spinach, arugula, broccoli, green beans, and peas.[5] Natural chlorophyll is highly unstable and prone to degradation; therefore, most chlorophyll supplements (including those used in studies) actually contain a semisynthetic derivative of chlorophyll called sodium copper chlorophyllin (SCC), which has been chemically modified to increase its stability and solubility.[5] While chlorophyll has demonstrated potential health benefits in preclinical research, its effects in humans are poorly understood.

    What are chlorophyll’s main benefits?

    In vitro and animal studies suggest that chlorophyll and its derivatives may have anti-inflammatory,[6] antioxidant,[7][8] anticarcinogenic, anti-obesity,[9] and anti-diabetic properties.[10] However, none of these effects have been confirmed in human clinical trials.

    Chlorophyll and its derivatives have demonstrated cancer-preventative effects in animals, and this remains an area of active research in humans.[11][12][13][14] Chlorophyll seems to be able to tightly bind to various carcinogenic compounds (e.g., polyaromatic hydrocarbons, heterocyclic amines, aflatoxin),[15][16][17] potentially preventing their gastrointestinal absorption and interaction with body tissues. Two clinical trials have found that chlorophyll supplementation (as SCC) reduced the absorption of aflatoxin, a carcinogenic mold and food contaminant.[18][1] Still, it’s unknown if this translates to a reduced risk of cancer in the long-term.

    What are chlorophyll’s main drawbacks?

    Chlorophyll is generally considered to be safe and well-tolerated, although proper safety analyses have not been done. According to case reports, oral use has been associated with green-colored stool and increased skin sensitivity to sun exposure (photosensitivity),[19][20] and topical use may cause dermatitis.[21]

    How does chlorophyll work?

    The effects of chlorophyll are complex and poorly understood. In vitro studies suggest that chlorophyll can act as an antioxidant directly by acting as an electron donor to stabilize reactive species, and can also activate the transcription factor NF-E2-related factor 2 (Nrf2), leading to an increased production of the body’s own antioxidant enzymes.[22][5] Accordingly, in animals chlorophyll has been shown to reduce oxidative stress and prevent oxidative damage following exposure to pro-oxidant compounds.[8][5] Chlorophyll could have cancer-preventative effects by tightly binding (chelating) to carcinogenic compounds, preventing their absorption and interactions with the body, and has been found in animals to protect against DNA damage and mutations induced by certain compounds.[5] However, how chlorophyll works in the human body is largely unexplored.

    While it was previously thought that chlorophyll was not absorbed by the human body, research now suggests that upon ingestion, chlorophyll is rapidly degraded into different derivative compounds that may be subsequently absorbed into the bloodstream with varying degrees of bioavailability.[23][24] Natural chlorophyll consists of a ring structure with a magnesium atom in the center and a hydrophobic (i.e., insoluble in water) side chain. Through exposure to different temperatures, pH, or food processing techniques, chlorophyll can be converted into many possible derivatives; these can involve replacing the central magnesium atom with another metal (e.g., zinc, iron, copper), removing it altogether, or removing the side chain.[5] All of these potential changes alter the properties of chlorophyll. It has been suggested that chlorophyll’s potential positive effects are likely due to its derivatives, not the unaltered compound.[5][25] Ultimately, a lot more research is needed to understand the complexities of chlorophyll and its derivative compounds.

    What are other names for Chlorophyll

    Note that Chlorophyll is also known as:
    • Chlorophyll a
    • Chlorophyll b
    • Sodium copper chlorophyllin (a semisynthetic derivative)
    Chlorophyll should not be confused with:

    Dosage information

    Chlorophyll is most often taken in a liquid or capsule form at dosages ranging from 100 to 300 mg daily.[1][2][3] However, more studies in humans are needed to determine what the effective dose of chlorophyll (or the particular chlorophyll derivative) is. Most dietary supplements contain the chlorophyll derivative sodium copper chlorophyllin, rather than natural chlorophyll, due to its increased stability.

    Frequently asked questions

    What is chlorophyll?

    Chlorophyll is a naturally occurring pigment found in plants and algae that creates their characteristic green color. Its primary function is to facilitate photosynthesis, whereby sunlight is used to generate chemical energy for the plant.[4] There are several types of chlorophyll that are together considered the most abundant pigments on Earth, but chlorophyll a and b account for over 99% of naturally occurring chlorophyll.[5] Chlorophyll is a phytonutrient, meaning it is a biologically active but non-nutritive substance found in plants that may contribute to health. Some food sources particularly rich in chlorophyll include spinach, arugula, broccoli, green beans, and peas.[5] Natural chlorophyll is highly unstable and prone to degradation; therefore, most chlorophyll supplements (including those used in studies) actually contain a semisynthetic derivative of chlorophyll called sodium copper chlorophyllin (SCC), which has been chemically modified to increase its stability and solubility.[5] While chlorophyll has demonstrated potential health benefits in preclinical research, its effects in humans are poorly understood.

    What are chlorophyll’s main benefits?

    In vitro and animal studies suggest that chlorophyll and its derivatives may have anti-inflammatory,[6] antioxidant,[7][8] anticarcinogenic, anti-obesity,[9] and anti-diabetic properties.[10] However, none of these effects have been confirmed in human clinical trials.

    Chlorophyll and its derivatives have demonstrated cancer-preventative effects in animals, and this remains an area of active research in humans.[11][12][13][14] Chlorophyll seems to be able to tightly bind to various carcinogenic compounds (e.g., polyaromatic hydrocarbons, heterocyclic amines, aflatoxin),[15][16][17] potentially preventing their gastrointestinal absorption and interaction with body tissues. Two clinical trials have found that chlorophyll supplementation (as SCC) reduced the absorption of aflatoxin, a carcinogenic mold and food contaminant.[18][1] Still, it’s unknown if this translates to a reduced risk of cancer in the long-term.

    Does chlorophyll improve anemia?

    Anemia generally refers to a reduction in the red blood cell count, hematocrit, or hemoglobin in the blood, leading to symptoms of fatigue and weakness.[26] Chlorophyll has some structural similarities to the heme group of hemoglobin: both molecules share a similar ring structure, but chlorophyll has a magnesium atom in the center of the ring, while heme has an iron atom.[27] Because of this, it was historically thought that chlorophyll supplementation might help treat anemia.

    Animal studies using chlorophyll (as SCC) in doses much higher than those typically used in humans have observed improvements in blood parameters, including increased levels of red blood cells, hematocrit, and hemoglobin.[28][29] However, one clinical trial in endurance athletes found that SCC had no effect on anemia-related blood parameters.[30] Interestingly, in traditional Chinese medicine, a compound called shengxuening (SXN) that is extracted from the excrement of silkworms has been used for various types of anemia with some success. SXN is particularly rich in chlorophyll derivatives, including sodium iron chlorophyllin (SIC) wherein the central magnesium atom is replaced with an iron atom.[31] The iron atom in SIC is absorbed in the gastrointestinal tract by the same mechanisms as heme iron, and the chlorophyll derivatives in SXN are also hypothesized to stimulate erythropoetin.[31] Although trials have generally been small and of low methodological quality, research suggests that SXN may be more effective and better-tolerated than oral iron supplements in treating anemia.[32][33]

    Does chlorophyll reduce bad breath or body odor?

    There is currently no convincing evidence that chlorophyll supplementation reduces bad breath or body odor.

    Historically, chlorophyll was thought to have a deodorizing effect on urine, feces, wounds, breath, and general body odor; however, these claims were based primarily on case reports and on uncontrolled trials that had low-quality methodology and used outdated measurement tools.[19][34] One randomized controlled trial in people with a colostomy found that chlorophyll was no more effective than placebo in reducing fecal odor.[35] Most recently, a study published in 2004 found that in patients with trimethylaminuria — a genetic disorder that results in the build-up of trimethylamine (TMA) in the body, leading to a fishy body odor — chlorophyll (as SCC) reduced urinary levels of TMA, although changes in body odor were not assessed.[2]

    Does chlorophyll impact wound healing or general skin health?

    Historically, chlorophyll was used topically to promote wound healing, based on case reports and uncontrolled clinical trials;[36][37] however, this effect has not been validated in well-designed clinical trials, and there has been very little research on this topic over the last several decades.

    Topical chlorophyll and its derivatives have shown some benefits for skin health in preliminary clinical trials. In women with sun-damaged skin, a topical gel containing 0.066% (w/w) chlorophyllin-complex salts reduced pigmentation, pore size, and improved elasticity compared to baseline; however, this trial was not properly blinded and included just 10 people.[38] In two small trials, chlorophyll was found to improve acne and reduce oil production (based on subjective reporting) when used in addition to phototherapy, as compared to phototherapy alone, but these trials included just 4 and 24 participants.[39][40] Lastly, several case reports have reported improvements in rosacea symptoms with topical chlorophyll products.[41] Ultimately, larger, well-designed trials are needed to confirm the efficacy of chlorophyll for skin health.

    What are chlorophyll’s main drawbacks?

    Chlorophyll is generally considered to be safe and well-tolerated, although proper safety analyses have not been done. According to case reports, oral use has been associated with green-colored stool and increased skin sensitivity to sun exposure (photosensitivity),[19][20] and topical use may cause dermatitis.[21]

    How does chlorophyll work?

    The effects of chlorophyll are complex and poorly understood. In vitro studies suggest that chlorophyll can act as an antioxidant directly by acting as an electron donor to stabilize reactive species, and can also activate the transcription factor NF-E2-related factor 2 (Nrf2), leading to an increased production of the body’s own antioxidant enzymes.[22][5] Accordingly, in animals chlorophyll has been shown to reduce oxidative stress and prevent oxidative damage following exposure to pro-oxidant compounds.[8][5] Chlorophyll could have cancer-preventative effects by tightly binding (chelating) to carcinogenic compounds, preventing their absorption and interactions with the body, and has been found in animals to protect against DNA damage and mutations induced by certain compounds.[5] However, how chlorophyll works in the human body is largely unexplored.

    While it was previously thought that chlorophyll was not absorbed by the human body, research now suggests that upon ingestion, chlorophyll is rapidly degraded into different derivative compounds that may be subsequently absorbed into the bloodstream with varying degrees of bioavailability.[23][24] Natural chlorophyll consists of a ring structure with a magnesium atom in the center and a hydrophobic (i.e., insoluble in water) side chain. Through exposure to different temperatures, pH, or food processing techniques, chlorophyll can be converted into many possible derivatives; these can involve replacing the central magnesium atom with another metal (e.g., zinc, iron, copper), removing it altogether, or removing the side chain.[5] All of these potential changes alter the properties of chlorophyll. It has been suggested that chlorophyll’s potential positive effects are likely due to its derivatives, not the unaltered compound.[5][25] Ultimately, a lot more research is needed to understand the complexities of chlorophyll and its derivative compounds.

    Update History

    References

    1. ^Jubert C, Mata J, Bench G, Dashwood R, Pereira C, Tracewell W, Turteltaub K, Williams D, Bailey GEffects of chlorophyll and chlorophyllin on low-dose aflatoxin B(1) pharmacokinetics in human volunteers.Cancer Prev Res (Phila).(2009-Dec)
    2. ^Yamazaki H, Fujieda M, Togashi M, Saito T, Preti G, Cashman JR, Kamataki TEffects of the dietary supplements, activated charcoal and copper chlorophyllin, on urinary excretion of trimethylamine in Japanese trimethylaminuria patients.Life Sci.(2004-Apr-16)
    3. ^Egner PA, Stansbury KH, Snyder EP, Rogers ME, Hintz PA, Kensler TWIdentification and characterization of chlorin e(4) ethyl ester in sera of individuals participating in the chlorophyllin chemoprevention trial.Chem Res Toxicol.(2000-Sep)
    4. ^Ebrahimi P, Shokramraji Z, Tavakkoli S, Mihaylova D, Lante AChlorophylls as Natural Bioactive Compounds Existing in Food By-Products: A Critical Review.Plants (Basel).(2023-Apr-02)
    5. ^Martins T, Barros AN, Rosa E, Antunes LEnhancing Health Benefits through Chlorophylls and Chlorophyll-Rich Agro-Food: A Comprehensive Review.Molecules.(2023-Jul-11)
    6. ^Li Y, Cui Y, Lu F, Wang X, Liao X, Hu X, Zhang YBeneficial effects of a chlorophyll-rich spinach extract supplementation on prevention of obesity and modulation of gut microbiota in high-fat diet-fed miceJFF.(2019 Sep)
    7. ^Kumar SS, Shankar B, Sainis KBEffect of chlorophyllin against oxidative stress in splenic lymphocytes in vitro and in vivo.Biochim Biophys Acta.(2004-May-03)
    8. ^Wang E, Wink MChlorophyll enhances oxidative stress tolerance in Caenorhabditis elegans and extends its lifespan.PeerJ.(2016)
    9. ^Li Y, Cui Y, Hu X, Liao X, Zhang YChlorophyll Supplementation in Early Life Prevents Diet-Induced Obesity and Modulates Gut Microbiota in Mice.Mol Nutr Food Res.(2019-Nov)
    10. ^Wunderlich ALM, Azevedo SCSF, Yamada LA, Bataglini C, Previate C, Campanholi KSS, Pereira PCS, Caetano W, Kaplum V, Nakamura CV, Nakanishi ABS, Comar JF, Pedrosa MMD, Godoi VAFChlorophyll treatment combined with photostimulation increases glycolysis and decreases oxidative stress in the liver of type 1 diabetic rats.Braz J Med Biol Res.(2020)
    11. ^Simonich MT, McQuistan T, Jubert C, Pereira C, Hendricks JD, Schimerlik M, Zhu B, Dashwood RH, Williams DE, Bailey GSLow-dose dietary chlorophyll inhibits multi-organ carcinogenesis in the rainbow trout.Food Chem Toxicol.(2008-Mar)
    12. ^Harttig U, Bailey GSChemoprotection by natural chlorophylls in vivo: inhibition of dibenzoa,lpyrene-DNA adducts in rainbow trout liver.Carcinogenesis.(1998-Jul)
    13. ^Simonich MT, Egner PA, Roebuck BD, Orner GA, Jubert C, Pereira C, Groopman JD, Kensler TW, Dashwood RH, Williams DE, Bailey GSNatural chlorophyll inhibits aflatoxin B1-induced multi-organ carcinogenesis in the rat.Carcinogenesis.(2007-Jun)
    14. ^de Vogel J, Jonker-Termont DS, van Lieshout EM, Katan MB, van der Meer RGreen vegetables, red meat and colon cancer: chlorophyll prevents the cytotoxic and hyperproliferative effects of haem in rat colon.Carcinogenesis.(2005-Feb)
    15. ^Dashwood R, Yamane S, Larsen RStudy of the forces of stabilizing complexes between chlorophylls and heterocyclic amine mutagens.Environ Mol Mutagen.(1996)
    16. ^N Tachino, D Guo, W M Dashwood, S Yamane, R Larsen, R DashwoodMechanisms of the in vitro antimutagenic action of chlorophyllin against benzoapyrene: studies of enzyme inhibition, molecular complex formation and degradation of the ultimate carcinogenMutat Res.(1994 Jul 16)
    17. ^V Breinholt, M Schimerlik, R Dashwood, G BaileyMechanisms of chlorophyllin anticarcinogenesis against aflatoxin B1: complex formation with the carcinogenChem Res Toxicol.(1995 Jun)
    18. ^Egner PA, Wang JB, Zhu YR, Zhang BC, Wu Y, Zhang QN, Qian GS, Kuang SY, Gange SJ, Jacobson LP, Helzlsouer KJ, Bailey GS, Groopman JD, Kensler TWChlorophyllin intervention reduces aflatoxin-DNA adducts in individuals at high risk for liver cancer.Proc Natl Acad Sci U S A.(2001-Dec-04)
    19. ^Young RW, Beregi JSUse of chlorophyllin in the care of geriatric patients.J Am Geriatr Soc.(1980-Jan)
    20. ^Zhao CY, Frew JW, Muhaidat J, Cheung K, Lee P, Poulos V, McCrossin I, Cachia AR, Tefany F, Murrell DFChlorophyll-induced pseudoporphyria with ongoing photosensitivity after cessation - a case series of four patients.J Eur Acad Dermatol Venereol.(2016-Jul)
    21. ^SMITH LWThe present status of topical chlorophyll therapy.N Y State J Med.(1955-Jul-15)
    22. ^Zhang Y, Guan L, Wang X, Wen T, Xing J, Zhao JProtection of chlorophyllin against oxidative damage by inducing HO-1 and NQO1 expression mediated by PI3K/Akt and Nrf2.Free Radic Res.(2008-Apr)
    23. ^Ferruzzi MG, Failla ML, Schwartz SJAssessment of degradation and intestinal cell uptake of carotenoids and chlorophyll derivatives from spinach puree using an in vitro digestion and Caco-2 human cell model.J Agric Food Chem.(2001-Apr)
    24. ^Gallardo-Guerrero L, Gandul-Rojas B, Mínguez-Mosquera MIDigestive stability, micellarization, and uptake by Caco-2 human intestinal cell of chlorophyll derivatives from different preparations of pea (Pisum sativum L.).J Agric Food Chem.(2008-Sep-24)
    25. ^Perez-Galvez A, Viera I, Roca MChemistry in the Bioactivity of Chlorophylls: An Overview.Curr Med Chem.(2017)
    26. ^Turner J, Parsi M, Badireddy MAnemiaStatPearls.(2023-01)
    27. ^Hendry GA, Jones OTHaems and chlorophylls: comparison of function and formation.J Med Genet.(1980-Feb)
    28. ^Tagauov YD, Abu-Elsaoud AM, Abdrassulova ZT, Tuleukhanov ST, Salybekova NN, Tulindinova G, Al-Abkal FImprovement of Blood Parameters of Male Rats Exposed to Different Injection Doses of Liquid Chlorophyll.Cureus.(2023-Mar)
    29. ^Jin X, Dai G, Xuan L, Zhang M, Jiang H, Sui YEffects of Sodium Chlorophyllin Copper on APO-1 Expression in Bone Marrow Mesenchymal Stem Cells of Rats with Aplastic Anaemia.J Immunol Res.(2022)
    30. ^Cugliari G, Messina F, Canavero V, Biorci F, Ivaldi MRelationship of chlorophyll supplement and platelet-related measures in endurance athletes: a randomized, double-blind, placebo-controlled studySport Sci Health.(2018 Jun)
    31. ^Ding L, Xu L, Jin Y, Wei Y, Pan Y, Sattar S, Tan Y, Yang T, Zhou FEfficacy of SXN in the Treatment of Iron Deficiency Anemia: A Phase IV Clinical Trial.Evid Based Complement Alternat Med.(2019)
    32. ^Zhang L, Zhang W, Jin H, Wang D, Wei N, Wang YEffect and safety of Shengxuening (extract from excrement of bombyxin) for renal anemia: a systematic review.J Tradit Chin Med.(2016-Oct)
    33. ^Zeng Q, Wang XH, Yang LP, Lang R, Liang Y, Yu RHShengxuening Oral Iron Supplementation for the Treatment of Renal Anemia: A Systematic Review.J Transl Int Med.(2020-Dec)
    34. ^Kephart JChlorophyll derivatives—Their chemistry? commercial preparation and usesEcon Bot.(1955 Jan)
    35. ^Christiansen SB, Byel SR, Strømsted H, Stenderup JK, Eickhoff JHCan chlorophyll reduce fecal odor in colostomy patients?.Ugeskr Laeger.(1989-Jul-03)
    36. ^BOWERS WFChlorophyll in wound healing and suppurative disease.Am J Surg.(1947-Jan)
    37. ^Smith RGEnzymatic debriding agents: an evaluation of the medical literature.Ostomy Wound Manage.(2008-Aug)
    38. ^Sigler ML, Stephens TJAssessment of the safety and efficacy of topical copper chlorophyllin in women with photodamaged facial skin.J Drugs Dermatol.(2015-Apr)
    39. ^Song BH, Lee DH, Kim BC, Ku SH, Park EJ, Kwon IH, Kim KH, Kim KJPhotodynamic therapy using chlorophyll-a in the treatment of acne vulgaris: a randomized, single-blind, split-face study.J Am Acad Dermatol.(2014-Oct)
    40. ^Kim JE, Hwang JI, Lee JI, Cho BK, Park HJPilot study on photodynamic therapy for acne using chlorophyll: evaluator-blinded, split-face study.J Dermatolog Treat.(2012-Feb)
    41. ^Vasily DBTopical Treatment With Liposomal Sodium Copper Chlorophyllin Complex in Subjects With Facial Redness and Erythematotelangiectatic Rosacea: Case Studies.J Drugs Dermatol.(2015-Oct)