Relationship between ABO Blood Groups and Susceptibility to Dental Caries and Periodontitis: A Narrative Review

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Relationship between ABO Blood Groups and Susceptibility to Dental Caries and Periodontitis: A Narrative Review

Majed AbuKhader1 , * Open Modal Amal Abdulbaqi1 Polyxeni Petropoulou2 Abubaker Qutieshat2
Authors Info & Affiliations
The Open Dentistry Journal 02 Oct 2025 DOI: 10.2174/0118742106419798250925021418
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Abstract

Introduction

Oral health significantly impacts overall well-being. Emerging research has focused on systemic factors, including ABO blood groups, as potential influencers of oral disease susceptibility. The purpose is to understand the potential physiological and/or immunological association between the ABO blood groups and susceptibility to periodontal diseases and dental caries. This might aid in developing early diagnostic and treatment strategies for these conditions based on the individual ABO blood group.

Methods

This review synthesizes findings from cross-sectional studies published between 2015-2025, exploring the association between ABO blood types and susceptibility to dental caries and periodontitis, and examining immunological and physiological mechanisms underpinning these relationships. A set of inclusion and exclusion criteria was adopted to ensure proper search, sound evaluation, and conclusions.

Results

A systematic search of the major databases identified 29 relevant cross-sectional studies involving diverse populations, of which 21 studies discussed the ABO blood group association with periodontitis.

Discussion

Findings indicated that individuals with blood group AB exhibited an increased risk of developing dental caries, while those with blood group O were at higher risk of developing periodontitis. Possible explanations include the presence of salivary immunoglobulins (IgA, IgM, IgG), the ABO antigen secretion status, or the combination of both. Although these associations were significant, blood groups alone do not conclusively determine disease development. Additional factors, such as oral hygiene, dietary habits, ethnicity, and genetics, play critical roles.

Conclusion

In-depth research including various confounders is needed to provide a comprehensive conclusion. Findings reported here can have practical implications in dental practice by incorporating blood group data into the patient assessment profile in dental screenings.

Keywords: ABO blood group, Immunoglobulins, Salivary antigens, Periodontitis, Dental caries, Oral health, Salivary immunoglobulins.

1. INTRODUCTION

Oral health plays an important role in maintaining general personal satisfaction and quality of life. Therefore, oral diseases pose a major public health concern, with dental caries and periodontal diseases being among the most common avoidable oral diseases worldwide. Dental caries are one of the most prevalent oral diseases and are characterized by enamel demineralization. They can be arrested and potentially reversed in their early stages but are often not self-limiting, and without proper care, caries can progress until the tooth is destroyed [1]. Periodontitis is the main cause of tooth loss, which occurs due to inflammatory disruption of periodontal tissues. It is caused by excessive immune responses to bacteria in subgingival dental plaque, leading to loss of periodontal integrity, impaired tooth function, and eventually tooth loss [1, 2]. These oral disorders are associated with many factors, such as aging, orthodontic needs, exposure to fluoride, and exposure to preventive measures [1].

The ABO blood grouping system was discovered by Austrian scientist Karl Landsteiner, who observed that the red blood cells of some individuals agglutinated with serum from others. He documented agglutination patterns in which he created the ABO blood grouping and divided individuals into three blood type groups: ‘A’, ‘B’, and ‘O’. Later, another blood type group, ‘AB’, was identified [3, 4]. Landsteiner, along with his colleague Alexander Wiener, also developed the Rh system in 1937, based on the presence or absence of the Rh (Rhesus factor) antigen (D antigen) [5]. The blood type has importance in transfusion medicine, paternity suits, forensic science, and the study of different populations by anthropologists. The ABO system, comprising blood groups A, B, AB, and O, is determined by antigens that are found on the red blood cell surface and usually referred to as ABO antigens. These antigens are represented by terminal sugar moieties added to the oligosaccharide chain structure, so that fucose represents the H antigen, N-acetylgalactosamine (GalNAc) represents the A antigen, and galactose represents the B antigen. Thus, individuals with blood group O express the H antigen, individuals with blood group A express the A antigen, those with blood group B express the B antigen, and those with blood group AB express both A and B antigens [6, 7]. The ABO antigens are associated with the blood cell structure, but many individuals secrete these antigens freely in their body fluids, such as saliva, mucus, and semen. These individuals are called secretors, as they release their antigens into their bodily fluids. Those who do not secrete their antigens in different liquids other than blood are non-secretors. Research has shown that the presence or absence of the ABO antigens in the saliva may affect the capacity of microscopic organisms residing in the oral cavity to adhere to tooth surfaces, potentially affecting the development of oral diseases [8, 9]. In addition to the fact that saliva plays an important role in optimal oral health, new research suggests that salivary pH is more significant in the development and progression of oral diseases than previously thought [10].

The global distribution of the ABO system indicates that blood group O is the most common worldwide, followed by blood groups A, B, and AB. Certain varieties have been associated with specific regions/countries: blood group O has been reported in European, American, and Canadian populations, blood group B in the people of the Indian subcontinent, and blood group A in Chinese and Japanese populations [3, 8]. The Rhesus factor (Rh), which is always associated with the ABO system, was reported to be Rh-positive (Rh+) in about 85% of the global population, with varying percentages reported across countries (Kenya: 96%; India: 99%; Iran: 90%; and Turkey: 87%) [11].

Several systemic health conditions have been found to be associated with blood type differences [12]. For example, individuals with blood group A have been reported to be more prone to gallstones, colitis, and tumors of the salivary glands, pancreas, and ovary. Meanwhile, it was suggested that blood group B and non-O blood groups are at risk of ischemic heart disease and might be prone to coronary atherosclerosis [1, 13]. Investigation into the relationship between blood groups, the Rhesus (Rh) factor, and dental diseases started in 1930. Richard Thompson was the first to investigate blood groups and susceptibility to dental caries in 1931, while Weber and Pastern were the first to study the association of ABO blood groups with periodontal disease [14-17]. There was a decent number of research studies reporting the association between ABO blood grouping and oral health, which investigated various aspects of this relationship, including periodontal diseases, dental caries, malocclusion, oral infections, and oral cancer [18]. This review is intended to summarize the research done in relation to periodontal diseases and dental caries in the past 10 years, from 2015 to 2025. The outcome of this review will provide a collective view on the factors that may influence the relationship between ABO blood grouping and oral health, periodontal diseases, and dental caries in particular. Knowledge of the ABO blood groups of patients and their association with periodontal diseases and dental caries is very important, and this can help in the development of early diagnosis and treatment strategies for such diseases.

2. METHODS

The search strategy was adopted from a similar work done by Ghani Ur Rehman, and it was modified and outlined in this section [19]. The literature search was conducted in March 2025 using online databases, including Google Scholar, PubMed/Medline, ScienceDirect, and EBSCO, to explore the association between ABO blood grouping and periodontal diseases and dental caries. The publication period of articles was set from 2015 to 2025. Databases were searched by using Boolean operators (i.e., and/or/not) in combination with a group of keywords, such as periodontal diseases, dental caries, ABO blood groups, oral health, and periodontitis. English versions of papers describing clinical studies, cross-sectional studies, case reports, and retrospective studies on the subject were considered for inclusion. Historical reviews, meta-analyses, articles with unpublished data, and letters to the editors were excluded. Studies investigating the association between ABO blood group and other oral conditions, such as oral cancer, oral infections, oral ulcers, and malocclusion, were also excluded. Moreover, the Rhesus factor was not considered in this review analysis. Titles and abstracts were screened for relevance. Initial screening yielded 45 articles, but with critical analysis of the full text of the articles and applying exclusion criteria based on low sample size (i.e., less than 100 participants) and lack of significant association between ABO blood group and oral health, 29 articles were included. These articles were summarized into two tables: one table lists the articles investigating the association between ABO blood group and periodontal diseases, and the other table lists the articles investigating the association between ABO blood group and dental caries. Reference lists in all full-text articles were hand-screened to identify additional relevant original research articles.

3. REVIEW AND DISCUSSION

The search retrieved twenty-nine articles, summarized in Tables 1 and 2. The following sections review and discuss the information presented in these tables.

Table 1.
Studies investigating the association between ABO blood groups and dental caries.
No. Author and Year of Publication Ref. Location Methods Sample
Size 		ABO
Group 		Strength of Correlation
1 Almalki et al. (2024) [15] Saudi Arabia Dental caries were assessed using the WHO-modified criteria on the DMF-Index (Decayed, Missing, Filled Teeth) and the DMFS (Decayed, Missing, Filled Surfaces) index. 300 AB Significant
2 Kadhum, et al. (2015) [20] Iraq Decayed (D), missing (M), and filled (F) teeth were detected following the criteria described by the WHO. 250 AB Significant
3 Alkhayoun et al. (2019) [21] Iraq Oral examination was done under standardized conditions according to the basic methods of oral health surveys of WHO using DMFS. 209 AB Significant
4 Singla et al. (2015) [22] India DMFT index was recorded and calculated. 150 A and B Significant
5 Govindaraju et al. (2018) [23] India The decayed, extracted, and filled deciduous tooth status of the children was assessed by a pediatric dentist. 500 AB Significant
6 Yadav et al. (2018) [24] India Dental caries were recorded using the DMFT Index. 315 B Significant
7 Mazumdar et al. (2022) [25] India DMFT index was used. DMFT scores were categorized into 3 sets depending on the severity of dental caries: DMFT = 1-5, DMFT = 6-10, DMFT = above 10. 198 O Significant
8 Jogi et al. (2024) [26] India Data for the dental caries status were recorded by measuring the number of decayed permanent teeth as per the WHO 1997 criteria. 335 O Significant
Table 2.
Studies investigating the association between ABO blood groups and periodontal diseases.
No. Author and Year of Publication Ref. Location Methods Sample
Size 		ABO Group Strength of Correlation
1 Azab and Aljefari (2022) [29] Libya A manual periodontal probe (Williams periodontal probe) was used. The presence of plaque, gingival bleeding, clinical attachment level (CAL), and probing pocket depth (PPD) were clinically assessed. 200 O Significant
2 Kouki et al. (2019) [30] Syria Clinical attachment loss ≥4 mm and periodontal pocket depth ≥4 mm were set as indicators for periodontitis. Radiographic bone loss was also used as an indicator in the assessment. 1009 O Significant
3 Mostafa et al. (2019) [31] Saudi Arabia Probing pocket depth (PPD) and clinical attachment loss (CAL) were measured using a periodontal probe (UNC-15). CAL was categorized as: mild = 1-2 mm, moderate = 3-4 mm, and severe = ≥5 mm. 205 O Significant
4 Farshori et al. (2020) [32] Saudi Arabia Oral cavities were thoroughly examined for the presence of dental caries, gingivitis, periodontitis, and tooth decay or tooth loss. 860 O Significant
5 Al-Bahrani (2021) [33] Iraq Patients were divided into localized and generalized chronic periodontitis. Clinical indicators used were: alveolar crest level >2 mm below the CEJ and periodontal pocket depth >4 mm. 200 O Significant
6 Ramamoorthy et al. (2015) [34] India Patients already diagnosed with chronic periodontitis, who had at least 20 teeth excluding third molars, with blood grouping records. 410 O, B Significant
7 Dhalkari et al. (2016) [35] India Ramfjord’s periodontal index (PDI) was used. At least one site with attachment loss >3 mm and periodontal pocket depth >4 mm were used as indicators for periodontitis 200 O Significant
8 Anup et al. (2016) [36] India Periodontitis subjects exhibited CAL = 3 mm in two or more nonadjacent teeth or CAL = 5 mm in ≥30% of teeth. 684 O Significant
9 Bhuse et al. (2017) [37] India Clinical attachment loss >1-2 mm and periodontal pocket depth >4 mm were used as indicators for periodontitis 300 O Significant
10 Kaul et al. (2017) [38] India Ramfjord’s Periodontal Index was used with 4 grades: Grade 0: 0-0.16, Grade I: 0.17-0.5, Grade II: 0.6-1.5, Grade III: 1.6-3.0, Grade IV: ≥3.1. 875 A Significant
11 Kokane et al. (2018) [39] India Clinical attachment loss >3 mm and periodontal pocket depth >4 mm were used as indicators for periodontitis. 288 B Significant
12 Puri et al. (2018) [40] India Mean clinical attachment loss ≥5 mm and periodontal pocket depth 5–7 mm were used as indicators for periodontitis 272 O Significant
13 Chawan et al. (2018) [41] India Clinical attachment loss ≥3 mm and periodontal pocket depth ≥5 mm were used as indicators for periodontitis. 300 O Significant
14 Mahantesha et al. (2018) [16] India PPD and CAL were measured using UNC-15 periodontal probe. Subjects were divided into 2 groups: Group 1: CAL and PPD <3 mm and no radiographic bone loss; Group 2: CAL ≥3 mm and PPD ≥4 mm. 100 B Significant
15 Bhardwaj and Chopra (2019) [42] India William’s periodontal probe was used. PPD ≥5 mm in >30% of sites was used as an indicator for chronic periodontitis. 500 B Significant
16 Singhal et al. (2023) [43] India William’s periodontal probe was used to examine the periodontal status (PPD). 1425 O Significant
17 Changela et al. (2023) [44] India Community Periodontal Scores (CPI) were recorded using the CPI probe (Hu-Freidy) with a 0.5 mm ball tip. Healthy gingival group (CPI score 0), Gingivitis group (CPI scores 1 & 2), and Periodontitis group (CPI scores 3 & 4). 350 O Significant
18 Aamir Khan et al. (2024) [3] India PPD and CAL were measured using UNC-15 periodontal probe. Criteria: CAL 1-2 mm = Mild chronic periodontitis; CAL 3-4 mm = Moderate chronic periodontitis; CAL ≥5 mm = Severe chronic periodontitis. 100 B Significant
19 Saito et al. (2024) [6] Japan The Community Periodontal Index (CPI) was used to evaluate periodontal status using gingival bleeding and pocket depth scores. 2374 AB Significant
20 Moghadam et al. (2025) [45] Iran Assessments included evaluation of GI, PPD, CAL, and bleeding on probing. 368 B Significant
21 Chrysanthakopoulos (2021) [46] Greece Clinical attachment loss ≥6 mm in at least 2 teeth and periodontal pocket depth ≥5 mm in more than one site were used as indicators for periodontitis. 854 A Significant

3.1. Association of ABO Blood Group with Dental Caries

There were 8 articles that investigated the association of ABO blood groups with dental caries in different populations in India, Iraq, and Saudi Arabia, as shown in Table 1. These cross-sectional studies were conducted in various settings, including dental clinics, dental colleges, and schools. The research methodology followed in these studies was based on the DMFT (Decayed, Missing, and Filled Teeth) index, which has been used as a reference to assess oral health. It is widely used by the World Health Organization (WHO) for comparing and measuring dental caries in individuals. The index expresses the mean number of DMFT in individuals whose DMFT index is taken. The outcome reported in all 8 articles suggests that individuals with blood group AB are at high risk of developing dental caries.

In the five studies conducted in India, the sample size ranged from 150 to 500 participants, and the following reported outcomes in these studies were as follows: Two studies reported a significant association between blood group O and dental caries; one study reported a significant association between blood group B and dental caries; one study reported a significant association between blood group AB and dental caries; and one study reported a significant association between blood group A and B and dental caries. In the Indian population studied, the common ABO blood groups reported were O and B. This is consistent with what was reported in India, where blood group O is common, although studies have found that blood group B is common in Northern India, while blood group O is more prevalent in South India [27].

Three studies were conducted in the Arabian Peninsula: two studies in Iraq and one study in Saudi Arabia. The sample size ranged from 209 to 300 participants, and they reported a significant association between blood group AB and dental caries. In both Iraqi and Saudi populations, the common ABO blood group reported was O. This suggests that participants with blood group O may be less susceptible to dental caries but potentially more susceptible to other types of oral diseases.

Looking into the reported outcomes presented in the above studies, the association between ABO blood grouping and dental caries appears to be influenced by ethnicity. Arabs and Indians have different physiological attributes, which could be linked to their blood group type and susceptibility to dental caries. In the Arab population, individuals with blood group AB are more at risk of developing dental caries, despite being the least represented in the studied sample. There are several possible explanations for the above outcome: 1- Decreased salivary flow rate in individuals with blood group AB. The salivary flow rate plays an important role in relation to dental caries because the washing action of saliva, as well as its protective constituents, increases with a high flow rate. 2- Increased concentration of salivary alkaline phosphatase among individuals with blood group AB, as variations in alkaline phosphatase levels cause changes in phosphate levels, which lead to the initiation and progression of caries. 3- Total protein in the oral cavity, as increased concentration may have a protective role. 4- The absence of AB antigens (non-secretor) and/or antibodies in the saliva, which may lead to the development of dental caries [25]. In the Indian population, individuals with blood groups O and B are more at risk of developing dental caries, possibly due to the antigenic or carbohydrate structure of blood groups expressed in individuals’ saliva in the oral cavity. It was reported that blood group-specific sugars and several other sugars have a complex connection with the blood group antigens and the inhibition of bacterial aggregation. Salivary inhibition of bacterial aggregation was observed with GalNAc (A antigen), which is specific for blood group A, whereas it was not observed in the case of galactose (B antigen), which is specific for blood group B, and fucose (H antigen), which is specific for blood group O. This, as a result, explains the findings above that blood groups O and B have higher dental caries prevalence [21, 28].

3.2. Association of ABO Blood Group with Periodontal Diseases

There were 21 articles that investigated the association of ABO blood groups with periodontal diseases in different populations in India, Iraq, Saudi Arabia, Syria, Iran, Japan, and Greece, as shown in Table 2. These cross-sectional studies were done in various settings, including dental clinics, dental colleges, and schools. The research methodology followed in these studies was based on appropriate clinical measurements using a manual periodontal probe. Plaque, gingival bleeding, Clinical Attachment Level (CAL), and Probing Pocket Depth (PPD) were examined and assessed clinically for each participant. As only 8 studies examined multiple parameters beyond the periodontal index, such as plaque and gingival indices, this review focused on data related to the association of ABO blood groups with periodontitis. Various probing methods were used to assess periodontitis, including William’s probing, Ramfjord′s periodontal index, and UNC-15. In most of the above studies, PPD was set at ≥ 5 mm, and CAL was set at > 3 mm.

The number of studies conducted in India to investigate the association of ABO blood groups with periodontitis was almost 61.9% (13 studies) of the total number of related studies (see Table 2). This is possibly because periodontitis is considered a pandemic in some states in India, with a prevalence rate reaching 85% of the population [47]. The outcomes reported in these 13 studies indicate that individuals with blood group O are at risk of developing periodontitis, and the reported association was strong. Studies done in Indian and Arab populations (Saudis, Syrians, Libyans, and Iraqis) indicated that individuals with blood group O are at risk of developing periodontitis. Studies involving Asians (Japanese and Iranians) and other populations (Europeans) reported an association of various blood groups with the risk of developing periodontitis.

The outcome of these studies does not emphasize, although a strong association was detected, that blood groups are conclusive evidence as an etiological factor for causing dental caries and/or periodontal disease. There are other proven etiological factors, like poor oral hygiene, frequent consumption of sugary or acidic foods and drinks, and insufficient fluoride exposure [48, 49]. Additionally, factors like inadequate saliva flow and genetic predispositions can increase susceptibility to oral health diseases and carry more weight than blood groups in assessing cases [50].

3.3. Salivary ABO Antibodies, ABO Antigens and Oral Health

Periodontitis and dental caries were often regarded as two independent diseases and studied separately based on the pathogenic bacteria involved and their clinical manifestations. However, there were studies that investigated the association between periodontitis and dental caries, with some showing an inverse association and others showing a positive association between these two diseases [51]. A systematic review done by Li et al., which covered literature until 2023, aimed to conduct a robust critical appraisal of the evidence on the relationship between periodontitis and dental caries. The authors concluded that periodontitis and dental caries are not independent variables and both have a positive and significant correlation. The pooled results of all the included studies indicated that patients with periodontitis had a higher risk of developing dental caries. At the bacterial level, however, the main bacterial species associated with each disease have a distinct pathological profile: Mutans streptococci (especially Streptococcus mutans) and Lactobacillus have long been recognized as pathogens that are associated with dental caries, while Porphyromonas gingivalis, Fusobacterium nucleatum, Actinobacillus actinomycetemcomitans, and others are associated with periodontitis progression [51, 52]. These bacteria are found in the oral cavity, where saliva is one of the main elements of the oral cavity environment. Saliva is an extracellular fluid produced and secreted by salivary glands in the mouth. As a vital fluid of the oral cavity, it plays an important and beneficial role in balancing the mouth and its components, which may affect personal health status. ABO antigens and ABO antibodies are present in the saliva through certain mechanisms, and they are essential contributors to the immunity of the oral cavity by preventing the adherence of bacteria (such as those causing dental caries and periodontitis), neutralizing viruses, enzymes, and toxins, or by acting in synergy with other factors such as lactoferrin and lysozyme [53, 54].

Individuals are classified as ‘secretors’ and ‘non-secretors’ based on their ability to secrete water-soluble ABO antigens (ABH) in saliva.

Table 3.
Summary of ABO antibodies, antigens, and associated risks for dental caries and periodontitis.
Blood Group ABO Antibodies in Saliva ABO Antigen in Saliva Risk of Dental Caries Risk of Periodontitis
O Anti A Antibody
Anti B Antibody		 H antigen
(D-Fucose)		 Low risk High risk
AB No antibodies Antigen A
(N-acetyl Galactosamine)
Antigen B
(D-galactose)		 High risk Low risk
B Anti A Antibody Antigen B
(D-galactose)		 High risk High risk
A Anti B Antibody Antigen A
(N-acetyl Galactosamine)		 Low risk Low risk

The secretion of these antigens is controlled by the fucosyltransferase (FUT) secretor gene, located on the short arm of chromosome number 19, in the form of two alleles denoted as dominant “Se” and recessive “se.” In their pattern of inheritance, SeSe and Sese produce a dominant secretor phenotype, while sese produces a recessive non-secretor phenotype. Therefore, individuals of blood group O secrete only the H antigen; those with blood group A secrete A and H antigens, while those with blood group B secrete B and H antigens in their saliva. It is generally known that about 80% of the world’s population are secretors (Se gene) of ABH antigens, and only 20% are non-secretors [10, 55].

Immunoglobulins IgA, IgM, and IgG class-specific ABO antibodies, also referred to as anti-A antibodies and anti-B antibodies, are detected in saliva and serve as major immunological defense on mucous membranes and are produced locally. According to Schönbacher et al. (2023), in a cohort of healthy individuals, IgA was the most abundant ABO antibody class in saliva, followed by IgM and IgG [54]. Alkhayoun et al. detected the levels of IgA, IgM, and IgG in saliva samples collected from individuals of blood groups O, A, B, and AB. They found that the level of salivary IgA varies among the blood groups, which was significant, with the highest level found in blood group O, followed by blood group A, blood group B, and the lowest level in blood group AB [21].

Taking into account all the information discussed above, the following findings can be listed and summarized in Table 3:

1- Healthy individuals with blood group O are at low risk of developing dental caries and at high risk of developing periodontitis. One explanation could be that a high amount of IgA in the saliva of these individuals is effective in preventing S. mutans from causing dental caries. On the other hand, the H antigen increases the risk of P. gingivalis and P. intermedia causing periodontitis.

2- Healthy individuals with blood group AB are at high risk of developing dental caries and at low risk of developing periodontitis. One explanation could be that a negligible amount of IgA in the saliva of these individuals is not effective against S. mutans in causing dental caries. On the other hand, the A antigen and B antigen in the saliva promote the clearance of P. gingivalis and P. intermedia from the oral cavity, preventing periodontitis development.

3- Healthy individuals with blood group B are at high risk of developing dental caries and periodontitis. One explanation could be that both the low amount of IgA in the saliva of these individuals and the presence of the B antigen are not effective against S. mutans, P. gingivalis, and P. intermedia in causing dental caries and periodontitis.

4- Healthy individuals with blood group A are at low risk of developing dental caries and at low risk of developing periodontitis. One explanation could be that there is a high amount of IgA in the saliva of these individuals, which is effective in preventing S. mutans from causing dental caries. On the other hand, the A antigen in the saliva promotes clearance of P. gingivalis and P. intermedia from the oral cavity, preventing periodontitis development.

4. REVIEW LIMITATIONS AND FUTURE DIRECTIONS

Due to the fact that this current review is narrative in nature and provides a preliminary overview of the literature, implementing a quality assessment framework such as ROBINS-I or the Newcastle-Ottawa Scale would be useful to evaluate the risk of bias in included studies. This narrative review can be used as a platform to conduct a future systematic review study adopting the PRISMA approach on this topic to systematically validate the quality and reliability of the work findings and conclusions.

CONCLUSION

The findings presented in this review were based on 29 research articles and were confined to a specific population in a specific geographical area. Therefore, more studies are warranted to support the findings of this review and to address the effects of oral health practices, gender, age, geographical location, and race on the association between ABO blood grouping and oral diseases such as dental caries and periodontitis. These findings can be used as a preliminary guide in dental practice to develop and introduce risk stratification based on a patient’s blood group in dental screenings.

AUTHORS’ CONTRIBUTIONS

The authors confirm contribution to the paper as follows: M.A.: Concept; M.A., A.Q., A.A., P.P.: Data Collection and/or Processing; M.A., A.Q.: Analysis and/or Interpretation; M.A., A.Q.: Literature Search; M.A, A.Q.: Writing Manuscript; A.Q., A.A., P.P.: Critical Review. All authors reviewed the results and approved the final version of the manuscript.

LIST OF ABBREVIATIONS

DMFT = Decayed, Missing, and Filled Teeth
WHO = World Health Organization

CONSENT FOR PUBLICATION

Not applicable.

FUNDING

None.

CONFLICT OF INTEREST

The authors declar no conflict of interest, financial or otherwise.

ACKNOWLEDGEMENTS

The authors gratefully acknowledge the generous support of the National University of Science and Technology and Oman Dental College in facilitating the publication of this work.

REFERENCES

1
Frencken JE, Sharma P, Stenhouse L, Green D, Laverty D, Dietrich T. Global epidemiology of dental caries and severe periodontitis – A comprehensive review. J Clin Periodontol 2017; 44(S18): S94-S105.
2
Balkrishna A, Singh K, Sharma A, et al. ABO blood group phenotypes and dental disorders-Is there any relation? A cross sectional study in Haridwar, Uttarakhand, India. J Oral Health Oral Epidemiol 2021; 10(3): 122-7.
3
Khan MA, Lal N, Chandra T, Ali W, Ismail H. Association of ABO phenotype, Rhesus factor, platelet count and hemoglobin level with oral hygiene status and severity of chronic periodontitis. J Oral Biol Craniofac Res 2024; 14(6): 730-4.
4
AlSihli H, Elmarsafy SM, Afifi IK. Correlation of dental caries with ABO blood group and salivary secretor status among female subjects, Makkah City, Saudi Arabia. Int J Health Sci Res 2018; 8: 85-93.
5
Schwarz HP, Dorner F. Karl Landsteiner and his major contributions to haematology. Br J Haematol 2003; 121(4): 556-65.
6
Saito M, Shimazaki Y, Yoshii S, Kojima T. Association between ABO blood type and periodontal disease: A cross-sectional study. Res Sq 2024; 4: 1-12.
7
Branch DR. Anti‐A and anti‐B: What are they and where do they come from? Transfusion 2015; 55(S2): S74-9.
8
Banoosh S. The relation of ABO blood groups with some oral diseases. Tikrit J Dent Sci 2018; 6: 52-7.
9
Prasanna S, Kumar AR, Kumar KR, Ramya R, Dinesh S. ABO grouping & its implication in oral diseases. Indian Dent Assoc Madras Branch 2020; 3: 9-12.
10
Salih K, Jouda J, Al-jaff S, El-Haboby BT. Frequency of ABO blood groups and secretor status and their relation with dental decay in sections of students and employees of Al-Mustansiriyiah University, Iraq. World J Exp Biosci 2015; 3: 108.
11
Aravind T, Neela N, Mannava P, et al. Evaluation of correlation between periodontitis and ABO blood grouping- A clinical study. J Adv Med Dent Sci Res 2019; 4(4): 78-82.
12
Abegaz SB. Human ABO blood groups and their associations with different diseases. BioMed Res Int 2021; 2021(1): 6629060.
13
Patel R, Patel K, Patel H, Shah H. ABO blood group and periodontitis: Correlation and no correlation. Ann Int Med Dent Res 2016; 2(1): 251-4.
14
Mahajan NM, Kohad RM. Association between ABO blood groups and periodontal diseases. JISP 1998; 1: 62-3.
15
Almalki S, Gowdar I, Arishi F, Alhumaidani R, Alhumaidani F, Gufran K. Association between ABO blood group, dental caries, gingivitis, impacted teeth and malocclusion among Saudi adults: A cross-sectional study. Clin Cosmet Investig Dent 2024; 16: 371-9.Association Between ABO Blood Group.
16
Mahantesha S, Mv SM, Ashwini S, St AB, Ct RA. The interrelationship between ABO blood group with periodontal disease among Bangalore population: A cross-sectional. Int J Curr Adv Res 2018; 7: 7-10.
17
Thompson R. Blood groups and susceptibility to dental caries. Exp Biol Med 1931; 29(1): 106.
18
Singh A, Purohit B. ABO blood groups and its association with oral cancer, oral potentially malignant disorders and oral submucous fibrosis– A systematic review and meta-analysis. Asian Pac J Cancer Prev 2021; 22(6): 1703-12.
19
Rehman GU. Association of ABO blood grouping and periodontal disease: A literature review. Dent J Adv Stud 2021; 9(3): 116-20.
20
Kadhum RF, Diab BS, Ban S. ABO blood type in relation to caries experience and salivary physicochemical characteristic among college students at Al-Diwania Governorate in Iraq. J Baghdad Coll Dent 2015; 27(4): 125-31.
21
Alkhayoun JD, Saleem MA, Abdulla WL. Dental caries and salivary immunoglobulin A in relation to ABO blood type and Rh factor among dental students aged 20-21 years old. J Res Med Dent Sci 2019; 7: 123-8.
22
Singla S, Verma A, Goyal S, Singla I, Shetty A. Correlation of dental caries and blood group in Western Punjab population in India. Indian J Multidiscip Dent 2015; 5(2): 59-61.
23
Govindaraju L, Jeevanandan G, Subramanian EG. ABO blood grouping: A potential risk factor for early childhood caries - A cross-sectional study. Indian J Dent Res 2018; 29(3): 313-6.
24
Yadav K, Solanki J, Dileep CL, Adyanthaya BR, Mishra P, Yadav O. Association between different blood groups, depression and oral health status of dental students. Clujul Med 2018; 91(3): 317-21.
25
Mazumdar P, Saha T, Mukherjee S, Roy S. Association between ABO blood group and dental caries in 19-59 years age group of suburban population of north Kolkata, west Bengal: A cross sectional study. Int J Curr Res 2022; 14: 1-4.
26
Jogi NK, Naveen N, Singh J, Sharma A, Matsyapal C. Correlation between blood groups and dental caries among 12-15years school children in Bilaspur, Chhattisgarh: A cross-sectional study. Afr J Biol Sci 2024; 6: 2412.
27
Periyavan S, Sangeetha SK, Marimuthu P, Manjunath BK, Seema DN. Distribution of ABO and Rhesus-D blood groups in and around Bangalore. Asian J Transfus Sci 2010; 4(1): 41.
28
Campi C, Escovich L, Moreno A, et al. Expression of the gene encoding secretor type galactoside 2 α fucosyltransferase (FUT2) and ABH antigens in patients with oral lesions. Med Oral Patol Oral Cir Bucal 2012; 17(1): e63-8.
29
Azab AE, Aljefari HMM. Prevalence of oral health problems and distribution according to socio-demographic variables and blood groups among patients in the Tripoli Region. Trends J Sci Res 2022; 1(1): 1-15.
30
Kouki MA, Sulaiman AA, Kouki MT, Alsabbagh MM. Investigation of ABO Blood groups in periodontal status and its effect on level of response to nonsurgical periodontal treatment. J Clin Diagn Res 2019; 13: 36.
31
Mostafa D, Elkhatat EI, Koppolu P, Mahgoub M, Dhaifullah E, Hassan AH. Correlation of ABO blood groups and Rh factor with the severity of generalized chronic periodontitis: A cross-ectional Study in Riyadh, Saudi Arabia. Open Access Maced J Med Sci 2019; 7(4): 617-22.
32
Farshori MP, Alanazi A, Alshammari M, Alanazi A. Prevalence of Gingivitis and Periodontitis in Saudi adult male population and the ABO blood group distribution. J Dent Res Pract 2020; 2(2): 1.
33
AlBahrani Z. Association between ABO blood group and Radiographic findings in periodontal disease. Med-Leg Update 2021; 21(2): 1293-8.
34
Ramamoorthy B, Varghese SV, Ramesh A. Relationship between periodontal disease and ABO blood group phenotypes-A cross sectional retrospective study. Int J Pharm Pharm Sci 2015; 7(11): 386-8.
35
Dhalkari CD, Indurkar M, Ingle K, Nayyar AS. Association of Periodontal Disease and ABO blood groups: A cross-sectional study. Sch Bull 2016; 2(11): 605-8.
36
Anup P, Siddhartha V, Girish S, Keshava A. ABO and Rh blood group system and periodontal disease - A prevalence study. J Adv Med Med Res 2016; 16(5): 1-6.
37
Bhuse KJ, Shetty D, Shetty A, Dharmadhikar S. Evaluation and comparison of the association between ABO blood groups and severity of chronic periodontitis. Int J Curr Res 2017; 9: 46712.
38
Kaul M, Agarwal S, Agarwal V, Modinagar P. An exploring link to periodontitis: ABO blood group and Pedodontics. Int Joural Curr Res 2017; 9(4): 48812-6.
39
Kokane NB, Gupta B, Agrawal V, Kokane V, Sharma A, Anand R. Association of ABO Blood group and Rh factor with periodontal disease in adult population Of Greater Noida: A cross-sectional study. IOSR J Dent Med Sci 2018; 17(3): 65-9.
40
Puri SS. Relationship between human ABO blood groups and periodontal diseases. Int J Sci Appl Res 2018; 5(4): 8-13.
41
Chawan S, Babu C, Manohar J, Reddy H, Chavan V, Manaswini M. Association of severity of periodontal disease in population with different blood groups. Scholars Acad J Biosci 2018; 6: 28.
42
Bhardwaj A, Chopra P. To determine and correlate the chronic periodontitis status and blood groups in two major ethnic groups of Indian Population. J Evol Med Dent Sci 2019; 8(52): 3920-5.
43
Singhal P, Bhat GK, Chanu TB, Rajendra GS, Setia S. Prevalence of periodontal disease in various ABO blood groups – An epidemiological study. Natl Res Denticon 2023; 12(4): 37-43.
44
Changela R, Khatri M, Patel N, Verlianey N, Panwar S, Vachhani J. Evaluation of association between human ABO blood groups and periodontal diseases. Int J Sci Res 2023; 12: 16-8.
45
Moghadam S, Hoseinbor S, Bamedi M, Ranjbaran A. Association of ABO blood groups and Rh factor with periodontal disease prevalence in a population from Saravan, Iran. Zahedan J Res Med Sci 2025; 27(1): e158043.
46
Chrysanthakopoulos N. ABO blood group system and periodontal disease indices: A cross-sectional study in Greek adults. Asploro J Biomed Clin Case Rep 2021; 4(2): 132-44.
47
Shewale AH, Gattani DR, Bhatia N, Mahajan R, Saravanan SP. Prevalence of periodontal disease in the general population of India-A systematic review. J Clin Diagn Res 2016; 10(6): ZE04-9.
48
Aripin D, Suwargiani A, Wardani R, Susilawati S. oral hygiene instruction – How it affects the caries experience, oral hygiene status, and sCD14 levels? Open Den J 2022; 16(1)
49
Li T, Ma L, Yan Y, et al. Dental caries and associated factors in Tibetan School-Age Children in Gannan, China. Int Dent J 2025; 75(2): 643-51.
50
Fujihara C, Hafiyyah OA, Murakami S. Identification of disease-associate variants of aggressive periodontitis using genome-wide association studies. Jpn Dent Sci Rev 2023; 59: 357-64.
51
Li Y, Xiang Y, Ren H, et al. Association between periodontitis and dental caries: A systematic review and meta-analysis. Clin Oral Investig 2024; 28(6): 306.
52
Boehlke C, Rupf S, Tenniswood M, Chittur SV, Hannig C, Zierau O. Caries and periodontitis associated bacteria are more abundant in human saliva compared to other great apes. Arch Oral Biol 2020; 111: 104648.
53
Feller L, Altini M, Khammissa RAG, Chandran R, Bouckaert M, Lemmer J. Oral mucosal immunity. Oral Surg Oral Med Oral Pathol Oral Radiol 2013; 116(5): 576-83.
54
Schönbacher M, Banfi C, Berghold A, et al. Immunoglobulin class profiles of ABO antibodies in saliva and serum of healthy individuals. Transfus Med Hemother 2023; 50(4): 294-302.
55
Mahjaf GM, Altaher TA, Nouraldein M, Hamad M. Detection of ABO IgA immunoglobulin, saliva from a healthy Sudanese individual at Khartoum state in 2023. Excell J Med Sci 2024; 5(1): 24-7.