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Open Access Macedonian Journal of Medical Sciences logoLink to Open Access Macedonian Journal of Medical Sciences
. 2019 May 27;7(10):1706–1711. doi: 10.3889/oamjms.2019.322

Physicians’ Perspective on Diabetes Mellitus Management within the Context of Personalized Medicine Era in Tabuk Governorate, Saudi Arabia

Asma Ali Alharbi 1,*, Tariq Mohamed Shaqran 2, Ahmed Abu ELfoutoh Eltobgy 3, Ahmad Raja Albalawi 4, Waad Saad Alnawmasi 1
PMCID: PMC6560294  PMID: 31210827

Abstract

BACKGROUND:

Minimizing the number of therapy failures and decreasing the diabetic complications can be achieved by the application of personalising diabetes therapy, based on patient`s genetics, however, currently, personalised Medicine (PM) in diabetes mellitus management is not extensively applied.

AIM:

To assess the knowledge, attitudes, and willingness of physicians in practising of PM in diabetes management.

METHODS:

A cross-sectional analytical study was implemented among 126 physicians from six different governmental hospitals and 12 primary care centres selected by the stratified random sampling technique in the Tabuk region of Saudi Arabia. A structured self-administered questionnaire was utilised for data collection. A simple scoring system (scale of 5 points) was utilised to assess knowledge and willingness. Likert scale was applied to evaluate the attitudes towards practising PM in DM management by the fixed choice response formats.

RESULTS:

The majority of the participants (97.62%) claimed not receiving any PM and/or genomic medicine training. Most of them (82.54%) expressed unsatisfactory knowledge concerning personalised DM, whereas the medium level of attitudes was reported among 57.14% of them and a good level of willingness had been observed among 76.98% of the physicians.

CONCLUSION:

Emphasizing on essential personalised DM management knowledge aspects should be given a considerable priority. Fortunately, positive attitudes and goodwill of physicians towards PM are encouraging and should be supported by policymakers.

Keywords: Personalized Medicine, Precision Medicine, Diabetes Miletus, Genomics, KAP Studies

Introduction

Diabetes mellitus (DM) is considered one of the biggest worldwide health problems of the 21st century as well as it is a considerable contributor to the morbidity and mortality all over the world caused by the non-communicable diseases. Currently, there are 415 million adults living with diabetes mellitus in different areas of the world, and this is expected to increase by more than 50% over the coming 20 years. In addition to that number, there are 318 million adults with impaired glucose tolerance, which at higher risk of developing diabetes in the future [1], [2]. Saudi Arabia has one of the highest diabetic prevalence (14.4%) country in the world [3]. Also, Saudi Arabia has one of the highest annual incidence rates of type 1 diabetes in children aged 0-14 years, with 31.4 new cases per 100,000 population [4]. Despite the availability of many effective oral therapies to treat diabetes, a considerable percentage of patients do not achieve the required glucose-control rate or may be subjected to adverse effects, from these drugs [5]. Therefore, it is suggested that the response of patients to anti-diabetic therapies is subjected to inter-individual variability, possibly due to genetic factors regarding drug absorption, distribution, and metabolism. Therefore, exploring genetic markers associated with drug reaction can assist physicians with the decisions of drug selection, dose modification, therapy duration, and escaping adverse drug effects [6].

Most of type 2 diabetic patients have polygenetic forms of the disease in which each gene locus shares only a little risk [7]. For example, the association of the E23K variant in KCNJ11 with an increased risk for secondary failure of sulfonylurea in type 2 DM patients explains how a gene can influence the response to a drug [8]. Also, patients with OCT1 polymorphisms (organic cation transporter 1), which is the main port of entry for metformin into hepatocytes and enterocytes have a decreased response to metformin [9]. Fortunately, nowadays, there are many treatment options for diabetes patients that can improve outcomes for many of them. However, there is still a need to define the appropriate treatment for each, since a good number of monotherapy treatments fail within three years and diabetes related-complication and death continue [10], [11]. Therefore, personalising diabetes therapy based on the genetics of patients can reduce the number of treatment failures and decreasing the diabetes-associated complications but, there is a limited implementation of personalised medicine (PM) in treatment of DM [12].

Personalised medicine (PM) involves identifying specific information about a specific patient and then prescribing a drug that is particular for that patient [13]. The National Academy of Sciences (NAS) defined PM as “the use of genomic, epigenomic, exposure and other data to define individual patterns of disease, potentially leading to better individual treatment” [14]. Its goal is to utilise specific information about the patient to specify the appropriate intervention [15]. The intervention could range from a common drug given to several patients to a drug specific for the patient’s genetic profile [16]. Evidence-based support exists for benefits of applying PM for diabetes management in patients with certain monogenic forms of diabetes, and it is expected that applying this strategy for the more common forms of DM will occur with expanding knowledge of polygenic determinants of diabetes [17].

The application of PM in the clinical practice is expected to occur. However, physicians need to be aware of the correct test at the correct time and interpret the test result in the right way and alter their prescription behaviour accordingly. However, we are at an early stage of its application, and a dramatic shift will be needed in the main fields of medical research for this new area of medicine to be fully implemented [18]. Also, numerous challenges in health research exits as there is a need for more understand of the diseases ’mechanisms and translate research results into practice [19].

The study aimed to assess knowledge, attitudes, and willingness of physicians to practice PM in diabetes mellitus management in Tabuk, Saudi Arabia.

Material and Methods

A cross-sectional analytical design has been adopted in this study, which has been conducted in six different governmental hospitals and 12 primary care centres in Tabuk province. The province has an area of 108,000 km² and a population of 791,535 in 2015 [20]; its capital is Tabuk city and composed of six sub-directorates (Tabuk city, Taimaa, Haqel, Duba, Alwajh and Umlujj).

All physicians specialised in internal medicine and/or its diabetic related sub-specialities, namely, endocrinology, paediatrics, community medicine and geriatrics, were included. Physicians who are not providing direct patient care, e.g. administrators and not practising clinical medicine or diabetic related sub-specialities were excluded.

The researchers have followed 3 steps to develop a standardised self-administered questionnaire: The first step was a literature survey of relevant PM studies to identify the pertinent variables and formulating a preliminary questionnaire by the researchers. The second step was taken the opinion of 4 family medicine, and 2 research methodology professors and consultants on the proposed questionnaire in which the nominal group technique has been utilised and then modifications and adjustments have been done. The third step was testing the validity and reliability of the approved questions by the studied experts. Therefore, the studied physicians were asked to respond to a structured 35-items self-administrated questionnaire, designed to evaluate the diabetes management practice variables as related to PM. The independent variables including age, gender, health facility, highest qualification, source of PM awareness, duration of work experience in years and training in PM and/or genomic medicine and dependent variables (knowledge, attitudes and willingness) were selected and revised by five medical research experts. Approximately 20 minutes were needed by the participants to complete it. Ten Knowledge questions with correct or incorrect responses were applied. Assessment of attitude has been based on the Likert scaling method [21] using 10 statements scored as follows: 3 for agreement, 2 for undecided and 1 for disagreement. The total score has been computed by summing the individual scores. Forced-choice response scale (yes or no) was applied to assess willingness degree.

Multi-stage random sampling technique was applied to allocate the physicians. At the first stage, three sub-directorates from Tabuk province (Tabuk city, Taimaa, and Haqel) have been randomly selected by simple random sampling technique. At the second stage, two governmental hospitals and four primary health care centres were selected by the stratified random sampling technique from each sub-directorate. At the third stage, physicians have been selected by systematic random sampling technique. Only, the eligible subjects have been recruited (126 physicians).

Pre-test study has been conducted throughout the first two months in the preparatory phase of the study to: formulate the research problem for more precise investigation, refine the study variables, and test the validity and reliability of the study tools and instruments.

Ethical approval for carrying out the study was obtained from the regional research committee of Tabuk region. Furthermore, all of the study participants were briefly informed that all their personal information would be kept confidential. Refusal to answer any question or withdraw from the study at any time was granted to all participants. They were informed that there was no “correct” or “incorrect” answer, and they were requested to express their opinions and beliefs freely. Their informed consents were taken.

Data entry and analysis were done using the Statistical Package for Social Sciences version 22 (SPSS Inc., Chicago, IL). Arithmetic means and standard deviations were applied to describe continuous data, whereas frequency and percentages were applied for categorical data. Chi-squared tests were utilised to assess the associations between categorical data and unpaired t-test to test for the significant difference between two continuous variables. A p-value of less than 0.05 was considered for statistical significance.

Results

The study included 148 physicians, with a response rate of 85.06%. Physicians who were not in direct contact with patients (n = 6) and/or not practising diabetic management (n = 16) were excluded. Thus, a total of 126 physicians participated in the study. Of the participants, 53.17% and 46.83% were males and females, respectively, as shown in Table (1) with average age and experience years of 37 ± 3.68 and 13 ± 6.42, respectively. Only 9.52% of them have obtained a doctorate or Saudi Board degrees, and surprisingly, 2.38% of them received PM and/or Genomic training. The main source of their PM knowledge (57.14%) was the internet.

Table 1.

General Characteristics of the Studied Physicians

Character Health Facility Total (N = 126)

Hospitals (N = 68) Primary Health Care Centers (N = 58)

No. % No. % No. %
Age (years): Mean± SD 39.46 ± 4.54 34.12 ± 2.68 37.00 ± 3.68
t = 8.17, P< 0.05
Sex:
 Males 41 60.29 26 44.83 67 53.17
 Females 27 39.71 32 55.17 59 46.83
χ2 = 0.34, P>0.05
Highest Qualification:
 MBBS 15 22.06 38 65.52 53 42.06
 Diploma 14 20.59 5 8.62 19 15.08
 Master 28 41.17 14 24.14 42 33.34
 Doctorate or Saudi Board 11 16.18 1 1.72 12 9.52
χ2= 26.62, P< 0.05
Experience years: Mean ± SD 16.16 ± 8.84 9.27 ± 3.57 13 ± 6.42
t = 5.89, P > 0.05
PM and/or Genomic Training:
 Received 3 4.41 - 0.00 3 2.38
 Did not receive 65 95.59 58 100.00 123 97.62
Source of PM Knowledge:
 Internet 39 57.35 33 56.90 72 57.14
 Text books 10 14.71 12 20.69 22 17.46
 Medical journals 11 16.18 4 6.89 15 11.91
 In-service training 5 7.35 7 12.07 12 9.52
 Others 3 4.41 2 3.45 5 3.97
χ2= 0.45, P > 0.05

It’s obvious from Table 2 and Figure 1 that only 11.1% of participants have a good level of knowledge regarding important PM elements in DM management. Also, the fair and poor levels of knowledge among them were 6.4% and 82.5%, respectively.

Table 2.

Personalized DM Medical Knowledge Assessment of the Studied Physicians

Personalised DM Medical Aspect Studied Physicians’ Knowledge (N. 126)

Correct Answer Incorrect Answer

No. % No. %
Definition 7 5.56 119 94.44
Rationale 10 7.94 116 92.06
Vision 8 6.35 118 93.65
Objectives 9 7.14 117 92.86
Components 9 7.14 117 92.86
Clinical Diagnostic Methods 26 20.63 100 79.37
Required laboratory investigations 22 17.46 104 82.54
Recent PM drugs 16 12.70 110 87.30
Most important defective genes 7 5.56 119 94.44
Recent Management Strategies 12 9.52 114 90.48
Overall Assessment: No. %
 Good 14 11.1
 Fair 8 6.4
 Poor 104 82.5

Figure 1.

Figure 1

Overall Assessment of knowledge of Physicians Regarding Personalized Medicine in Diabetes Miletus Management

It’s clear from Table 3 and Figure 2 that nearly more than half (57.1%) of participants have positive attitudes towards important PM aspects in DM management.

Table 3.

Attitudes of the Studied Physicians towards Important Personalized DM Medical Aspects

Personalised DM Medical Aspect Studied Physicians’ Attitudes (N. 126)

Favourable Undecided Unfavourable

No. % No. % No. %
Importance in Medical Progress 79 62.70 41 32.54 6 4.76
Physicians’ Acceptance 102 80.95 20 15.87 4 3.18
Easy Patients’ Accessibility 42 33.33 49 38.89 35 27.78
Current Achievements 48 38.10 50 39.68 28 22.22
Ethical Considerations 82 65.08 27 21.43 17 13.49
Wide Spread Applicability 38 30.15 51 40.48 37 29.37
Medical Curricula Sufficiency 9 7.14 36 28.57 81 64.29
Needed Research 100 79.37 15 11.90 11 8.73
Current High Costs 73 57.93 29 23.02 24 19.05
Future Mapping of Medicine 105 83.33 19 15.08 2 1.59
Overall Attitudes Assessment: No. %
 Favourable 72 57.1
 Un-decided 34 27.0
 Un-favorable 20 15.9

Figure 2.

Figure 2

Overall Assessment of Attitudes of Physicians towards Personalized Medicine in Diabetes Miletus Management

Also, one may notice that 64.29%, 29.37%, 27.78%, 22.22%, and 19.05% of them have an unfavourable attitude towards medical curricula sufficiency, widespread applicability, easy patients’ accessibility, current achievements and current high costs of practising PM in DM management, respectively.

Finally, the results indicate that 77% of participants have a good willingness degree regarding PM practising in DM management, with 90.48%, 82.54%, and 80.95% of them reporting that they agree to practice PM in DM management, looking for training on personalized diabetic management, and intersected in personalized diabetic management practicing, respectively, Table 4 and Figure 3.

Table 4.

Willingness Assessment of the Studied Physicians Regarding Personalized DM Medical Practice

Personalised DM Medical Aspect Studied Physicians’ Willingness (N. 126)

YES NO

No. % No. %
Intersected in PM Practicing 102 80.95 24 19.05
Agree to Practice PM 114 90.48 12 9.52
Ready to Learn PM Practicing Principles 92 73.02 34 26.98
Keen to have PM Practicing Degree 90 71.43 36 28.57
Looking for training on PM 104 82.54 22 17.46
Will search for recent PM topics-as needed 87 69.05 39 30.95
Disseminate PM materials on colleagues 71 56.35 55 43.65
Try to organize PM workshop(s) 48 38.10 78 61.90
Try to attend PM conference(s) 62 49.21 64 50.79
Eager to Practice PM 97 76.98 29 23.02
Overall Enthusiasms’ Assessment: No. %
 Good 97 77.0
 Fair 22 17.4
 Poor 7 5.6

Figure 3.

Figure 3

Overall Assessment of Physicians’ Willingness to Practice Personalized Medicine in Diabetes Miletus Management

Discussion

Because of the multifactorial and complex nature of diabetes mellitus, variability has been reported in the response of patients to most currently available oral hypoglycemics. Therefore, different guidelines recommended using a patient-specific approach and choosing management strategies that provide the patient with the most benefit and the least harm [22].

Despite the existence of several studies investigating diabetes, there is a lack of evidence regarding knowledge, attitudes and practices of physicians and their influence on diabetes and its risk in the community [23].

The World Health Organization (WHO) in 2016 recommended that countries with high diabetic prevalence, as the case in Saudi Arabia have to fight the rise in diabetes prevalence, to minimise diabetes-related premature deaths and to improve access to main diabetes therapies and basic technologies. Such commitment should address the key gaps in the diabetes knowledge base and conduct evaluation studies of innovative programs intended to change attitudes and behaviour [24]. Therefore this study was conducted to explore the knowledge, the extent of positive attitudes, and willingness of physicians to practice PM in diabetes management to provide sound and practical data for diabetic decision makers’ program development.

Personalised treatment of diabetes based on patient genomic can reduce the number of therapy failures and reducing the rate of diabetic-related complications and consequently improve the patients` care [12]. However, in the present study, only 2.38% of surveyed physicians received PM and/or Genomic training.

With many advances in PM on the horizon, the researcher has expected that the PM knowledge of the studied physicians would be satisfactory and increased exponentially. However, the current results showed a considerable very low gap in physicians’ knowledge regarding the basic principles of personalised medicine as only 11.1% of physicians had a good knowledge regarding important personalised diabetic management elements. Also, insufficient knowledge was observed in another study carried among oncologists [25]. However, a better level of knowledge was reported in another study conducted by Chow-White P et al. among oncologists [26].

The practice of PM for diabetes (PMFD) includes 4 processes [27]. First, is the specification of genes and biomarkers for diabetes; Second, is the allocation of resources to early detect or prevent diabetes; Third, is the selection of personalised treatments for affected patients; Fourth, is the measurement of circulating biomarkers of diabetes to evaluate the response to prevention and/or therapy. It is important to notice that the detection of efficiency in anti-diabetic drug development is possible if genetically [28] or nutritionally [29] drug determinants are identified in patients with diabetes. Also, patients who are at high risk for diabetes, as evidenced by genetic testing can be subjected to preventive measures, such as alteration in lifestyle or therapies, to prevent or at least delay the diabetes development [30]. Thus, PM allows prescribing personalised drugs with less time lost with an inappropriate response or with side effects [31]. Unfortunately, in the present study, definition, rationale, vision, objectives, components, recent drugs, most important defective genes and recent management strategies were identified correctly by a minority of physicians.

Despite the lack of knowledge about personalised diabetic management reported among physicians in the present study, they expressed a favourable attitude towards important personalised diabetic management aspects as most of them had a favourable attitude towards physician`s acceptance. However, a considerable proportion of them had a favourable concern regarding high cost and ethical consideration. The results also indicated good willingness degree among physicians regarding personalised diabetic management practising, with the majority of them reported that they agree to practice personalised diabetic management, looking for training on personalised diabetic management, and intersected in personalised diabetic management practising. Recent studies also reported that physicians in the USA perceived their lack the knowledge and skills to incorporate genomic medicine in their practices; despite their positive attitude towards it [32], [33].

The present study has some important limitations. The cross-sectional design was merely descriptive without investigating the factors that could be associated with physicians` knowledge and willingness. Due to the limitations of international studies in that area, we could not sufficiently compare our findings with others. Also, the results were based on a self-administered structured questionnaire (quick, easy, participants answer at their convenience, and cost-efficient but may lack conscientious responses, differences in understanding and interpretation by participants and lack of personalisation). Therefore, carrying out the study only in Tabuk city could impact the generalizability of results. However, the transferability model of generalizability [34] can be adopted and applied in the Tabuk region and the northern parts of Saudi Arabia, given the proximal similarity of such geographical and demographic parts. Finally, we have to realise that both individual- and system-level factors likely contribute to differences by race and ethnicity in use and responses to PM practice as stressed by Kaphingst, and Goodman (2016) [35]. Thus, given the demographic and predominant consanguineous marriage pattern in KSA, it is of great importance to conduct national genomic studies and investigations to determine the needed PM areas for the Saudi population properly.

In conclusion, a high priority should be given to continuing medical education for physicians regarding essential personalised diabetic management knowledge. Additionally, discovering the positive attitudes and favourable willingness of physicians towards the application of PM in patient’s care are promising and should be encouraged by decision makers.

Acknowledgement

The authors would like to thank Dr Tahani Khalil Family Medicine Residency Joint Program director, King Salman Military hospital, Tabuk for her tremendous support in making this project a success.

Footnotes

Funding: This research did not receive any financial support

Competing Interests: The authors have declared that no competing interests exist

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