Dermatology: Practical and Conceptual


Dermatology Practical & Conceptual

Original Article | Dermatol Pract Concept. 2022;12(1):e2022031 1

Comparison of Actinic Keratosis and Severity Index 
with Physician Global Assessment and Total Lesion 

Count and the Ability to Predict Skin Cancer 
Ayda Acar1, Isil Karaarslan1

1 Ege University, Medical Faculty, Department of Dermatology and Venereology, Izmir, Turkey

Key words: actinic keratosis, AKASI, physician global assessment, skin cancer, total lesion count

Citation: Acar A, Karaarslan I. Comparison of actinic keratosis and severity index with physician global assessment and total lesion count 
and the ability to predict skin cancer. Dermatol Pract Concept. 2022;12(1):e2022031. DOI: https://doi.org/10.5826/dpc.1201a31

Accepted: August 14, 2021; Published: January 2022

Copyright: ©2022 Acar and Karaarslan. This is an open-access article distributed under the terms of the Creative Commons  
Attribution-NonCommercial License (BY-NC-4.0), https://creativecommons.org/licenses/by-nc/4.0/, which permits unrestricted 
noncommercial use, distribution, and reproduction in any medium, provided the original authors and source are credited.

Funding: None.

Competing interests: None.

Authorship: All authors have contributed significantly to this publication.

Corresponding author: Ayda Acar, MD, Department of Dermatology, Ege University Faculty of Medicine, University Street Bornova, Izmir, 
Turkey. E-mail: aydaerbas@yahoo.com

Introduction: Actinic keratosis (AK) is a known indicator for sun damage, and subsequent squamous 
cell cancer may develop. The actinic keratosis and severity index (AKASI) is a recently developed tool 
that can evaluate both field cancerization and AK severity. 

Objectives: We sought to evaluate if AKASI was a good predictor of cancer in AK patients and to 
compare AKASI with both the Physician Global Assessment (PGA) and total lesion count (TLC).

Methods: Ninety patients with AK were included in the study. Each patient was examined, and AKs 
were scored with AKASI, PGA and TLC by 2 dermatologists. The AKASI, PGA and TLC values were 
compared between patients with skin cancer and patients without skin cancer. 

Results: Mean AKASI, PGA, and TLC scores were 4.9, 1.7 and 9 respectively. The patients with skin 
 cancer had higher scores of AKASI, PGA and TLC compared to the patients without skin cancer 
(P = 0.022, P = 0.014, P = 0.005, respectively). AKASI, PGA and TLC were very strongly correlated 
with each other (P < 0.001). The AKASI threshold value for non-melanoma skin cancer was  determined 
to be 5.1.

Conclusions: AKASI, PGA and TLC may be used in the assessment of the severity of AK in daily prac-
tice or studies and may be considered as valuable tools in determining high-risk patients and to choose 
treatment option. AKASI seems to have an advantage to give a numeric threshold value for skin cancer.

ABSTRACT



2 Original Article | Dermatol Pract Concept. 2022;12(1):e2022031

Introduction

Actinic keratoses (AK) are hyperkeratotic lesions on sun-dam-

aged skin characterized by atypical epidermal proliferation of 

keratinocytes that have a potential for malignant transfor-

mation to squamous cell carcinoma (SCC). They are gener-

ally asymptomatic, erythematous, or pigmented papules or 

plaques with scales, located on sun-exposed areas like the 

face, scalp, ear helices, and dorsum of the hand [1]. Excessive 

exposure to ultraviolet (UV) radiation is the major cause 

of AK. Fairer skin types, older age, chronic use of systemic 

immunosuppressive drugs, and exposure to arsenic have also 

been described as risk factors [2-4]. In addition to immuno-

suppressive drugs, other drugs, such as voriconazole, calcium 

channel blockers, BRAF inhibitors, hedgehog inhibitors, 

hydroxyurea, and psoralen plus UVA therapy have been 

linked to a higher risk for AK and SCCs [5-8]. On the other 

hand, oral retinoids and nicotinamide have been linked to a 

reduction in the risk of AK and SCC [9]. 

The estimated risk for an individual AK to transform 

into SCC has been reported to be 0.075%-0.096% annually 

[2]. Although most of AKs regress spontaneously or persist 

without a malignant transformation, the major concern is 

the difficulty in estimating which lesion might have a higher 

potential for malignancy. The thickness or hyperkeratosis of 

an individual AK lesion does not have equal SCC progres-

sion risk [10]; thus, treatment is highly recommended for 

each AK lesion. In recent years, the term field cancerization 

(FC), which describes an area of severe sun damage with 

multiple AKs, telangiectasia, wrinkles, dyschromia and elas-

tosis, has been proposed [11] and FC treatment has been 

recommended for a better management of the patients [3]. 

The identification of patients with a higher risk for malig-

nant transformation is another important issue to consider 

when deciding which patients should be included in a closer 

follow-up program. 

There have been some efforts to grade the risk of patients 

with malignant potential. The Physician Global Assessment 

(PGA) scale is a subjective assessment tool that allows the 

physician to evaluate the overall situation of the patient [12]. 

PGA grades AKs in five categories (0: clear, 1: almost clear, 

2: mild, 3: moderate, 4: severe) [12]. The total lesion count 

(TLC), in which physician counts the clinically evident AK 

lesions, is another suggested way to evaluate a patient both 

before and after the therapy [13]. Recently, the actinic kera-

tosis and severity index (AKASI) has been suggested [12]. The 

AKASI supplies a numerical score on an index and evaluates 

both the severity of AK and FC (Table 1) [12]. AKASI has also 

been reported to be useful in monitoring treatment outcomes 

[10]. In AKASI score, the head is divided into 4 regions: scalp, 

forehead, left face (cheek, ear, chin, and nose), and right face. 

The scalp constitutes 40% of the head region, and each of 

the other areas constitutes 20%. For each of the 4 areas, the 

percentage of actinic damage is scored 0 to 6. The most prom-

inent AK distribution, erythema, and thickness are assessed 

from 0-4. The maximum AKASI value is 18. The pivotal study 

proposed an AKASI score of 2.9 as mild, 5.3 as moderate, 8.3 

as severe, 8.7 as very severe [12]. 

Objectives

In the literature, the data on the association between 

non-melanoma skin cancer and AKASI, PGA, and TLC is 

limited [14]. In this study, we sought to evaluate this asso-

ciation and discuss the ability of these methods to predict 

skin malignancy. 

Methods

The study was approved by the local ethics committee (no: 

70198063-050.06.04). Patients with AK, who were referred 

to our dermato-oncology unit within a 6-month period and 

who signed the informed consent form, were involved in 

the study. Patients with a history of photosensitivity, non-

melanoma skin cancer (NMSC)-prone genodermatoses, and 

melanoma were excluded. 

A detailed anamnesis on accompanying diseases, drug 

usage, previous history of NMSC, duration of the present 

lesions, and the Fitzpatrick skin type were recorded. A 

total-body skin and dermoscopic examination were per-

formed for each patient. The patients were examined by 

2 dermatologists at the same time in order to avoid any 

interobserver variability. The AKASI, PGA and TLC values 

were noted. 

Descriptive statistics of the data were given as mean, 

standard deviation, median, minimum, maximum, frequency 

and percentage values. Normality assumption of quantitative 

data was checked by Shapiro-Wilk test. Independent sample 

t-test was used for variables with normal distribution, while 

Mann-Whitney U test and Kruskal-Wallis test (Dunn test 

for paired comparisons) were used for variables that did 

not provide the assumption of normality. The correlation 

of quantitative data with each other was evaluated with 

Spearman Rho correlation coefficient. Relationships between 

categorical variables were examined using the Pearson 

Chi-square test. A receiver operating characteristic (ROC) 

analysis was used to determine a cutoff point for diagnostic 

methods. Statistical analysis was performed using IBM SPSS 

Statistics 25.0 (IBM SPSS Statistics for Windows, Version 

25.0, IBM) package program. The significance level was set 

at 0.05 in all analyses.



Original Article | Dermatol Pract Concept. 2022;12(1):e2022031 3

Table 1. Definition of Components of Actinic Keratosis Area and Severity Index (AKASI) and How to 
Calculate AKASI Score*

Evaluation of AKASI [12]

AKASI Components Definitions

Solar damage (SD) Head is divided to 4 areas: scalp (S), forehead (F), right half of the face (R), left half of 
the face (L). 
Skin with solar damage for each of the 4 areas is estimated and scored 0-6. 
0 (0%), 1(1-9%), 2(10-29%), 3(30-49%), 4(50-69%), 5 (70-89%), 6 (90-100%). 

Distribution of AK (D) 0 No AK

1 Isolated or scattered AK

2 Clustered (Small clusters up to 25 cm2)

3 Clustered and confluent (AKs are coalescing in a cluster of <25 cm2) 

4 Confluent (AKs are coalescing and cannot be easily distinguish)

Erythema of AK (E) 0 No erythema

1 Slight red

2 Moderate red

3 Intense red

4 Very intense red

Thickness of AK (T) 0 No palpable or visible AK

1 Just palpable AK

2 Clearly palpable

3 Thickened

4 Very thickened

Total AKASI score 
(0-18)

0.4 x (D+E+T+SD of scalp) + 0.2 x (D+E+T+SD of forehead) + 0.2 x (D+E+T+SD of right 
face) + 0.2 x (D+E+T+SD of left face)

*Adapted from the report of Dirschka et al [12].

AK = actinic keratosis; AKASI = actinic keratosis area and severity index.

Results

A total of 90 patients were involved in the study. Fifty-four 

patients (60%) were males. The age range was 48-87 years 

(mean age was 69 years and median age was 71). The accom-

panying diseases were hypertension (43%), diabetes mellitus 

(27%), coronary arterial disease (CAD) (14%), solid organ 

malignancy (13%), inflammatory or autoimmune skin dis-

eases (13%), solid organ transplantation (6%) and others 

(asthma, vertigo, Parkinson disease, migraine, gut, essential 

thrombocytosis, familial Mediterranean fever, hepatitis B) 

(10%). Fourteen patients (16%) were receiving calcium 

channel blockers, 9 patients (10%) were receiving immuno-

suppressive drugs, and 1 patient was receiving hydroxyurea. 

The distribution of Fitzpatrick skin type was as follows: 73 

patients (81%) had Fitzpatrick skin type II and 17 patients 

(19%) had type III. The duration of the present AK lesions 

ranged from 2 months to 30 years. The mean duration was 

7 years. Mean AKASI was 4.9, mean PGA was 1.7 and mean 

TLC was 9.3. Mean AKASI was 6 in male patients and 3 

in female patients. The difference between male and female 

patients was statistically significant (P < 0.001). Mean PGA 

was 2 in male and 1 in female patients. Mean TLC was 11 in 

male and 7 in female patients. The difference between male 

and female patients of PGA and TLC was statistically signif-

icant (P < 0.001, P = 0.002).



4 Original Article | Dermatol Pract Concept. 2022;12(1):e2022031

Fifty-one patients (57%) did not have any current skin 

cancer or skin cancer history. A total of 39 patients (43%) 

had a current skin cancer and/or past history of skin cancer. 

Among them, 28 patients (31.1%) had only previous skin 

cancer history, 8 patients (8.8%) had only concurrent skin 

cancer, and 3 patients (3.3%) had both concurrent skin cancer 

and previous skin cancer history. Nineteen patients (21.1%) 

had only basal cell carcinoma (BCC) and BCC count was 26. 

Thirteen patients (14.4%) had only SCC and SCC count was 

21. Seven patients (7.7%) had both SCC and BCC, tumor 

count was 29 (11 for SCC and 18 for BCC). One patient 

who had both BCC and SCC also had 2 basosquamous cell 

carcinomas. Total tumor count was 78 (44 for BCC, 32 for 

SCC, and 2 for basosquamous cell carcinoma). In all but 7 

patients all the tumors were located on the face or scalp. In 

7 patients, 14 tumors (8 BCCs and 6 SCCs) were located on 

an extremity or trunk. None of the patients had skin cancer 

metastasis. 

All items were compared between the group with 

previous or present skin cancer (Group A, n = 39) and 

the group with no history of skin cancer (Group B, n = 

51) (Table 2). The mean age in group A was 70 years 

(median 73 years), and the mean age in group B was 69 

years (median 70 years). The mean age of the patients 

was higher in the group with skin cancer, but it was not 

statistically significant (P = 0.261). Mean and median 

AK duration was longer in the group A (mean 9, median 

9) compared to the group B (mean 6, median 5). Hav-

ing longer AK duration in the group A was statistically 

significant (P = 0.009). The distribution of demographic 

features and scores of AKASI, PGA and TLC in the two 

groups are shown in Table 2. There was no statistically 

significant relationship between having skin cancer and 

gender (P = 0.794), or accompanying diseases. However 

statistically significant relationship was found with not 

having CAD (P = 0.028). AK duration was significantly 

related with AKASI, PGA and TLC scores (P = 0.038, 

P = 0.010, P = 0.016). Mean and median AKASI, PGA 

score and TLC were higher in group A (mean 6, median 

6; mean 2, median 2; and mean 11, and median 11, 

respectively) compared to group B (mean 4, median 4; 

mean 2, median 1 and mean: 8, and median 7, respec-

tively) (Table 2). The higher scores of AKASI, PGA and 

TLC in group A were statistically significant (P = 0.022,  

P = 0.014, P = 0.005). 

Nineteen patients with high risk drugs or diseases for 

skin cancer had higher AKASI scores and it was statistically 

significant (P = 0.033). These patients had also higher mean 

PGA and TLC values, which were not statistically significant 

(P = 0.077, P = 0.221).

Patients were also grouped as no skin cancer (group 

I, n = 51 patients), patients with only BCC (group II, n 

= 19 patients), patients with only SCC (group III, n = 13 

patients), and patients with both BCC and SCC (group IV, 

n = 7 patients). Mean AKASI score, PGA, and TLC were 

highest in group IV. The ranking of mean values of scores 

was: group III, II, and I respectively. The increase in the mean 

values of AKASI, PGA, and TLC from group I to group IV 

was statistically significant (P = 0.026, P = 0.026, P = 0.038). 

The total number of skin cancer counts (previous and present) 

were not related with AKASI, PGA, and TLC (P = 0.064, P = 

0.075, P = 0,149). 

AKASI, PGA, and TLC were correlated with each 

other (P < 0.001). Correlation between AKASI and PGA, 

between AKASI and TLC, and between PGA and TLC were 

very strong (r = 0.881, r = 0.893, r = 0.849). As a result of 

ROC analysis, the AKASI threshold value for total NMSC 

was determined to be 5.1 (P = 0.022, area = 0.642). The 

AKASI thresholds for SCC and BCC according to ROC 

analysis were 5.5 (P = 0.056, area = 0.682) and 6.9 (P = 

0.926, area = 0.509), respectively. Total NMSC threshold 

value was statistically significant. However, threshold val-

ues for only BCC or only SCC groups were not statistically 

significant. 

Table 2. Comparison Between the Group with Previous or Present Skin Cancer (Group A) and the 
Group with No History of Skin Cancer (Group B).

Group A Group B

Male percent 62% 59%

Mean and median age 70, 73 69, 70

Mean and median AK duration (years) 9, 9 6, 5

Mean and median AKASI 6, 6 4, 4

Mean and median PGA 2, 2 2, 1

Mean and median TLC 11, 11 8, 7

AK = actinic keratosis; AKASI = actinic keratosis area and severity index; PGA = Physician Global Assessment; TLC = total 
lesion count.



Original Article | Dermatol Pract Concept. 2022;12(1):e2022031 5

Conclusions

In order to determine the malignant transformation risk in 

AK, there is a need for scoring the disease extent and overall 

severity rather than evaluating the individual lesion. PGA 

and TLC have been used for determining the severity of AK. 

Recently, in 2017, AKASI was proposed by Dirschka et al 

[12]. In 2018, Pellacani et al compared AKASI with TLC [13] 

and found AKASI a reproducible method that can be used in 

clinical trials as an alternative to TLC. Although no significant 

difference was found between AKASI and TLC in the interob-

server variability, AKASI had a slightly higher intra-class cor-

relation coefficient compared to TLC. They stated that either 

of the 2 methods could be used [13]. In 2018, Schmitz et al 

investigated the association between AKASI and keratinocytic 

tumors [14]. They concluded patients with SCC had a higher 

AKASI score compared to patients with BCC, Bowen disease 

or AK solely [14]. Schmitz et al suggested that the AKASI 

score of 3 is consistent with mild, 5.5 moderate, 8.5 severe, 

and > 11 very severe AK. Their estimated AKASI score for 

invasive SCC development was found to be 7, median AKASI 

scores of 4.8, and 7.1 and PGA 2 and 2.5 in patients with BCC 

and SCC respectively [14]. Additionally, AKASI was used in 

studies evaluating AK treatment outcomes [10, 15-18].

In 2017, Dréno et al [19] recommended the actinic kerato-

sis field assessment scale (AK-FAS) to evaluate the severity of 

AK and sun damage, as AK-FAS evaluates AK area percent-

age, hyperkeratosis and sun damage. The AK area is graded as 

I-IV (< 10%, 10%-25%, > 25%-50%, and > 50%) according 

to percentage of AK covering the face or scalp. Hyperkera-

tosis and sun damage are assessed as absent or present [19]. 

In 2019, AKFAS together with AKASI was used in a study 

of both dermoscopic and reflectance confocal microscopic 

evaluation of AK before and after imiquimod therapy [15]. 

We preferred to use AKASI over AK-FAS because AK-FAS 

does not provide a numerical value as AKASI does. 

In the present study, the median AKASI, PGA, and TLC 

values were found to be significantly higher in patients with 

NMSC compared with patients without NMSC. These values 

were highest in the patients who had both BCC and SCC and 

in the patients who had SCC alone. Additionally, AKASI, 

PGA, and TLC were well correlated. The AKASI threshold 

value for NMSC was determined to be 5.1; male patients had 

significantly higher AKASI, PGA, and TLC scores compared 

to female patients. The patients with current skin cancer or 

skin cancer history had significantly longer AK duration, 

higher AKASI, PGA, and TLC scores compared to patients 

without skin cancer or history of skin cancer. Patients who 

had an immunosuppressive condition (drugs, solid organ 

transplantation, and systemic malignancy) had significantly 

higher AKASI scores compared to patients without an immu-

nosuppressive condition.

Our study employed AKASI, PGA and TLC to assess the 

severity of AK and to evaluate the relationship with malig-

nancy risk. We conclude that AKASI, PGA, and TLC may be 

used in the assessment of the severity of AK in daily practice 

or studies. Although a longer period is needed for calcula-

tion of AKASI, it seems advantageous to have a numerical 

threshold value for skin cancer. This is the second study that 

evaluates this threshold value in the literature. To establish a 

common value, more studies are needed. 

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