Aging underlies heterogeneity between comorbidity and multimorbidity frameworks.

Studies exploring differences between comorbidity (i.e., the co-existence of additional diseases with reference to an index condition) and multimorbidity (i.e., the presence of multiple diseases in which no one holds priority) are lacking. In this single-center, observational study conducted in an academic, internal medicine ward, we aimed to evaluate the prevalence of patients with two or more multiple chronic conditions (MCC), comorbidity, or multimorbidity, correlating them with other patients' characteristics. The three categories were compared to the Cumulative Illness Rating Scale (CIRS) comorbidity index, age, gender, polytherapy, 30-day readmission, in-hospital and 30-day mortalities. Overall, 1394 consecutive patients (median age 80 years, IQR 69-86; F:M ratio 1.16:1) were included. Of these, 1341 (96.2%; median age 78 years, IQR 65-84; F:M ratio 1.17:1) had MCC. Fifty-three patients (3.8%) had no MCC, 286 (20.5%) had comorbidity, and 1055 (75.7%) had multimorbidity, showing a statistically significant (p < 0.001) increasing age trend (median age 38 years vs 71 vs 82, respectively) and increasing mean CIRS comorbidity index (1.53 ± 0.95 vs 2.97 ± 1.43 vs 4.09 ± 1.70, respectively). The CIRS comorbidity index was always higher in multimorbid patients, but only in the subgroups 75-84 years and ≥ 85 years was a significant (p < 0.001) difference (1.24 and 1.36, respectively) noticed. At multivariable analysis, age was always independently associated with in-hospital mortality (p = 0.002), 30-day mortality (p < 0.001), and 30-day readmission (p = 0.037), while comorbidity and multimorbidity were not. We conclude that age determines the most important differences between comorbid and multimorbid patients, as well as major outcomes, in a hospital setting.

Introduction

Although the prevalence of patients with multiple chronic conditions (MCC) is rising worldwide [1, 2], research on this topic still needs to fill in some important gaps of knowledge [3, 4]. New standardized definitions are needed so as to allow comparisons and meta-analyses [5], and it has been proposed that the concepts of comorbidity and multimorbidity should not be used interchangeably and that a distinction is desirable [2, 3, 6]. This is not a matter of semantics, given that the lack of a clear distinction has hampered the development of high-quality studies addressing these issues [2, 7]. In line with this view, specific Medical Subject Headings (MeSH) were recently designated to distinguish comorbidity from multimorbidity, which are now being used in scientific search engines as different MeSH [8, 9]. More in detail, comorbidity indicates the combined effects of additional conditions in reference to a single index chronic disease under study, whereas multimorbidity is defined as the co-occurrence in the same individual of multiple diseases in which no single disease holds priority [10, 11]. So, while comorbidity focuses on a single condition among many, multimorbidity describes the disease burden as a whole, and it has been theorized that this distinction may translate into specific treatment choices [12]. For instance, different principles of exercise have recently been outlined for patients with either comorbidity or multimorbidity [13]. There is no doubt, however, that in real life some overlaps may be unavoidable, and that a sharp distinction will have to be based more on ad hoc studies rather than on systematic reviews. In this regard, we herein aim at classifying MCC into comorbidity or multimorbidity frameworks and correlating the results with demographic and clinical outcomes in a large series of patients consecutively admitted to an academic internal medicine ward. The significance of differentiating comorbidity from multimorbidity will then be discussed.

Material and methods

Data from consecutively enrolled adult patients in the San MAtteo Complexity (SMAC) study, a large ongoing prospective research project on clinical complexity (NCT03439410) conducted in November 2017-November 2019 at our Institution, were analyzed. The follow-up of these patients is still ongoing, with the aim of validating a recently developed clinical complexity index [14-16].

The San Matteo Hospital Foundation, an academic hospital of Northern Italy, serves a population of ~ 550,000 people, and most patients (> 90%) access the Emergency Department before admission. In the SMAC study, adult patients admitted to our internal medicine unit were included, regardless of the cause of admission. The details of the enrolment have already been described elsewhere [17]. Demographic (i.e., age, gender) and clinical data (i.e., polypharmacy, body mass index [BMI], frailty according to the Edmonton Frail Scale [18], length of stay, in-hospital and 30-day mortalities, 30-day readmission) were collected, including the Cumulative Illness Rating Scale (CIRS) [19], a common tool for assessing MCC in clinical studies [20]. Assuming that the correct selection of such a tool should depend on the outcomes under investigation [20, 21], we embraced the CIRS because of its ability to predict mortality and hospital stay and readmission [22]. Diseases were identified and categorized according to the International Classification of Diseases (ICD; 9th revision). In particular, the whole ICD9 chapter was used for categorization (e.g., chapter 2, neoplastic diseases; chapter 3, endocrine, nutritional and immunological diseases; etc.…).

All patients with MCC, defined as the simultaneous presence of at least two chronic conditions, were either classified into a comorbidity or a multimorbidity framework, strictly according to the MeSH definitions. Comorbidity was defined as the co-existence of additional diseases with reference to an index condition [8] while multimorbidity as the presence of multiple diseases in which no one holds priority [9]. Recognized complications of an index disease (e.g., ascites, hepatic encephalopathy in liver cirrhosis) were considered associated conditions in respect to an index disease, and thus classified as comorbidities [23]. The absence of chronic diseases, or the presence of only one chronic condition -also defined by the appropriate MeSH [24]- were categorized as “no MCC”. Practically, an expert academic physician (MVL), who was unaware of patients’ age, gender, and outcomes, partitioned all patients into one of these three categories, following the abovementioned criteria. All anonymous demographic and clinical data were retrieved from the dedicated REDCap database. As practical and representative examples, patients in whom (i) a univocal etiopathogenic link for disease clustering was noticed (e.g., alcohol abuse causing liver cirrhosis and its consequences, or obesity causing metabolic syndrome) or (ii) a clear clinical priority was evident (e.g., recent onset of a neoplastic disease in a patient with mild essential hypertension), were categorized as comorbid. Instead, patients with (i) unrelated MCC (e.g., asthma, autoimmune thyroid disease, Parkinson’s disease) with no clear risk factors, or (ii) MCC with multiple risk factors (e.g., obesity, tobacco smoking, alcohol abuse), where categorized as having multimorbidity. Finally, cases in which it was not possible to clearly categorize the patient into one of the two categories (i.e., the actual presence of an index disease was uncertain), according to the MeSH criteria, were considered as having multimorbidity. Prior to study commencement, a random sample of 25 patients within each category were categorized and reviewed by three other physicians with different experience, to verify whether any discordance existed. The agreement among the observers was > 90%.

As the primary aim, the three categories (no MCC, comorbidity, and multimorbidity) were compared to the CIRS comorbidity index. As a secondary aim, other correlations included age, gender, polytherapy, length of stay, CIRS severity index, 30-day readmission, in-hospital and 30-day mortalities. The study was approved by the local ethics committee (Protocol number 2017/0019414) and all patients provided written informed consent. All data generated or analyzed during this study are included in this published article.

Statistical analysis

For the purpose of this study, the sample size was not calculated a priori. However, the sample size (n = 1000) was based on the primary aim of the SMAC study. Continuous data were described with mean and standard deviation or median and interquartile range (IQR; i.e., 25th–75th percentiles), and categorical data were described as counts and percent. They were compared between patients’ categories with the Kruskall–Wallis test and the Fisher exact test, respectively. Data were analyzed with generalized linear models to adjust for age the association of patients’ category with the CIRS comorbidity and severity indices. Differences between categories and 95% CI were retrieved from the model. The interaction of age and patients’ categories was assessed and subgroup analyses by age categories were performed. Hospital mortality, 30-day mortality, and 30-day readmission were analyzed with logistic models. Multivariable models for these outcomes were fitted, where the choice of covariates was decided a priori based on clinical considerations. Among the covariates, we also included the index disease (comorbidity framework) or the reason for hospital admission (multimorbidity framework or no MCC) according to the main chapters of the International Classification of Diseases (ICD; 9th revision). A two‐sided p < 0.05 was considered statistically significant. For post-hoc comparisons, p < 0.017 was set for significance (Bonferroni correction). All analyses were performed using Stata 16 (StataCorp, College Station, TX, USA).

Results

Overall, 1394 consecutive patients (median age 80 years, IQR 69–86; F:M ratio 1.16:1) enrolled in the SMAC study were included. Of these, 1341 (96.2%; median age 78 years, IQR 65–84; F:M ratio 1.17:1) had two or more MCC and were categorized as either comorbid or multimorbid. Although the comparison between patients with MCC (n = 1341) and no MCC (n = 53) was very unbalanced, significant differences were noticed (Supplementary Table 1). In brief, patients with MCC displayed a higher median age (80 vs 38 years), mean CIRS comorbidity index (3.85 vs 1.53), mean CIRS severity index (1.78 vs 1.32), polypharmacy (72.7% vs 0%), median length of stay (14 vs 9 days), and 30-day mortality (12.9% vs 3.8%).

Demographic and baseline clinical characteristics of the entire cohort according to the presence of no MCC, comorbidity, or multimorbidity are reported in Table 1. Notably, most patients were categorized as having multimorbidity (1055, 75.7%), and a statistically significant (p < 0.001) increasing age was noticed, namely no MCC (median age 38 years), comorbidity (median age 71 years), and multimorbidity (median age 82 years). Moreover, the distribution of age groups significantly differed (p < 0.001) both among the three categories and within each category. In particular, the prevalence of multimorbidity significantly increases (p < 0.001) with increasing age, while the opposite significant trend (p < 0.001) was noticed for comorbidity. Although the median number of chronic conditions did not statistically differ between multimorbid (6, IQR 5–8) and comorbid patients (4, IQR 3–5), the CIRS comorbidity index (mean 4.09 vs 2.97) and the CIRS severity index (mean 1.82 vs 1.63) were significantly higher (p < 0.001) in multimorbid vs comorbid patients. Similarly, the intake of ≥ 5 medications was significantly more prevalent (p < 0.001) in multimorbid vs comorbid patients (78.7% vs 50.9%). Differently, after the Bonferroni correction, the distribution of the BMI did not differ (p = 0.043) between comorbid and multimorbid patients.

Table 1

Demographic and baseline clinical characteristics of the 1394 patients included in the study according to the presence of no multiple chronic conditions (MCC), comorbidity, or multimorbidity

					Post-hoc comparisons
	No MCC (I)	Comorbidity (II)	Multimorbidity (III)	p value	p value (I vs II)	p value(I vs III)	p-value(II vs III)
No. of patients, n (%)	53 (3.8)	286 (20.5)	1055 (75.7)	-	-	-	-
Female gender, n (%)	25 (47.2)	153 (53.5)	571 (54.1)	0.610	-	-	-
Age, median (years; IQR)	38 (30–57)	71 (57–81)	82 (75–87)	< 0.001	< 0.001	< 0.001	< 0.001
Age groups, n (years; %)				< 0.001	< 0.001	< 0.001	< 0.001
18–64	42 (79.3)	105 (36.7)	116 (11.0)	-	-	-	-
65–74	4 (7.5)	59 (20.6)	142 (13.5)	-	-	-	-
75–84	6 (11.3)	81 (28.3)	398 (37.7)	-	-	-	-
≥ 85	1 (1.9)	41 (14.4)	399 (37.8)	-	-	-	-
CIRS comorbidity index, mean (SD)	1.53 (0.95)	2.97 (1.43)	4.09 (1.70)	< 0.001	< 0.001	< 0.001	< 0.001
CIRS severity index, mean (SD)	1.32 (0.22)	1.63 (0.26)	1.82 (0.28)	< 0.001	< 0.001	< 0.001	< 0.001
EFS > 5, n (%)	51 (3.6)	115 (8.2)	268 (19.2)	< 0.001	< 0.001	< 0.001	< 0.001
Intake ≥ 5 medications, n (%)	0 (0)	145 (50.9)	830 (78.7)	< 0.001	< 0.001	< 0.001	< 0.001
BMI class, n (%)				0.003	0.069	0.004	0.043
< 18.5	6 (11.3)	31 (10.8)	65 (6.1)	-	-	-	-
18.5–24.9	36 (67.9)	142 (49.7)	517 (49.0)	-	-	-	-
25–29.9	7 (13.2)	71 (24.8)	309 (29.3)	-	-	-	-
≥ 30	4 (7.6)	42 (14.7)	164 (15.6)	-	-	-	-

Significance after the Bonferroni correction is set at p < 0.017. Post-hoc comparisons are in italics

BMI, Body Mass Index; CIRS, Cumulative Illness Rating Scale; EFS, Edmonton Frail Scale; IQR, interquartile range; MCC, multiple chronic conditions; SD, standard deviation

The correlates of the CIRS comorbidity index with patients’ categories are reported in Table 2. In all models, the category “no MCC” was considered as “base”. In the unadjusted model, patients with multimorbidity had a significantly greater CIRS comorbidity index compared to those with comorbidity. We then assessed the interaction of age and patients’ categories in a model including both the main effects and the interaction proving a significant effect modification (p < 0.001). For this reason, the association of the CIRS comorbidity index with patients’ categories was assessed by age groups. When adjusting the analysis for age groups, despite the CIRS comorbidity index turning out to be always higher in multimorbid patients, only in the subgroups 75–84 years and ≥ 85 years was a significant difference (1.24 and 1.36, respectively; p < 0.001) noticed. The same trend was observed when using the CIRS severity index as the dependent variable (Supplementary Table 2). In particular, patients with multimorbid patients had a significantly greater CIRS severity index compared to comorbid patients and only in the subgroups 75–84 years and ≥ 85 years was a significant difference (0.51 and 0.38, respectively; p < 0.001) noticed.

Table 2

Correlates of the CIRS comorbidity index in the entire cohort of patients

	CIRS comorbidity index (mean; SD)	Difference (vs no MCC)	95% CI	p value	Multi- vs comorbidity	p value
Unadjusted model				< 0.001
No MCC	1.53 (0.95)	0
Comorbidity	2.97 (1.43)	1.44	1.13–1.74	< 0.001
Multimorbidity	4.09 (1.70)	2.56	2.29–2.84	< 0.001	1.12 (0.89–1.36)	< 0.001
Subgroup analysis (p for interaction < 0.001)
Subgroup for age 18–64 (N = 263)
No MCC		0
Comorbidity		1.22	0.83–1.62	< 0.001
Multimorbidity		1.66	1.23–2.08	< 0.001	0.43 (-0.007–0.12)	0.93
Subgroup for age 65–74 (N = 205)
No MCC		0
Comorbidity		1.81	1.17–2.44	< 0.001
Multimorbidity		2.32	1.75–2.89	< 0.001	0.52 (-0.08–1.12)	0.113
Subgroup for age 75–84 (N = 485)
No MCC		0
Comorbidity		1.42	0.49–2.35	0.003
Multimorbidity		2.66	1.75–3.57	< 0.001	1.24 (0.84–1.64)	< 0.001
Subgroup for age ≥ 85 (N = 441)
No MCC		0
Comorbidity		0.85	0.39–1.31	< 0.001
Multimorbidity		2.22	2.06–2.38	< 0.001	1.36 (0.77–1.96)	< 0.001

Differences between categories are computed using a generalized linear model

CI, confidence interval; CIRS, Cumulative Illness Rating Scale; MCC, multiple chronic conditions

The median length of stay was significantly lower (9 days, IQR 7–13) for patients with no MCC compared to the other groups (p < 0.001), while no difference was noticed between comorbid (14 days, IQR 9–23) and multimorbid (14 days, IQR 10–21) patients. Overall, 267 patients died, of whom 92 (6.6%) during the hospital stay and 175 (12.5%) within 30 days after discharge. Table 3 shows the odds ratio for in-hospital and 30-day mortality and 30-day readmission in patients with comorbidity compared to multimorbidity (no MCC was again considered as base). Of patients who died in hospital, 2 (3.8%) had no MCC, 22 (7.7%) had comorbidity, 68 (6.4%) had multimorbidity (p = 0.527), while of patients who died within 30 days after discharge, 2 (3.8%) had no MCC, 43 (15.0%) had comorbidity, and 130 (12.3%) had multimorbidity (p = 0.068). Additionally, 207 patients (14.8%) were readmitted to the hospital within 30 days after discharge. Of these, 6 (11.7%) had no MCC, 44 (22.7%) had comorbidity, and 157 (21.9%) had multimorbidity (p = 0.213). Hence, no differences emerged regarding in-hospital mortality and 30-day readmission, while comorbidity was significantly associated with 30-day mortality (OR 4.51, p = 0.042).

Table 3

Odds ratio for in-hospital mortality, 30-day mortality, and 30-day readmission in patients with comorbidity vs multimorbidity, derived from a logistic model

		Odds ratio	95% CI	p value
In-hospital mortality	N (%)			0.533
No MCC	2 (3.8)	1
Comorbidity	22 (7.7)	2.12	0.48–9.32	0.318
Multimorbidity	68 (6.4)	1.76	0.42–7.37	0.441
30-day mortality				0.088
No MCC	2 (3.8)	1
Comorbidity	43 (15.0)	4.51	1.06–19.23	0.042
Multimorbidity	130 (12.3)	3.58	0.86–14.90	0.079
30-day readmission				0.227
No MCC	6 (11.7)	1
Comorbidity	44 (22.7)	2.20	0.88–5.50	0.091
Multimorbidity	157 (21.9)	2.11	0.88–5.03	0.093

CI, confidence interval; MCC, multiple chronic conditions

The multivariable analysis for the outcomes in-hospital mortality, 30-day mortality, and 30-day readmission outcomes are reported in Table 4. No differences were noticed for the comorbidity and multimorbidity categories and for gender. Regarding age, groups 75–84 and ≥ 85 were significantly associated with greater odds for in-hospital mortality (4.82 and 6.15, respectively) and 30-day mortality (3.42 and 6.20, respectively). An active oncological disease was present in only one (1.9%) patient with no MCC, in 88 patients (30.8%) with comorbidity, and in 81 patients (7.7%) with multimorbidity (data not shown in the Table). When considering the specific ICD9 chapters, only chapter 2 (oncological diseases) maintained its significance after the Bonferroni correction (odds ratio 2.59; p < 0.001) for 30-day mortality. Regarding the 30-day readmission outcome, no differences were noticed among the three categories no MCC, comorbidity, and multimorbidity, as well as no gender differences having emerged. Polypharmacy was significantly associated with increased odds for 30-day readmission (OR 1.34), as well as the ICD9 chapter 2 (OR 4.23), even after the Bonferroni correction (p < 0.001).

Table 4

Multivariable analysis for the outcomes of the study

In-hospital mortality	OR	95% CI	p-value	30-day mortality	OR	95% CI	p-value	30-day readmission	OR	95% CI	p-value
Patient category			0.084	Patient category			0.043	Patient category			0.159
No MCC	1			No MCC	1			No MCC	1
Comorbidity	0.60	0.12–3.05	0.541	Comorbidity	1.34	0.29–6.24	0.708	Comorbidity	0.97	0.36–2.63	0.951
Multimorbidity	0.32	0.06–1.64	0.172	Multimorbidity	0.73	0.16–3.41	0.692	Multimorbidity	0.86	0.32–2.31	0.763
Gender				Gender				Gender
Male	1			Male	1			Male	1
Female	0.80	0.52–1.24	0.315	Female	0.82	0.59–1.15	0.253	Female	0.77	0.56–1.07	0.115
Age group (years)			0.002	Age group (years)			< 0.001	Age group (years)			0.037
18–64	1			18–64	1			18–64	1
65–74	2.12	0.66–6.83	0.207	65–74	2.25	1.02–5.00	0.045	65–74	1.59	0.90–2.80	0.111
75–84	4.82	1.75–13.31	0.002	75–84	3.42	1.68–6.97	0.001	75–84	2.01	1.20–3.38	0.008
≥ 85	6.15	2.17–17.42	0.001	≥ 85	6.20	3.01–12.78	< 0.001	≥ 85	2.17	1.24–3.79	0.007
Intake ≥ 5 medications	1.33	0.99–1.80	0.061	Intake ≥ 5 medications	1.23	0.99–1.52	0.056	Intake ≥ 5 medications	1.34	1.09–1.64	0.005
ICD9 of index disease or cause of admission			0.517	ICD9 of index disease or cause of admission			< 0.001	ICD9 of index disease or cause of admission			< 0.001
2	1.11	0.47–2.62	0.810	2	*2.59	1.31–5.12	0.006	2	*4.23	2.16–8.28	< 0.001
3	1.16	0.39–3.50	0.786	3	1.15	0.44–2.97	0.780	3	0.49	0.19–1.27	0.144
4	1	/	/	4	0.25	0.06–1.16	0.077	4	0.63	0.26–1.56	0.318
7	0.69	0.33–1.46	0.334	7	0.85	0.45–1.61	0.624	7	0.71	0.40–1.27	0.252
8	0.92	0.42–2.02	0.840	8	1.62	0.85–3.08	0.143	8	0.82	0.43–1.56	0.555
9	0.29	0.08–1.08	0.066	9	0.45	0.17–1.22	0.117	9	1.08	0.55–2.13	0.829
10	0.96	0.31–2.94	0.945	10	1.36	0.55–3.35	0.509	10	0.46	0.16–1.35	0.158
17	0.83	0.27–2.51	0.735	17	1.14	0.46–2.79	0.781	17	1.39	0.62–3.12	0.427

CI, confidence interval; ICD9, international classification of diseases 9; MCC, multiple chronic conditions; OR, odds ratio

*Still significant after the Bonferroni correction (p < 0.001). ICD9 chapters nomenclature: 2, Infectious and Parasitic Diseases; 3, Neoplasms; 4, Diseases of the Blood and Blood-Forming Organs;7, Diseases of the Circulatory System; 8, Diseases of the Respiratory System; 9, Diseases of the Digestive System; 10, Diseases of the Genitourinary System; 17, Injury and Poisoning

Given the potential negative impact of oncological diseases, we performed an alternative multivariable analysis excluding oncological patients (presenting an ICD9 chapter 2 disease). Even in this case, the comorbidity and multimorbidity groups were not associated, in a multivariable model, with any of the outcomes (in-hospital mortality, 30-day mortality and 30-day readmission; data not shown).

Discussion

MCC constitutes a major health problem, their prevalence is very high, both in the general population and in hospital settings [25-27], and this burden seems to be constantly growing [28]. Certainly, MCC heavily affect important outcomes, such as mortality [29] and healthcare utilization and costs [30]. Despite the above and taking into account the sharp increase of dedicated studies [31], there persists a confused conceptualization of the terms to describe the occurrence of MCC [7]. In this regard, the recently proposed distinction between comorbidity [8], defined in accordance with the seminal statement by Feinstein [32] as in relation to an index disease, and multimorbidity [9], in which no disease holds priority, represents an important achievement [10]. To assess whether this distinction has actual consistency in an internal medicine setting, we have used this conceptualization for the first time to evaluate how this is correlated with a series of demographic and clinical variables.

Considering all the 1394 inpatients, the prevalence of MCC (96.2%) was higher than that reported in the general practice, [33, 34] but similar to what was found in previous hospital studies, which are, however, partly comparable to ours. In fact, even within the same setting, other differences affect generalizability of the data. Aubert and colleagues conducted a multicenter and multinational study, reporting a prevalence of MCC of 86% [35]. Most of the centers were academic, but also specialist units were included which might have lowered patients’ median age (64 years). Moreover, the use of administrative data collected in a retrospective fashion may have affected the overall accuracy of that study [36]. A setting that has greater similarity to ours is that of Schneider and colleagues who found a prevalence of MCC of 93%, although, also in this case administrative data were assessed [37]. In our study, the median age of patients with MCC was 78 years and patients aged 18–64 were under-represented compared to the primary care setting or to the general population [33, 34]. Finally, in line with an Italian registry study, no gender predominance was found in patients with MCC [38].

As expected, and in keeping with all the previous literature [39-42], patients with MCC had, compared to those with only one acute or chronic disease, greater age, and worse outcomes, despite numerically unbalanced groups.

By dividing the patients into the three categories, namely no MCC, comorbidity, and multimorbidity, the latter turned out to be the most prevalent (75.7%). This finding has no support in the literature, as no one has ever designed a similar study before. The median age of patients with multimorbidity was significantly higher compared to those with no MCC and comorbidity. Moreover, a significantly increasing age trend was noticed, having multimorbidity the highest prevalence in patients aged 75 and over. This argues in favor of a stochastic accumulation of diseases, among which no disease holds priority, as a consequence of aging which carries epigenetic effects due to cumulative life events, prolonged impact of common risk factors and unhealthy lifestyle, frailty (which was actually more prevalent in this group), socioeconomic distress, and mental impairment [34, 43, 44]. Conversely, in comorbid patients (20.5%) an opposite age trend was noticed. Of note, according to a recent systematic review, while most frail patients were also multimorbid (roughly 72%), only a minority of multimorbid patients were frail (roughly 16%) [45]. This figure is in line with our data, which reported a prevalence of frailty of roughly 19% in multimorbid patients. The prevalence of comorbidity instead was higher in the 18–64 age group and decreased with aging. Mechanisms other than aging, such as common genetic susceptibility [46], direct causation of a disease to another or the co-presence of a glaring complication especially when a chronological link is evident [43], could point at an index disease, and hence comorbidity [47]. Additionally, an etiological link between diseases may be more easily recognizable in younger patients, given the milder effect of aging.

A relevant result—being the primary endpoint of the study—is that multimorbid patients had greater CIRS comorbidity and severity indexes compared to comorbid patients. Notably, the median number of chronic diseases did not statistically differ between the two categories, confirming that this parameter did not interfere with patient categorization. After adjustment for age groups, this difference was significant only in patients aged > 75, thus confirming an age effect not only in underlying patient categorization, but also in the magnitude of the CIRS scores.

Concerning polypharmacy, we have applied its most common definition, i.e., the intake of five or more medications [48]. Multimorbidity and polypharmacy are indeed strictly related, but the detrimental effects of drug-drug interactions are often overlooked [49]. Richardson and Doster, placing comorbidity and multimorbidity in the context of a three-dimensional framework of risk, responsiveness and vulnerability, predicted a different decision making about treatments in relation to these categories [12] and it has been said that concordant diseases may be managed synergistically [50]. Our results show that polypharmacy was more common in patients with multimorbidity (78.7%) and it was significantly associated with a higher risk of 30-day readmission. Yet, roughly half (50.9%) of the patients with comorbidity also had polypharmacy, and this may reflect the co-presence of concordant diseases which may lower the need for different classes of medications. The greater odds for 30-day readmission in polypharmacy (OR 1.34) could reflect the presence of more severe or unstable conditions requiring hospital admission.

Rather disappointingly, we did not find any meaningful differences in patients’ major outcomes between the comorbidity and the multimorbidity frameworks, not even after the exclusion of neoplastic patients. However, also in a primary care practice, comorbidity scores did not predict important clinical outcomes, such as hospital admission and re-admissions, whereas different results were noticed when considering physician-defined complexity, that also took into account contextual and psychosocial contributors [51]. After all, it is well known that the available measures for categorizing MCC do not reflect the overall patients’ complexity [14, 38, 43, 52, 53]. Age once again confirmed to be the most important and independent determinant of in-hospital mortality, 30-day mortality, and 30-day readmission.

Indeed, our study has some limitations. Although we followed the MeSH criteria for differentiating comorbidity from multimorbidity, and although this differentiation was performed by a single expert physician, we are aware that the nuanced definitions may imply some subjectivity, which, however, reflects what happens in the real-world clinical practice. In addition, we did not take into account the allocation of diagnostic and therapeutical resources per each patient, which might be useful for identifying comorbidity and multimorbidity in clinical practice. The generalizability of our results is limited to an academic, internal medicine setting, and cannot be applied to the primary care setting, where the definition of an index disease might be more challenging. The brief follow-up time might have mitigated some differences in terms of major outcomes. On the other hand, our study also has many strengths, including the homogeneity of data, the real-world setting, and its monocentric nature. More importantly, all patients’ data have been collected in a prospective fashion, through direct interview, without using administrative data which are hampered by many limitations [36]. The hospital setting guarantees, more than others, that all morbid conditions have been taken into account. Finally, this study was conducted just before the beginning of the SARS-CoV-2 pandemic, hence our results were not affected by this event.

To conclude, we have performed the first ad hoc study focusing on possible differences between patients with comorbidity and multimorbidity. Multimorbid patients are much more prevalent, older, and with a greater disease burden and polypharmacy. Most of the heterogeneity between multimorbidity and comorbidity was found to be a consequence of aging that, as expected, proved to be an independent determinant of mortality and re-hospitalization. In future studies, differentiating patients into these two frameworks may be useful in both research and clinical settings.

Below is the link to the electronic supplementary material.

Supplementary file1 (DOCX 13 kb)

Supplementary file2 (DOCX 17 kb)