1 Introduction
We study the determinants of Italian regional governments’ choices concerning the number of local health authorities (LHAs). Our argument is that, other things being equal, such decisions depend on whether the government perceives the citizens’ healthcare demand as a demand for substitutable or complementary services. We cite empirical results from the Italian National Health Service (NHS) in support of our hypothesis.
Consolidation of local bureaucratic organizations has occurred in different institutional contexts and sectors since the mid-1990 s (e.g., healthcare: Talbot and Johnson
2007 for the United Kingdom; McDaid et al. (
2009) for Ireland; local governments: Andrews
2015 for vertical consolidation in England; Blom-Hansen et al.
2016 for horizontal consolidation in Denmark). In Italy, consolidation of the healthcare sector has been on a large scale, the number of LHAs being cut from 638 in 1982 to 143 in 2012. Why do governments consolidate public bureaus and, more specifically, LHAs? The main motivation for consolidation presumably is cost reduction, thanks to economies of scale and scope, lower management and back-up costs, the introduction of cost-effective management styles, and the gain in monopsony power in negotiating with private sector providers (Garside
1999; Fulop et al.
2002 for the United Kingdom; France et al.
2005, p. S190 for Italy). The idea that cutting the number of LHAs can reduce bureaucratic costs, heighten efficiency and free public resources for investment in better healthcare services is popular among Italian national politicians (see the opening quotation). The academic literature also suggests political and institutional motivations for bureaucratic reorganization. Governments interested in policy reforms may see consolidation or decentralization as a way of strengthening their control over the bureaucracy (Lester et al.
1983 on environmental policy in the US states; Del Vecchio and Cuccurullo
2013 on the Italian NHS). Majoritarian electoral systems may facilitate the drive for bureaucratic reorganization (Pollitt
2007 for the United Kingdom). Consolidation/decentralization attitudes, moreover, are related to partisanship. For example, in Britain the Conservative governments of the early 1990 s expanded the number of LHAs in order to mimic competition (Le Grand
1999), whereas the New Labor governments, implementing command and control policies, preferred to have fewer and larger LHAs (Goodwin
2000). Electoral considerations likewise may play a role. For example, hospital mergers in the English NHS under New Labor were less common in election years, especially in swing districts (Gaynor et al.
2012).
In this paper, we propose an additional determinant of a government’s decision to consolidate public bureaus, which is driven by strategic incentives to reduce bureaucratic slack. We model the interaction between the government and the bureaus as a two-stage game (see also Fedeli and Santoni
2006). In the first stage, the government chooses whether to consolidate or to keep two bureaus separate. In the second stage, for given amounts of public resources, the government and the bureaus play a Nash budgetary game by choosing their compliance levels (Miller
1977), namely, respectively, the share of resources to be allocated to the bureaucratic budget and the share of the budget to be devoted to service production. It turns out that in subgame perfect symmetric Nash equilibrium the government can reduce bureaucratic slack by either promoting competition between bureaus when they produce services that it perceives as substitutes, or by consolidating bureaus producing complements. The basic mechanism at work is an externality in bureaucratic compliance levels (i.e., effort levels): provided that the bureaus “care about” the government’s demand, their payoffs become interdependent in that an increase in compliance levels in one bureau induces the other bureau to raise (respectively, lower) its own compliance efforts when the services are complements (respectively, substitutes). With complements, the government has an incentive to induce the bureaus to internalize the externality by consolidating them into a single agency, whereas it prefers to keep them separated in the case of substitutes. The model also shows that those incentives are reinforced by shocks to the government’s demand for bureaucratic output that were not foreseeable at the time the government designs bureaucratic organization.
We test our hypotheses using regional data on the Italian NHS from 1982 to 2012. The NHS was established in 1978 and has been operative since 1980. It is a universal public healthcare system providing comprehensive insurance coverage and uniform health benefits. It is financed partly by general taxation, along with user copayments for some services. Central and regional governments share responsibility for funding and service provision. On the expenditure side, each of the 20 regional Italian governments sets the level of regional healthcare services provided and determines their administration and organization. Those decisions are subject to a common national legal and regulatory framework, which specifies healthcare standards (termed “essential levels of care”, or LEAs). On the financing side, until 2012 the central government set regional healthcare budgets using general revenues and allocating resources on the basis of historical expenditure and healthcare needs, irrespective of regional fiscal capacity (France et al.
2005, p. S194; Francese and Romanelli
2011, p. 6). Major reforms of NHS governance were enacted in 1992 and 1999 to shift financing responsibilities to the regional governments and keep the NHS budget under control, but with mixed results.
1
In the Italian NHS, each regional government establishes the number of regional LHAs, called Aziende Sanitarie Locali. They are independent organizations with full autonomy regarding their legal, organizational, administrative, financial, accounting, managerial and technical responsibilities. The president of the region appoints each LHA’s director on the basis of five-year renewable private contracts. The LHAs provide care both directly (through LHA-managed hospitals and territorial agencies offering primary care, outpatient facilities, and other services) and indirectly (paying accredited public and private providers, such as hospitals, nursing homes and laboratories). Each director bargains with the regional government over the LHA’s budget. Hence, a rational regional government can organize healthcare services in order to influence the outcome of its negotiations with the LHA’s management over the allocation of largely predetermined resources.
The empirical results offer support for the model we propose. As long as each regional government’s willingness to pay for healthcare services—which we assume reflects citizens’ preferences—is unobservable over time, we proxy that willingness on the basis of society’s evaluation of physical healthcare resources—inputs used in the transformation process—and produced outputs (Jacobs et al.
2006, chapter 2). In addition, we use the ratio of the number of general practitioners to NHS specialists and the ratio of the number of NHS specialists to hospital beds as proxies for substitutable healthcare services. The idea is that the government perceives the demand for primary care services as a substitute for specialty and inpatient care if, say, increasing minor surgery procedures in general practice reduces patients’ demands for in hospital-based minor surgery (Scott
1996). That would also be the case if the government observes that an increase in the number of visits to primary care physicians is associated with a reduction in the number of visits to public healthcare specialists (Atella and Deb
2008). Similarly, the government may perceive NHS specialists and hospital beds to be substitutes, if an increase in the number of privately paid visits to public hospital-based specialists (performing examinations requiring medical equipment, say) lowers the demand for post-procedure recovery in NHS hospitals (Turchetti
2009, pp. 116–117). On the other hand, we take the ratio between the number of general practitioners and NHS hospital beds as a proxy for the demand for complementary healthcare services. That may be the case if the government perceives that the citizens’ demand for the detection of illnesses is a demand for both primary care and inpatient care (Fortney et al.
2005). For example, the detection of diabetes mellitus may require both blood pressure measurement by a general practitioner and glycated hemoglobin measurement and visit by a specialist diabetes team.
It turns out that variables proxying for the substitutable (complementary) services show a positive (negative) effect on the number of LHAs. Moreover, demand shocks, proxied by the two major Italian immigration amnesties in 1998 and 2002, magnify the incentives for consolidation or decentralization. The conclusions are not altered by controlling for: common time-specific shocks (supply-side and policy shocks to national healthcare laws and regulations); cost-side determinants (economies of scale); political and institutional factors (including election years, the regional government’s political “color”, and the type of regional electoral system); additional demand-side determinants of healthcare services (including regional per capita GDP and demographics); and time-invariant unobservable region-specific components (capturing, say, cultural differences).
Our paper also contributes to the empirical literature on the Italian NHS. However, whereas the existing literature focuses on healthcare expenditures and funding (Cellini et al.
2000; Giannoni and Hitiris
2002; Levaggi and Zanola
2003; Bordignon and Turati
2009; Francese and Romanelli
2011; Atella et al.
2014; Fedeli
2015), this paper is the first to model the determinants of the number of LHAs.
The paper proceeds as follows. Section
2 presents a stylized model capturing a regional government’s strategic incentives to design the structures of public bureaus. Section
3 presents the data and the empirical model. Section
4 presents the empirical results. Section
5 concludes.
2 The model
Borrowing both from the standard approach to the economic theory of bureaucracies (see, among others, Niskanen
1971; Migué and Bélanger
1974; Breton and Wintrobe
1975,
1982; Forte and Powers
1994), and from the public choice literature’s insight that politicians can increase bureaucratic efficiency by properly designing the organizational form of bureaucratic supply (Moe
1984,
2012; Bagnoli and McKee
1991; Ting
2002; Janssen et al.
2003; Bates and Santerre
2008; Bates et al.
2011), and from Horn and Wolinsky (
1988), who develop the idea that consolidation depends on the extent of input substitutability, this section extends Fedeli and Santoni (
2006) to the case of demand uncertainty. Consider a regional government willing to offer bureaucratic output (e.g., healthcare services). Output can be produced either separately by two independent agencies or jointly by a single consolidated agency. In the case we examine, agencies are LHAs supplying primary care (such as general practitioner visits and preventive care), secondary care (e.g., specialist visits in hospitals, hospitalization and medical assistance), or both.
The game sequence is as follows. At stage one, the regional government chooses whether to consolidate or to keep two bureaus separate. As long as each regional government has sole responsibility for determining the number of LHAs, this assumption fits the Italian NHS. At stage two, the government negotiates over the budget with the bureau(s). Following the game-theoretic approach of Nikaidȏ and Isoda (
1955) as applied by Miller (
1977) and Fedeli (
1999) to compliance relationships inside bureaucracies, each agent chooses simultaneously its own Nash compliance level. In particular, the government sets the share of public resources it allocates to the bureaus as a budget and the bureaus set the share of their budget that actually is used for producing the desired output. Depending on the outcome of stage one of the game, two subgames are considered. In the consolidation subgame, the government and the single bureau choose their own compliance strategies, by taking as given the strategies simultaneously chosen by the other agent. In the separation subgame, simultaneous bilateral Nash budget games are played between the government and each single bureau. Similar to Horn and Wolinsky’s (
1988) Nash-in-Nash bargaining solution,
2 each bilateral negotiation selects its Nash equilibrium under the assumption that a Nash equilibrium will occur in the other negotiation as well. Then, the equilibrium bureaucratic organizational form and compliance levels arise in sub-game perfect Nash equilibrium.
The government’s preferences are
$$G = \left\{ {\alpha \left[ {{\mathbf{Q}}_{{\mathbf{1}}} {\mathbf{ + Q}}_{{\mathbf{2}}} } \right] - \left[ {\frac{{\beta \, \left( {{\mathbf{Q}}_{{\mathbf{1}}}^{{\mathbf{2}}} {\mathbf{ + Q}}_{{\mathbf{2}}}^{{\mathbf{2}}} } \right)}}{2}} \right] - {\mathbf{2}}\gamma Q_{1} Q_{2} } \right\} + \sum\limits_{k = 1}^{2} {(R - B_{k} )} ,$$
(1)
The first term represents a quadratic evaluation function of the bureaucratic production of differentiated outputs
Qk,
k = 1,2, with
α > 0,
β >0,
β2 > 4γ
2 and
β > 2|γ| (Singh and Vives
1984). We assume that the function derives from the preferences of the electoral constituency (citizens or potential patients). The second term is the political rents the government obtains from the budgetary process, which is equal to the difference between public resources
R and the budget
Bk =
Rgk the regional government assigns to the bureaus, where
gk ∈ [0,1] is the share of resources it allocates to the production of output
k = 1, 2.
R is predetermined by the central government based on observables (e.g., demographics), an assumption that fits the Italian NHS. Governmental maximization of (1) with respect to
Qk gives
$$V_{k} = \alpha + \varepsilon - \beta Q_{k} - 2\gamma Q_{l} ,$$
(2)
where we enter a common additive shock
ε with E(
ε) = 0 and E(
ε2) =
s2, to the solution.
Vk,
k = {1,2} and
k ≠
l, represents the government’s perception of the citizens’ willingness to pay for
Qk, given
Ql. For
γ < 0 the two outputs are complements. In that case, the willingness to pay for, say, general practitioners’ diagnostic services and referral to hospital increases with the demand for hospitalization. For
γ > 0 the outputs are substitutes. As such, the willingness to pay for, say, specialist visits in hospital declines when the demand for primary care physician visits rises. For
γ = 0, the two outputs are independent. The shock
ε affects linearly the government’s reservation price, thus the willingness to pay for bureaucratic output. That term can be interpreted as a shock to the population that is eligible, e.g., for public healthcare coverage. The shock occurs after the government’s organizational choice, but its realized value is public knowledge before stage two takes place. Regarding the Italian NHS, the shock can be related to the inflows and outflows of immigrant workers and their families in each region associated with national immigration amnesties. Following Klemperer and Meyer (
1986), assume that the size of the shock is small enough so that both prices and bureaucratic output levels are positive.
Turning to bureaucratic preferences, with two independent bureaus (LHAs) we have decentralization, D:
$$LHA\;D_{k} = V_{k} Q_{k} + B_{k} (1 - h_{k} )$$
(3)
With one consolidated bureau we have centralization, C:
$$LHA\;C = \sum\limits_{k = 1}^{2} {LHA} \quad D_{k} = \sum\limits_{i = k}^{2} {V_{k} Q_{k} } + \sum\limits_{i = k}^{2} {B_{k} (1 - h_{k} )}$$
(4)
Equations (
3) and (
4) assume that public agencies care about bureaucratic revenue and evaluate their activities according to
Vk, namely the government’s perception of the citizens’ marginal willingness to pay for good
k = 1, 2. The latter assumption (originating from Niskanen
1971) fits the Italian NHS case, as the president of the region appoints the directors of the LHA, which means that they cannot ignore the politicians’ wishes. However, bureaus also are interested in slack. Slack is represented by the second term of both equations, where
hk ∈ [0, 1] denotes the share of the public budget
Bk that the bureau allocates to production. For simplicity, we assume that production occurs with constant-returns-to-labor technology at the minimum (symmetric) production cost
c > 0, with 0 < c<α. Hence, total production costs are TC
k = cQ
k. That assumption enables us to single out the government’s strategic incentives in designing bureaucratic structure that are related to the demand side. In the empirical section, we control for possible determinants of cost, including the returns-to-scale regime. Note that, although production occurs at minimum average cost, the budgetary process generates ex post inefficiencies as far as some slack arises in equilibrium.
Solving the model by backward induction, in stage two the government and the bureaus choose compliance levels, given the centralization/decentralization choice at stage one and the realized value of the shock ε. From previous assumptions, public resources for producing good k can be written as
hkgkR =
cQk, implying that
Qk =
hkgkR/
c, for
k = 1,2. Substituting this back into Eqs. (
1) and (
3) or (
4), preferences can be formulated in terms of the budgetary strategies
gk and
hk (Miller
1977) and the value of the shock ε. In the separation subgame D, the government engages in a simultaneous compliance game with each bureau. The government chooses g
k by maximizing Eq. (
1), taking as given the budgetary strategy of the bureau choosing h
k to maximize Eq. (
3) given g
k. Both agents take the Nash outcome of the parallel compliance game between the government and the other bureau as given, yielding the symmetric Nash equilibrium unconsolidated compliance levels:
$$\begin{aligned} & \hat{g}_{1}^{D} = \hat{g}_{2}^{D} = \frac{{\left( {\alpha - c + \varepsilon } \right)\left[ {\alpha \beta + \left( {\beta + 2\gamma } \right)\left( {c - \varepsilon } \right)} \right]}}{{4R\left( {\beta + \gamma } \right)^{2} }}, \\ & \hat{h}_{1}^{D} = \hat{h}_{2}^{D} = \frac{{2c\left( {\beta + \gamma } \right)}}{{\left[ {\alpha \beta + \left( {\beta + 2\gamma } \right)(c - \varepsilon )} \right]}} \\ \end{aligned}$$
In the consolidation subgame C, the government sets simultaneously g
k and g
l by taking as given the strategies h
k and h
l simultaneously set by the single bureau to maximize Eq. (
4) for given
gs. The solution yields the Nash equilibrium compliance levels:
$$\begin{aligned} & \hat{g}_{1}^{C} = \hat{g}_{2}^{C} = \frac{{\left[ {\alpha^{2} - \left( {\varepsilon - c} \right)^{2} } \right]}}{{4R\left( {\beta + 2\gamma } \right)}}, \\ & \hat{h}_{1}^{C} = \hat{h}_{2}^{C} = \frac{2c}{{\left[ {\alpha + \text{c} - \varepsilon } \right]}}. \\ \end{aligned}$$
Note that compliance levels always are positive and fall short of unity, provided the size of the shock is small enough. That result implies positive political rents and bureaucratic slack in Nash equilibrium. At stage one of the game, the government knows the distribution of the shock and its own state-contingent payoffs at stage two. Computing the government’s expected value function under D or C yields
$$\begin{aligned} & E\left( {\hat{G}^{D} } \right) = 2R + \frac{{\left( {\alpha - c} \right)^{2} \left( {\beta + 2\gamma } \right)}}{{4\left( {\beta + \gamma } \right)^{2} }} + \frac{{s^{2} \left( {\beta + 2\gamma } \right)}}{{4\left( {\beta + \gamma } \right)^{2} }} \\ & E\left( {\hat{G}^{C} } \right) = 2R + \frac{{\left( {\alpha - c} \right)^{2} }}{{4\left( {\beta + 2\gamma } \right)}} + \frac{{s^{2} }}{{4\left( {\beta + 2\gamma } \right)}}, \\ \end{aligned}$$
(5)
Equation (
5) shows that additive uncertainty raises the government’s expected payoff above its deterministic level by a term that is proportional to the variance of the shock s
2. Hence, the government chooses centralization as its subgame perfect Nash equilibrium strategy if and only if
$$E\left( {\hat{G}^{C} } \right) - E\left( {\hat{G}^{D} } \right) = \gamma \left[ {\left( {\alpha - c} \right)^{2} + s^{2} } \right]\left[ {\frac{{\left( {2\beta + 3\gamma } \right)}}{{4\left( {\beta + \gamma } \right)^{2} \left( {\beta + 2\gamma } \right)}}} \right] > 0,$$
(6)
namely for
γ < 0, meaning that bureaus produce complementary outputs from the electorate’s viewpoint. The intuition for this result is as follows. Provided that bureaus evaluate outputs according to the government’s demand, their payoffs become interdependent. When the outputs are complements, an increase in compliance by one bureau raises (lowers) the marginal utility of higher compliance by the other bureau. The government therefore has a strategic incentive to induce bureaus to internalize that externality by consolidating them into a single agency at stage one of the game, as long as consolidation reduces slack and raises the government’s expected utility. When the outputs are substitutes,
γ > 0, however, the externality takes the opposite sign, and a single consolidated agency would set a lower compliance level, resulting in more slack in Nash equilibrium. In that situation, the government has a strategic incentive to keep the two bureaus separated. Hence, unlike in Bagnoli and McKee (
1991) and contrary to the received view, promoting competition among bureaus does not necessarily increase bureaucratic efficiency, as that outcome depends on the nature of the externality in the budgetary process. Moreover, reducing bureaucratic slack in the presence of complements also implies an increase in government’s compliance (as long as the government’s marginal utility of greater compliance increases the bureau’s compliance level, i.e., g
i and h
i are strategic complements from the government’s viewpoint). As a consequence, bureaucratic production is higher when complements are produced by a consolidated bureau (i.e., Q
i
C
> Q
i
D
for
γ < 0). Moreover, uncertainty enhances the government incentives to consolidate bureaus with complements and to keep them separated with substitutes.
2.1 The stochastic solution
In order to evaluate more explicitly the difference between the stochastic and the deterministic equilibrium solutions of the model, it is useful to decompose the stochastic component of the government’s expected value function under centralization C and rewrite Eq. (
5), as follows:
$$\frac{{s^{2} }}{{4\left( {\beta + 2\gamma } \right)}} = \mathop {\frac{{s^{2} }}{{4\left( {\beta + 2\gamma } \right)}}}\limits_{{\text{stochastic gains from rents}}} = \mathop {\frac{{s^{2} }}{{4\left( {\beta + 2\gamma } \right)}}}\limits_{{\text{stochasticloss from production}}}$$
(7)
Equation (
7) shows that the stochastic shock alters the government’s tradeoff between the utility from political rents and that from the outputs. Let us explicate the economic intuition behind this result. In the stochastic case, the budget provided to the consolidated bureau is smaller, namely the government’s expected compliance
\(E\left( {\overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\frown}$}}{g}^{C} } \right) - = \frac{{\alpha^{2} - c^{2} - s^{2} }}{{4R\left( {\beta + 2\gamma } \right)}}\) is lower than in the deterministic case,
\(\mathop g\nolimits^{C} = \frac{{\mathop \alpha \nolimits^{2} - \mathop c\nolimits^{2} }}{{4R\left( {\beta + 2\gamma } \right)}}\), implying that expected political rents are higher in the stochastic than in the deterministic case. However, although the equilibrium level of the outputs is the same in both cases,
\(E\left( {\frac{{\overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\frown}$}}{g}^{C} \hat{h}^{C} R}}{c}} \right) = E\left( {\frac{\alpha + \varepsilon - c}{{2\left( {\beta + 2\gamma } \right)}}} \right) = \frac{\alpha - c}{{2\left( {\beta + 2\gamma } \right)}},\) by Jensen’s inequality the expected indirect utility from the outputs is lower in the stochastic than in the deterministic case, as long as the following is satisfied
$$E\left[ {\left( {\frac{{\overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\frown}$}}{g}^{C} \hat{h}^{C} R}}{c}} \right)^{2} } \right] = \left[ {\frac{{\left( {\alpha - c} \right)^{2} + s^{2} }}{{4\left( {\beta + 2\gamma } \right)^{2} }}} \right] > \left[ {E\left( {\frac{{\overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\frown}$}}{g}^{C} \overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\frown}$}}{h}^{C} R}}{c}} \right)} \right]^{2} = \left( {\frac{\alpha - c}{{2\left( {\beta + 2\gamma } \right)}}} \right)^{2} .$$
Considering both effects and given that the government’s payoff is concave in outputs, the larger expected political rents in the stochastic case more than offset the reduction in the expected gains from the outputs. As a result, the expected payoff is increasing in the variance of the shock. The analysis of the stochastic component of the government’s expected value function under decentralization D is similar. It follows that the latter also will be increasing in the variance of the shock. Hence, uncertainty will enhance the government’s incentive to choose C with complements and to choose D with substitutes.
2.2 Exogenous shocks to the demand slopes
Following Klemperer and Meyer (
1986), assume now that the exogenous shock influences the slopes of demand
$$V_{k} = \alpha - \frac{\beta }{\varepsilon }Q_{k} - \frac{2\gamma }{\varepsilon }Q_{l} ,$$
(8)
with
k, l = 1,2,
k ≠
l and with
E(
ε) = 1,
E(1/
ε) > 1,
E(
ε2) =
s2 > 1. Such a shock leaves both the degree of substitutability between bureaucratic outputs and the reservation price unaffected. The shock can be interpreted as capturing as well an unexpected increase in the local population eligible for accessing bureaucratic output. Solving the model by backward induction, the players’ budgetary strategies at a symmetric Nash equilibrium when the government deals with one single bureau are
$$\begin{aligned} & \overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\smile}$}}{g}_{1}^{C} = \overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\smile}$}}{g}_{2}^{C} = \frac{{\left( {\alpha - \text{c}} \right)\left[ {2\alpha - \left( {\alpha - \text{c}} \right)\varepsilon } \right]\varepsilon }}{{4\text{R}\left( {\beta + 2\gamma } \right)}}, \\ & \overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\smile}$}}{h}_{1}^{C} = \overset{\lower0.5em\hbox{$\smash{\scriptscriptstyle\smile}$}}{h}_{2}^{C} = \frac{2c}{{2\alpha - \left( {\alpha - \text{c}} \right)\varepsilon }}. \\ \end{aligned}$$
(9)
Therefore, at stage one of the game, the government’s expected payoff is
$$E\left( {G^{C} } \right) = \underbrace {2R}_{{\text{deterministic payoff}}} + \underbrace {{\frac{{2s^{2} (\alpha - c)^{2} }}{{4\left( {\beta + 2\gamma } \right)}}}}_{{\text{stochastic gains in terms of rents}}} - \underbrace {{\frac{{s^{2} (\alpha - c)^{2} }}{{4\left( {\beta + 2\gamma } \right)}}}}_{{\text{stochastic loss in terms of output evaluation}}}.$$
(10)
The symmetric budgetary strategies and the government’s expected payoff when dealing with two bureaus are:
$$\begin{aligned} & g_{1}^{D} = g_{2}^{D} = \frac{{\left( {\alpha - \text{c}} \right)\left[ {2\alpha \left( {\beta + \gamma } \right) - \left( {\alpha - \text{c}} \right)\left( {\beta + 2\gamma } \right)\varepsilon } \right]\varepsilon }}{{4\text{R}\left( {\beta + \gamma } \right)^{2} }}, \\ & h_{1}^{D} = h_{2}^{D} = \frac{{2c\left( {\beta + \gamma } \right)}}{{2\alpha \left( {\beta + \gamma } \right) - \left( {\alpha - \text{c}} \right)\left( {\beta + 2\gamma } \right)\varepsilon }}. \\ \end{aligned}$$
(11)
$$E\left( {G^{D} } \right) = \underbrace {2R}_{\text{deterministic payoff}} + \underbrace {{\frac{{2s^{2} \left( {\alpha - c} \right)^{2} \left( {\beta + 2\gamma } \right)}}{4(\beta + 2\gamma )}}}_{\text{stochastic gain in terms of rents}} - \underbrace {{\frac{{s^{2} \left( {\alpha - c} \right)^{2} \left( {\beta + 2\gamma } \right)}}{4(\beta + 2\gamma )}.}}_{\text{stochastic loss in terms of output evaluation}}$$
(12)
Equations (
10) and (
12) show that the government’s expected payoffs are increasing in the variance of the shock, yielding:
$$E\left( {G^{C} } \right) - E\left( {G^{D} } \right) = - \gamma \left[ {\left( {\alpha - c} \right)^{2} s^{2} } \right]\left[ {\frac{2\beta + 3\gamma }{{4\left( {\beta + 2\gamma } \right)\left( {\beta + \gamma } \right)^{2} }}} \right] > 0.$$
(13)
Uncertainty about the elasticity of the demand curve reinforces the deterministic incentives of the government to consolidate the bureaus with complements (γ < 0) and to keep the bureaus separated with substitutes (γ > 0). This confirms the previous findings derived under the assumption of an additive exogenous shock.
4 Results
The results for the initial specification of the estimating model are given in Column (a) of Table
2. Standard errors are consistent with autocorrelation and heteroscedasticity. The lagged dependent variable is statistically significant and negative, as expected, which supplies evidence in favor of the existence of some inertia in the adjustment process. The coefficient is small, in line with the hypothesis of gradual adjustment of the number of LHAs to the long-run level. The results support H1. They suggest that the change in the number of LHAs is positively correlated at standard levels of significance with
GPs/Specialists and
Specialists/Hospital beds, our measures of the government’s perception of citizens’ demand for substitutes, and negatively correlated with
GPs/Hospital beds, our measure for the demand for complements.
Table 2
Results for Hypothesis 1
LHAi,t−1 | − 0.068*** | − 0.051*** | − 0.274*** | − 0.043*** |
| (0.022) | (0.016) | (0.062) | (0.007) |
Specialists/Hospital bedsi,t−1 | 0.117*** | 0.166*** | 0.337*** | 0.251*** |
| (0.041) | (0.047) | (0.089) | (0.064) |
GPs/Hospital bedsi,t−1 | − 0.224** | − 0.304*** | − 0.467* | − 0.422*** |
| (0.094) | (0.102) | (0.262) | (0.138) |
GPs/Specialistsi,t−1 | 0.069** | 0.083*** | 0.132** | 0.086*** |
| (0.028) | (0.029) | (0.058) | (0.036) |
Economies of scalei,t−1 | | 0.176** | 0.397* | 0.126** |
| | (0.085) | (0.286) | (0.080) |
Economies of scale
i,t−1
2
| | − 0.016** | − 0.036 | − 0.011** |
| | (0.008) | (0.026) | (0.007) |
∆HTi,t−1 | | − 1.608*** | − 1.552*** | − 2.001*** |
| | (0.457) | (0.357) | (0.097) |
Electioni,t−1 | | 1.402** | 1.111** | 1.098** |
| | (0.648) | (0.461) | (0.430) |
Constant | − 4.219** | − 55.722** | − 121.738 | − 43.981** |
| (1.821) | (24.267) | (81.682) | (22.229) |
F-test (31, 580) for time dummies | 8.600*** | 8.890*** | 8.450*** | 47.040*** |
F-test (38, 510) for region specific time trends | | | 4.210*** | |
Wald test for exogeneity (p value) | | | | 6.61 (0.158) |
Log-likelihood | − 1643.52 | − 1517.94 | − 1475.27 | |
Pseudo-R2 | 0.0696 | 0.1149 | 0.1398 | |
Number of observations | 580 | 560 | 560 | 560 |
The results reported in Table
2 are robust to region-specific fixed effects (removed by first differencing), and to common supply shocks, controlled for with the full set of time dummies. In one second exercise, we add several variables to the set of regressors, following a general-to-specific approach. The results of that approach are summarized in Column (b) of Table
2, where our model in Column (a) is augmented by adding our measure of economies of scale (in its non-linear specification), the variation in the number of HTs, and the dummy for elections. The variable capturing economies of scale is statistically significant at the 5% level with a positive sign, and negative for its squared value. Therefore, an increase in the number of beds per hospital is associated at first with an increase in the desired number of LHAs, but above a certain threshold a further increase gives the government an incentive to consolidate.
The value of the Economies of scale variable peaks at around 240–280 beds per hospital, which compares well with the literature on that issue. The results also suggest that the change in the number of HTs is negatively correlated, at the 1% significance level, with the change in the number of LHAs. Our interpretation is that governments perceive their citizens seeing the acute healthcare services provided by HTs as complementary to the primary and secondary healthcare that the LHAs either produce directly or procure from accredited private providers. Therefore, an increase in the number of HTs is taken as an increase in a region’s demand for complementary healthcare services, which in our model should be negatively correlated with the number of LHAs. Finally, we control for whether an election was held in the year prior to the change in the number of LHAs. The sign of Election suggests that the number of LHAs is more likely to change in years preceding the elections.
Concerns relate to the potential omitted variable, to potential correlation of the error term with the beginning-of-period number of
LHAs,
LHAit−1, and to potential correlation of the former with the main independent variables of interest, namely
GPs/Specialistsit−1,
GPs/Hospital bedsit−1 and
Specialists/Hospital bedsit−1. The three concerns differ. Clearly, a crucial question is checking the extent to which results are robust to omitted variables other than those we have added to the set of regressors. To investigate this matter, we have added the full set of region specific time trends. Results are reported in Column (c), showing that, if anything, the impact of interests are larger (in absolute value) than those reported in Column (b). The endogeneity of
LHAit−1 derives from its potential correlation with the fixed component of the error term. The bias is relevant in the “small T, large N” setup, which is not our case. The second issue relates to simultaneity and reverse causality among the variables. We have addressed that concern by lagging the variables. However, despite the previous arguments, we nevertheless estimated a full instrumental variables specification. We did so for the three regressors of interest by entering the initial values of the variables for each region as instruments for all the subsequent values, as in a GMM approach, and three predetermined regressors, namely the lagged mortality rate, the lagged infant mortality rate, and the variation in the differenced number of LHAs per capita. The results are reported in Column (d) and show that the test for exogeneity does not reject the hypothesis that the set of instruments is valid. As before, the estimated parameters are larger than those from our preferred specification.
3
Table
3 reports the results from testing H2, namely the hypothesis that shocks to the government’s perceived demand for differentiated healthcare services reinforce the incentive to consolidate in the case of complements and to keep LHAs separated in the case of substitutes. Table
3 introduces the two demand-shock proxies to our preferred specification, namely the changes in regional populations induced by the Bossi-Fini law (Column a) and the Turco-Napolitano law (Column b). Those shocks enter the set of regressors and are interacted with our relevant variables. The results show that for all of the demand shocks, the estimated coefficients of the demand proxies are statistically significant. The interaction terms have the expected sign (positive for the demand for substitutes, negative for complements) and are statistically significant at the 5% level or below. These results confirm the predictions of our theoretical model. Other things being equal, an increase in the regional demand for substitute healthcare services is associated with an increase of the number of LHAs, while an increase in the demand for complementary healthcare services is associated with a decline in the number os LHAs. The incentives for consolidation and decentralization are amplified by shocks to demand.
Table 3
Results for Hypothesis 2
LHAi,t−i | − 0.051*** (0.016) | − 0.051*** (0.016) |
Specialists/Hospital bedsi,t−1 | 0.175*** (0.049) | 0.162*** (0.048) |
GPs/Hospital bedsi,t−1 | − 0.298*** (0.103) | − 0.292*** (0.102) |
GPs/Specialistsi,t−1 | 0.083*** (0.029) | 0.081*** (0.029) |
Specialists/Hospital bedsi,t−1 × Bossi Finii,t−1 | 0.140** (0.067) | |
GPs/Hospital bedsi,t−1 × Bossi Finii,t−1 | − 0.413** (0.181) | |
GPs/Specialistsi,t−1 × Bossi Finii,t−1 | 0.186** (0.082) | |
Bossi Finii,t−1 | − 0.063** (0.031) | |
Specialists/Hospital bedsi,t−1 × Turco Napolitanoi,t−1 | | 0.085*** (0.029) |
GPs/Hospital bedsi,t−1 × Turco Napolitanoi,t−1 | | − 0.206*** (0.070) |
GPs/Specialistsi,t−1 × Turco Napolitanoi,t−1 | | 0.077*** (0.026) |
Turco Napolitanoi,t−1 | | −0.032*** (0.011) |
F-test (31, 560) for time dummies | 8.950*** | 8.790*** |
log*likelihood | −1516.50 | −1517.52 |
Pseudo-R2 | 0.1158 | 0.1152 |
Number of observations | 560 | 560 |
Because the estimated Tobit coefficients represent the marginal effects of the independent variables on the latent variable (here, the desired change in the number of LHAs), we compute the marginal effects of our proxies for the demand for differentiated healthcare services on the observed outcome variable. Table
4 reports the results. As expected, the marginal effects are smaller than those derived from the Tobit estimates on the latent variable. The evidence supports H2, which predicts that the magnitudes of the estimated coefficients increase (in absolute value) when the demand shocks are considered.
GPs/Specialistsi,t | 0.0302 | 0.0824 | 0.0593 |
| (0.012) | (0.002) | (0.000) |
GPs/Hospital bedsi,t | − 0.1013 | − 0.2306 | − 0.1900 |
| (0.045) | (0.002) | (0.001) |
Specialists/Hospital bedsi,t | 0.0600 | 0.1091 | 0.0959 |
| (0.019) | (0.001) | (0.000) |
5 Conclusions
This paper has analyzed the incentives of the Italian regional governments to consolidate local health authorities (LHAs). We have tested the hypothesis, derived from a stylized model, that, when a regional government perceives its citizens as demanding complementary healthcare services, it has an incentive to consolidate individual LHAs. In the case of the demand for substitute services, the regional government has an interest in dealing with a larger number of smaller LHAs. Our Tobit estimates for the years 1982–2012 show that those incentives are likely to have been in place in the Italian NHS. Over the sample period, the number of LHAs has been reduced drastically. Unquestionably, most of this reduction has been forced on the regional governments, which have the legal power to set the number of LHAs, by central government legislation and regulations since the mid-1990 s aimed at cost-cutting. This paper has argued that, in order to gauge regional governments’ incentives for consolidating, we should also look at the demand side.
The approach followed in this paper emphasizes the government’s strategic choice of bureaucratic organization, namely the government’s use of a control mechanism that operates ex ante (Moe
2012). However, as firstly argued by Breton and Wintrobe (
1975), governments might also impose direct controls on bureaus. Such controls are costly and may take different forms of direct monitoring of bureaus associated with both different performance targets and different systems of rewards and sanctions, which, in turn, depend on regional regulations. What difference would the inclusion of control costs make to the argument presented in this paper? We would expect that the higher the cost of direct control, the more effective institutional design might be as opposed to direct control. For example, if specialists are costlier to control than general practitioners, we would expect that promoting competition between bureaus producing substitutes will be more effective than direct control.
4 Moreover, we would expect that introducing direct controls might affect our main results in so far as control costs vary between organizational forms. If controlling a consolidated agency is less costly than controlling two separate agencies (because of, say, economies of scale and scope in the control technology), consolidation might emerge as the optimal governmental choice irrespective of the nature of the healthcare services being provided. If instead government’s monitoring is more efficient in smaller than in larger agencies, separation might emerge as the government’s preferred choice. However, if the two potential effects of organizational form on control costs balance each other out, we would expect no change in our main findings. Following the reasoning of Coase (
1937), Alchian and Demsetz (
1972) and Breton and Wintrobe (
1975), these different effects also might depend on the types of control device chosen. This, in turn, might also pose the issue of institutional design of bureaucratic agencies of control, or independent authorities, which we leave for future research.