Outdoor habitat modifications to include migration of adults

Migration rates of adult mosquitoes between habitats are controlled by the availability of wet oviposition sites or the availability of humans on which to feed. Feeding adults are assumed to migrate into the outdoor habitat from the indoor and enclosed habitats in search of humans to bite, and out of the outdoor habitat in search of blood meals in indoor spaces. Indoor habitats are defined as interior, temperature-moderated spaces, such as homes and buildings, that are not exposed to temperature variations. Two unique assumptions defining the enclosed habitat are that it is entirely wet and that it has no human subjects available for biting (Russell et al., Reference Russell, Kay and Shipton2001). These characteristics alter both the oviposition and migration patterns for adults in enclosed habitats.

Complete system of habitat-specific equations

Incorporating the modifications described above, the complete model consists of a system of 23 ordinary differential equations, which include eight equations each for the outdoor and indoor habitats and seven equations for the enclosed habitat. As these equations are similar in character to many models in the literature, the complete description of each of them is given in Appendix 1. The system of equations by habitat, including both biological and spatial transition terms, is as follows. Note that the factor of ½ in the coefficients of pupal terms representing transition to the adult stage represents the simplifying assumption that half are female.

Outdoor habitat model:

$${E}^{\prime}_{do} = ( 1-p_{wo}) e_bA_{2o}-n_{Ed}E_{do}-q_{Ed}E_{do}$$

$$\;{E}^{\prime}_{wo} = p_{wo}e_bA_{2o} + n_{Ed}E_{do}-n_{Ew}E_{wo}-q_{Ew}E_{wo}$$

$${L}^{\prime}_{so} = n_{Ew}E_{wo}-( f_s + n_{Ls}) L_{so}-\displaystyle{{q_{Ls}} \over {k_o}}L_{so}^2 $$

$$\;{L}^{\prime}_{bo} = n_{Ls}L_{so}-( f_b + n_{Lb}) L_{bo}-\displaystyle{{q_{Lb}} \over {k_o}}L_{bo}^2 $$

$$\;{P}^{\prime}_o = n_{Lb}L_{bo}-( f_P + n_P) P_o$$

$$A_o^{\prime} = \displaystyle{{n_P} \over 2}P_o-( d_a + n_a) A_o + \displaystyle{1 \over 2} \times \displaystyle{1 \over {l_v}}A_{2o} + m_{eo}A_e + m_{io}A_i-m_{oi}A_o$$

$$\;A_{2o}^{\prime} = n_aA_o-d_aA_{2o}-\displaystyle{1 \over {l_v}}A_{2o} + m_{2io}A_{2i}-m_{2oe}A_{2o}-m_{2oi}A_{2o}$$

$$A_{3o}^{\prime} = \displaystyle{1 \over 2} \times \displaystyle{1 \over {l_v}}A_{2o}-d_aA_{3o}$$

Indoor habitat model:

$$\;{E}^{\prime}_{di} = ( 1-p_{wi}) e_bA_{2i}-n_{Ed}E_{di}-q_{Ed}E_{di}$$

$$\;{E}^{\prime}_{wi} = p_{wi}e_bA_{2i} + n_{Ed}E_{di}-n_{Ew}E_{wi}-q_{Ew}E_{wi}$$

$$\;{L}^{\prime}_{si} = n_{Ew}E_{wi}-( f_s + n_{Ls}) L_{si}-\displaystyle{{q_{Ls}} \over {k_i}}L_{_{si} }^2 $$

$$\;{L}^{\prime}_{bi} = n_{Ls}L_{si}-( f_b + n_{Lb}) L_{bi}-\displaystyle{{q_{Lb}} \over {k_i}}L_{_{bi} }^2 $$

$$\;P_i^{\prime} = n_{Lb}L_{bi}-( f_P + n_P) P_i$$

$$\;A_i^{\prime} = \displaystyle{{n_P} \over 2}P_i-( d_a + n_a) A_i + \displaystyle{1 \over 2} \times \displaystyle{1 \over {l_v}}A_{2i} + m_{oi}A_O-m_{io}A_i$$

$$\;A_{2i}^{\prime} = n_aA_i-d_aA_{2i}-\displaystyle{1 \over {l_v}}A_{2i} + m_{2oi}A_{2o}-m_{2io}A_{2i}$$

$$A_{3i}^{\prime} = \displaystyle{1 \over 2} \times \displaystyle{1 \over {l_v}}A_{2i}-d_aA_{3i}$$

Enclosed habitat model:

$${E}^{\prime}_{we} = e_bA_{2e}-n_{Ew}E_{we}-q_{Ew}E_{we}$$

$$\;{L}^{\prime}_{se} = n_{Ew}E_{we}-( f_s + n_{Ls}) L_{se}-\displaystyle{{q_{Ls}} \over {k_e}}L_{_{se} }^2 $$

$${L}^{\prime}_{be} = n_{Ls}L_{se}-( f_b + n_{Lb}) L_{be}-\displaystyle{{q_{Lb}} \over {k_e}}L_{be}^{^2 } $$

$$\;{P}^{\prime}_e = n_{Lb}L_{be}-( f_P + n_P) P_e$$

$$\;A_e^{\prime} = \displaystyle{{n_P} \over 2}P_e-d_aA_e + \displaystyle{1 \over 2} \times \displaystyle{1 \over {l_v}}A_{2e}-m_{eo}A_e$$

$$\;A_{2e}^{\prime} = m_{2oe}A_{2o}-d_aA_{2e}-\displaystyle{1 \over {l_v}}A_{2e}$$

$$\;A_{3e}^{\prime} = \displaystyle{1 \over 2} \times \displaystyle{1 \over {l_v}}A_{2e}-d_aA_{3e}$$

Outdoor temperature

A model derived from daily average temperature data from each city represents annual outdoor weather patterns (U.S. Climate Data). Temperatures in these cities range from annual lows of below 0 °C in early January to highs of over 30 °C in July and August, making the viability of mosquito survival highly variable. A truncated Fourier series is used to fit annual daily mean temperature data. Expressions for all five cities are in Table 1.

Indoor temperature

Because indoor spaces are climate-controlled, the indoor habitat is assumed to remain at a constant temperature year-round. Temperatures in the indoor habitat are defined at a constant 21 °C, representing the average indoor temperature of climate-controlled American households.

Enclosed temperature

The relationship between underground and surface temperatures provides a proxy for the insulating effect of enclosed habitats. In a study of underground wine storage areas, Tinti et al. report an external temperature amplitude of 15.5 °C and an underground temperature amplitude of 7.6 °C, implying that the ratio of underground to above-ground fluctuations is 0.49 (Tinti et al., Reference Tinti, Barbaresi, Benni, Torreggiani, Bruno and Tassinari2015). In addition to scaling the amplitude of the outdoor Fourier function by this value, a lag of two weeks between outdoor and enclosed temperatures is introduced. This modification is based upon the assumption that insulated spaces retain heat and cold for longer periods than exposed environments, as well as Naylor's finding that underground soil reached its annual peak temperature about 14 days after the soil surface in Indiana (Naylor and Gustin, Reference Naylor and Gustin2017). The resulting function determines the temperature of the enclosed habitat, given for all cities in Table 1. Figure 2 shows the resulting temperature patterns for all five cities.

Figure 2. A comparison of outdoor, indoor, and enclosed temperature models for all five cities. The blue (Outdoor) curve shows the best-fit Fourier series, the orange (Indoor) line shows constant temperature in climate-controlled spaces, and the yellow (Enclosed) curve is modified to represent a reduced amplitude and time lag for enclosed temperatures.

Egg production rates (e_b, p_wo, p_wi)

Egg production is determined by the proportion of eggs laid in wet habitats (p _w), the number of egg-laying adult females (A ₂), and the number of eggs produced per female per day (e _b). For the adults remaining in the indoor and outdoor habitats during oviposition, the proportion laying in aquatic habitat is taken to be very close to one unless there is no aquatic habitat available, using the Holling Type II functional response in Table 1. In enclosed areas, a 100% wet laying proportion is assumed.

Costa et al. report the mean number of eggs laid daily per adult female under two humidity conditions at each of three temperatures (Costa et al., Reference Costa, Santos, Correia and Albuquerque2010). These results are averaged at 25, 30, and 35 °C and the number of eggs laid daily is set to zero at 10 and 40 °C given Yang observed that oviposition did not occur at or beyond these temperatures (Yang et al., Reference Yang, Macoris, Galvani, Andrighetti and Wanderley2009). A best-fit Gaussian function is fit to these data to describe the number of eggs laid per female per day by temperature, which is used to derive e _b for each temperature and habitat, stated in Table 1. Values of this function are shown by temperature in fig. 3a.

Figure 3. Curve fitting sessions to determine the best-fit values for temperature-dependent equation parameters. The big larva maturation rate, oviposition cycle length, and eggs laid daily per female peak in the middle of the temperature range, between 25 and 30 °C. The remaining two maturation rates peak at warmer temperatures of around 35 °C. Death rates are lowest between 20 and 30 °C, indicating that moderate temperatures are most conducive to daily survival.

Egg flooding and eclosing rates (n_ed, n_ew)

Oviposition occurs in either a wet or a dry area according to the proportion of adult females laying in wet habitats. While eggs can remain viable for several months under dry conditions, they must become submerged in order to eclose (Focks et al., Reference Focks, Haile, Daniels and Mount1993). Assuming that breeding takes place in primarily manmade containers, and that human activity is the main source of flooding, one might expect containers to be filled every other week through lawn watering, sprinklers, the filling of animal dishes, etc. both indoors and outdoors, giving a daily flooding rate (n _Ed) of 0.071. There is no enclosed habitat flooding rate, as all eggs in this habitat are initially laid in wet areas.

For eggs laid in wet areas, and for originally dry eggs that have become submerged, transition out of the egg stage is determined by the eclosion rate (n _Ew). Focks et al. report a daily mean eclosion rate of 59.6% among wet eggs when submerged in water above 22 °C; however, they acknowledge that this threshold may be too high (Christophers, Reference Christophers1960, Focks et al., Reference Focks, Haile, Daniels and Mount1993). As eclosion rates are relatively fast, the assumption was made that the transition from wet to dry is negligible and is omitted in the model.

Egg death rates (q_Ed, q_Ew)

Faull and Williams report the mean survival time of A. aegypti eggs at varying levels of warmth and dryness to show the ongoing survival and viability of eggs laid in dry locations. On average, the eggs could survive 187.4 days under dry conditions and 229.3 days under wet conditions (Faull and Williams, Reference Faull and Williams2015), inverted to give death rates of 0.0053 (q _Ed) and 0.0044 (q _Ew) for dry and wet eggs, respectively.

Maturation rates for larvae and pupae (n_Ls, n_Lb, n_P)

In the larval and pupal stages, maturation parameters are temperature-dependent. Tun-Lin et al. studied maturation times and survival rates at five temperatures, ranging from 15 to 35 °C, and found that the time to maturation decreased consistently as temperatures rose within this range, consistent with other studies (Sharpe and DeMichele, Reference Sharpe and DeMichele1977, Rueda et al., Reference Rueda, Patel, Axtell and Stinner1990, Tun-Lin et al., Reference Tun-Lin, Burkot and Kay2000). A Gaussian curve is fit to Tun-Lin et al. in order to describe temperature-dependent maturation rates for each stage. Parameter values for the best-fit equation at each stage are recorded in Table 1 and shown in fig. 3b, d.

Temperature-dependent death rates for larvae and pupae (f_s, f_b, f_P)

Tun-Lin et al.'s observed survival rates and maturation times at each of five temperatures lead to survival half-lives, giving death rates for each temperature. A polynomial is fit to these death rates, given in Table 1. Figure 3e affirms that the values of D as determined by this polynomial remain greater than zero both within and beyond the temperature range included in Tun-Lin et al.'s study (Tun-Lin et al., Reference Tun-Lin, Burkot and Kay2000).

Death rate for pupae, density-dependent death rates for larvae (q_Ls, q_Lb)

Studies by Barbosa et al. and Moore et al. affirm the importance of density-dependent development parameters. Barbosa et al. observed eggs at eight different density levels and determined that high-density groups had higher mortality rates as a result of lessened food availability. Barbosa et al. found that crowding had a non-linear effect on survival rates, affirming the adoption of quadratic density-dependent death rates from the Anopheles gambiae model (Barbosa et al., Reference Barbosa, Peters and Greenough1972, Wallace et al., Reference Wallace, Prosper, Savos, Dunham, Chipman, Shi, Ndenga and Githeko2017). In another study of larval density, Moore et al. observed the production of growth retardant factors (GRF) in a colony in Puerto Rico. Moore et al. concluded that nutrition, not density, influences the production of GRF, implying that the density-dependent factors for which the model accounts are primarily physical rather than chemical (Moore and Whitacre, Reference Moore and Whitacre1972). Based on findings from these studies, this model considers the density-dependent death rate as a grouping of the combined effects of predation and crowding.

Southwood et al. observed mean daily adult emergence rates, as well as counts of eggs, larvae, and pupae appearing in manmade containers. Water jars were the primary breeding areas for mosquitos, with an average of 54.84 adults emerging daily from 100 jars (Southwood et al., Reference Southwood, Murdie, Yasuno, Tonn and Reader1972). The estimated surface area of 1 m² for the average water jar in Thailand is used to calculate a daily mean emergence rate of 0.5484 adults per m² of water available for breeding (Visvanathan et al., Reference Visvanathan, Vigneswaran and Kandasamy2015). This rate corresponds to n _pP in equation 6 of the model.

The remaining equations are solved at equilibrium at a constant temperature of 21 °C, which is the defined indoor temperature and falls within the range of outdoor temperatures in all cities. Southwood et al.'s emergence rate provides a constant value for P at this temperature. Southwood et al. report larval counts over the course of one year in water jars, and these values are averaged to derive a ratio of small to big larvae of 389/190. Based on these, algebraic manipulations of the equations for pupae and larvae lead to the value for q _Lb reported in Table 1. The same calculations for large and small larvae at equilibrium yield the value of q _Ls based on the ratio of wet eggs to small larvae. Using these values for q _Ls and q _Lb, the model reproduces the instar ratios from Southwood et al.'s field study when the system is solved at equilibrium.

Adult transition and death rates (n _a, d _a, l _v)

The pupal maturation rate (n _P) determines the rate of entry into the feeding adult stage. This value is halved to include only adult females, the only group that feeds and reproduces, assuming a 1:1 sex ratio (Sheppard et al., Reference Sheppard, McDonald, Tonn and Grab1969). In addition to maturing from the aquatic stages into a first feeding cycle, vectors re-enter the feeding adult stage between reproductive periods to begin a second cycle (Judson, Reference Judson1967).

The feeding population decreases in part as a result of transition into the egg-laying stage. Based on Costa et al.'s observation that mosquitos did not lay eggs within the first three days of reaching adulthood under any temperature conditions, the rate of maturation out of the feeding stage (n _a) is taken to be 1/3 (Costa et al., Reference Costa, Santos, Correia and Albuquerque2010). The daily adult death rate (d _a) of 0.11 corresponds to a mean daily adult survival rate of 89% (McDonald, Reference McDonald1977).

Adults transition into the egg-laying stage from the feeding stage, and the egg-laying population decreases as a result of the end of each oviposition cycle and death. The length of an oviposition cycle is temperature-dependent (Costa et al., Reference Costa, Santos, Correia and Albuquerque2010). A Gaussian function, l_v, is fit to Costa et al.'s oviposition cycle data to describe the length of the egg-laying period by temperature, recorded in Table 1. Values are shown in fig. 3f.

At each temperature, the rate at which adults exit the egg-laying stage – either to begin another feeding period or to complete the final oviposition cycle – is taken as the inverse of this value (1/l _v). The death rates of egg-laying and post-egg-laying adults take on the same constant value as the death rate of feeding adults (d _a).

Migration rates (m_oi, m_io, m_eo, m_2io, m_2oi, m_2oe)

Because of the limited availability of data describing mosquito migration patterns among habitats, estimated migration rates are based on the vector's needs in each stage of the gonotrophic cycle. Migration rates in the feeding stage are determined by the availability of humans to bite. It is assumed that all feeding mosquitos in the enclosed habitat migrate to the outdoor habitat (m _eo = 1) in order to feed. Migration rates between the indoor and outdoor habitats are estimated based on human activity. Given that the average person spends about two hours outdoors per day, and under the simplifying assumption that this time is evenly distributed, it is assumed that 8.3% of humans are outdoors and 91.7% are indoors at any given time (Diffey, Reference Diffey2011). These values are divided by three days, the average length of the feeding period, to derive daily outdoor-to-indoor and indoor-to-outdoor feeding migration rates (m _oi, m _io).

During the egg-laying stage, migration among habitats is treated as a function of the available wet oviposition area. The constants k _o, k _i, and k _e represent the areas of outdoor, indoor, and enclosed aquatic habitat, respectively, resulting in a total wet laying area of k _tot = k _o + k _i + k _e. In a study of oviposition preferences, Edman et al. found that only 5.8% of initially gravid A. aegypti mosquitos were recaptured in their original locations when left to lay in entirely dry environments (Edman et al., Reference Edman JD, Scott, Costero, Morrison, Harrington and Clark1998). This finding suggests a high rate of departure from each habitat in the absence of wet laying area, which is incorporated into the migration rates.

Edman et al. indicate that α = 94.2% of adults leave each habitat during the oviposition period in the complete absence of wet laying area (Edman et al., Reference Edman JD, Scott, Costero, Morrison, Harrington and Clark1998). For indoor to outdoor migration, this value is multiplied by (k _o/(k _o + k _i)), the proportion of the combined indoor and outdoor habitats made up by the outdoor habitat. This rate is divided by l_v, the length of the oviposition period, to represent daily migration.

The remaining two oviposition migration rates describe migration from the outdoor habitat to indoor and enclosed areas. For each of these rates, α is multiplied by (1 − (k _o/k _tot)), yielding a rate that is inversely related to the proportion of the total wet laying area that the outdoor aquatic habitat comprises. The outdoor-to-indoor and outdoor-to-enclosed rates are multiplied by (k _i/(k _i + k _e)) and (k _e/(k _i + k _e)), respectively. These equations are summarized in Table 1.