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Volume 29, Number 5—May 2023
Research

Leishmania donovani Transmission Cycle Associated with Human Infection, Phlebotomus alexandri Sand Flies, and Hare Blood Meals, Israel1

Author affiliations: Ministry of Health Central Laboratories for Public Health, Jerusalem, Israel (L. Studentsky, L. Orshan, I. Ben Avi, D. Diaz, S. Elbaz, M. Davidovich-Cohen); The Hebrew University of Jerusalem, Rehovot, Israel (L. Studentsky, G. Baneth); Ministry of Health National Laboratory for Public Health, Tel Aviv, Israel (F. Akad); Soroka University Medical Center, Beer-Sheba, Israel (O. Sagi); Israeli Ministry of Environmental Protection, Jerusalem (G. Zagron); Maccabi Healthcare Services, Tel Aviv (L. Valinsky)

Cite This Article

Abstract

Cutaneous leishmaniasis caused by Leishmania major or L. tropica and visceral leishmaniasis caused by L. infantum have been reported in Israel. We collected Phlebotomus spp. sand flies in the Negev desert of southern Israel to identify circulating Leishmania spp. Of 22,636 trapped sand flies, 80% were P. alexandri. We sequenced Leishmania-specific internal transcribed spacer 1 fragments and K26 genes. Of 5,019 Phlebotomus female sand flies, 2.5% were Leishmania DNA–positive; 92% of infections were L. donovani. Phylogenetic analyses showed separate clustering of L. donovani and L. infantum. P. alexandri flies positive for L. donovani harbored blood meals from European hares. Leishmania DNA isolated from a patient with cutaneous leishmaniasis who lived in the survey area was identical to L. donovani from P. alexandri flies. We report circulation of L. donovani, a cause of visceral leishmaniasis, in southern Israel. Prompt diagnosis and Leishmania spp. identification are critical to prevent leishmaniasis progression.

Zoonotic leishmaniasis is endemic to Israel. Leishmania tropica, L. major, and L. infantum infect humans in different areas of Israel and circulate through distinct zoonotic transmission cycles (1). Cutaneous leishmaniasis (CL) is caused by L. major, which is transmitted by Phlebotomus papatasi sand flies, and L. tropica, which is transmitted by P. sergenti and P. arabicus sand flies. Canine leishmaniasis and human visceral leishmaniasis (VL) are caused by L. infantum in Israel, and the putative vectors are P. perfiliewi, P. syriacus, and P. tobbi sand flies (19). Reservoirs for L. major are sand rats (Psammomys obesus), gerbils (Gerbillus dasyurus), jirds (Meriones crassus and M. tristrami), and possibly also voles (1013), whereas rock hyraxes (Procavia capensis) are considered the animal reservoir for L. tropica in Israel (14). Domestic dogs (Canis lupus familiaris), jackals (C. aureus), foxes (Vulpes vulpes), and wolves (C. lupus) are recognized reservoir hosts for L. infantum (15).

A substantial increase in CL incidence has been recorded since 2002, and endemic transmission has occurred in areas of Israel where it was previously unknown (6,16,17). Although not life-threatening, CL is a considerable public health problem in Israel; CL is diagnosed in hundreds of new patients annually. During 2001–2018, CL incidence rates increased 7-fold, from 0.4 to 2.9/100,000 population; a peak was observed in 2012, when the mean annual incidence increased to 4.4/100,000 population (18,19). Our study combines results from sand fly surveys, Phlebotomus spp. blood meal analysis, and human patient clinical data from the mountainous area of central Negev in southern Israel during the summer months of 2018–2020. We found a fourth leishmaniasis transmission cycle associated with human illness.

Materials and Methods

Study Area and Sand Fly Trapping

Figure 1

Locations of Phlebotomus spp. sand fly collection sites within the central Negev region of Israel in study of Leishmania donovani transmission cycle associated with human infection, Phlebotomus alexandri sand flies, and hare blood meals. We collected sand flies outdoors in August 2018, September 2019, and August 2020 by using modified traps from the US Centers for Disease Control and Prevention. The traps operated without light and were powered by 2 AA (1.2V) rechargeable batteries and baited with ≈1 kg dry ice. Traps were placed in an updraft vertical position overnight; openings were ≈10 cm above the ground, and collection cups hung above the motor and fan. Different colored circles indicate sites where specific Leishmania spp. infections were identified in trapped Phlebotomus sand flies. Empty circles indicate sites where sand flies were negative for Leishmania spp. Inset shows location of the survey area in Israel (red box).

Figure 1. Locations of Phlebotomus spp. sand fly collection sites within the central Negev region of Israel in study of Leishmania donovani transmission cycle associated with human infection, ...

We conducted our study in the mountainous desert area of central Negev in southern Israel (Figure 1). In this region, elevations range from 50 to 1,037 m above sea level, large differences occur between peak daytime and nighttime temperatures, and annual average precipitation is 30–150 mm (20,21). We collected sand flies outdoors in August 2018, September 2019, and August 2020 by using modified traps from the US Centers for Disease Control and Prevention. The traps operated without light and were powered by 2 AA (1.2V) rechargeable batteries and baited with ≈1 kg dry ice. We placed traps in an updraft vertical position overnight; openings were ≈10 cm above the ground, and collection cups hung above the motor and fan (22,23).

Identification and Sample Preparation

We transferred live sand fly catches to the laboratory, which we then chilled and processed. We counted dead sand flies and sorted by sex, identifying all male flies at the species level by using specific morphologic keys for genitalia (24,25). We kept all engorged females and <10–15 unfed females from each trap individually. If the number of female sand flies in the trap was >15, we pooled those flies with others in groups of 20 specimens each. We noted the blood meal size and freshness for each engorged female (26). We stored all female fly specimens in collection microtubes at −80°C until DNA extraction.

Molecular Analysis by Real-Time PCR, HRM Assay, and Sequencing

We extracted total DNA from sand fly samples by using the QIAsymphony DSP DNA Mini Kit and QIAsymphony SP robot (QIAGEN, https://www.qiagen.com). We homogenized the samples for 5 min in 50 μL lysis buffer and stainless steel beads by using a TissueLyser II instrument (QIAGEN). The lysis buffer contained DNase- and proteinase-free RNaseA (ThermoFisher Scientific, https://www.thermofisher.com), proteinase K, and ATL tissue lysis buffer (QIAGEN). After homogenization, we added 200 μL lysis buffer to each samples and incubated at 56°C for 2 h. We performed centrifugation and transferred the samples directly to the robot. We extracted DNA in accordance with the manufacturer’s instructions and eluted the DNA in 100 μL of elution buffer.

We performed all real-time PCR reactions by using a Roche LightCycler 96 (Roche, https://www.roche.com) and AccuMelt HRM SuperMix (Quantabio, https://www.quantabio.com). We analyzed all female sand flies for Leishmania spp. infection and single and engorged female flies to determine Phlebotomus sand fly species and blood meal source. We performed high-resolution melting (HRM) assays at the final step of each real-time PCR. We performed amplicon dissociation analysis by capturing fluorescence signals in 0.1°C/s increments and holding for 60 s in each range of the melting curve (60°C–85°C for sand fly species and blood meal detection assays or <95°C for Leishmania PCR). Sanger sequencing was performed at the Center for Genomic Technologies at Hebrew University of Jerusalem.

We screened all female sand flies for Leishmania DNA and identified parasite species by amplifying an internal transcribed spacer (ITS) 1 rRNA fragment with ITS1–219 PCR primers (Appendix Table 1) and by using the HRM assay (27). For PCR controls, we extracted DNA from parasite promastigote cultures of international reference strains: L. major (MHOM/PS/1967/JerichoII), L. tropica (MHOM/IL/1990/P283), L. infantum (MHOM/SD/62/2S), L. donovani (MHOM/SD/1962/1S-CLD2), and L. aethiopica (MHOM/ET/1972/L102). High purity water for molecular biology (Bio-Lab, http://www.biolab-chemicals.com) was used as a negative control.

We included DNA isolated from skin lesions from 4 patients who had leishmaniasis diagnosed at the parasitology laboratory at Soroka Medical Center, Beer-Sheba, Israel; leishmaniasis was caused by L. donovani/L. infantum complex in those patients (Table 1). Leishmaniasis was diagnosed at the hospital by using multiplex real-time PCR with 5 probes for the ITS region of Leishmania sp. (28,29). We analyzed the samples further at the Ministry of Health by using real-time PCR–HRM amplification of the ITS1 fragment and ITS region and then sequencing.

We amplified the entire 1,020-bp ribosomal ITS region from Leishmania-positive field, clinical, and control samples by using PCR primers LITSR and LITSV (Appendix Table 1). If the entire ITS region was not successfully amplified with LITSR and LITSV primers, we used an internal pair of primers, L5.8S and L5.8SR, to amplify ITS1 and ITS2 separately (30). We performed ITS1 amplicon sequencing for 12 of the positive samples, and the entire ITS region was sequenced from 6 unfed and 3 engorged females, 3 pooled Phlebotomus spp. samples, all 4 human samples, and 4 Leishmania-positive controls. We amplified the repeat region of the L. donovani and L. infantum HASPB (known as K26) gene for additional separation of L. donovani complex–positive samples by using primers K26F and K26R (31).

To identify Phlebotomus spp., we amplified a 368–393-bp fragment of the cytochrome b gene by using a universal primer set designed for this study (cytb-F and cytb-R; Appendix Table 1). The specificity of the designed primers was tested against DNA sequences from hematophagous arthropods, including sand flies, mosquitoes, and ticks. Male sand flies identified at the species level by using morphologic characteristics were used as positive controls and molecular biology grade water was used as a negative control. We analyzed all individual samples, and 1 third of samples from each melting curve pattern were sequenced.

We identified blood meal sources in Phlebotomus sand fly specimens by amplifying a 500-bp segment of host 12S and 16S mitochondrial rRNA genes by using modified vertebrate universal primers N12–16F and N12–16R (32). We included negative (water) and positive (100 ng of human DNA) controls in each PCR. We sequenced 50 samples that represented all HRM curve patterns and all female sand flies containing blood meals that had a melting curve of a rare host (<5 samples).

Figure 2

Phylogenetic analysis of Leishmania internal transcribed spacer 1 rRNA fragments in study of Leishmania donovani transmission cycle associated with human infection, Phlebotomus alexandri sand flies, and hare blood meals, Israel. Leishmania-specific internal transcribed spacer 1 rRNA fragments (201 bp) were amplified by PCR from P. alexandri sand flies, pooled female Phlebotomus spp. flies, and patient samples and then sequenced. Tree was constructed by using the maximum-likelihood method and Tamura 3-parameter model, estimated by using the Aikaike information criterion (33). Dendogram includes sequences from L. donovani and L. infantum isolated from sand flies and clinical samples in this study compared with Leishmania spp. reference controls and GenBank sequences from Israel and other countries. Tree shows substantial separate clustering of L. infantum (boostrap 94%) and L. donovani (bootstrap 89%) sequences. Empty circles are Leishmania international reference strains, black triangles are the 10 sequences from our study deposited in GenBank, and black circles are additional L. infantum–positive sand flies samples from Israel. Available GenBank sequences for L. major, L. tropica, L. infantum, and L. donovani from Israel and other countries are also included. GenBank accession numbers, Leishmania spp., isolate source, and country are indicated. Only bootstrap values >70% are shown. Not to scale.

Figure 2. Phylogenetic analysis of Leishmania internal transcribed spacer 1 rRNA fragments in study of Leishmania donovani transmission cycle associated with human infection, Phlebotomus alexandrisand flies,...

We used DNA from Leishmania reference strains, male sand fly specimens identified by morphologic characteristics, and human blood as templates for real-time PCR and HRM curve standardization. Each species produced a unique melting curve that was easily distinguishable from other species and consistent with observed nucleotide differences (Appendix Figures 13). We compared normalized HRM curves of field samples with the positive control included in each PCR, which enabled species determination (27). We validated species identification by sequencing 1 third of the samples; complete matches were observed for speciation by HRM curve analysis and DNA sequencing.

We aligned and corrected nucleotide sequences by using BioNumerics version 8.0 software (Applied Maths, https://www.applied-maths.com) and compared sequences against the GenBank database by using BLASTN (http://blast.ncbi.nlm.nih.gov). We identified Leishmania spp., blood meal sources, and sand fly species on the basis of >98% identity with sequences obtained during the BLAST search. We submitted sequences of the ITS1 fragments and entire ITS and K26 regions obtained in this study to GenBank (Appendix Table 2).

Figure 3

Phylogenetic analysis of entire Leishmania internal transcribed spacer region in study of Leishmania donovani transmission cycle associated with human infection, Phlebotomus alexandri sand flies, and hare blood meals, Israel. Leishmania-specific internal transcribed spacer region (988 bp) was amplified by PCR from P. alexandri sand flies, pooled female Phlebotomus spp. flies, and patient samples and then sequenced. Tree was constructed by using by using the maximum-likelihood method and Tamura 3-parameter model of all relevant Leishmania spp. and Trypanosoma cruzi as an outgroup. Sand fly and clinical samples from this study (black triangles), L. infantum isolates from Israel (black circles), Leishmania international reference strains (empty circles), and available GenBank Leishmania sequences are shown. GenBank accession numbers, isolate source, and country of origin are shown for each sequence. Only bootstrap values >70% are shown next to branches. Not to scale.

Figure 3. Phylogenetic analysis of entire Leishmania internal transcribed spacer region in study of Leishmania donovani transmission cycle associated with human infection, Phlebotomus alexandrisand flies, and...

Figure 4

Phylogenetic analysis of Leishmania K26 gene in study of Leishmania donovani transmission cycle associated with human infection, Phlebotomus alexandri sand flies, and hare blood meals, Israel. Leishmania-specific K26 gene fragment (348 bp) was amplified by PCR from P. alexandri flies, pooled female Phlebotomus spp. flies, and patient samples and then sequenced. Tree was constructed by using the maximum-likelihood method and Hasegawa-Kishino-Yano model. K26 phylogenetic analysis shows separation between L. infantum and L. donovani. Sand fly and clinical samples from this study (black triangles), L. infantum isolates from Israel (black circles), Leishmania international reference strains (empty circles), and available GenBank Leishmania sequences are shown. GenBank accession number, isolate source, and country of origin are shown for each sequence. Only bootstrap values >70% are shown next to branches. Not to scale.

Figure 4. Phylogenetic analysis of Leishmania K26 gene in study of Leishmania donovani transmission cycle associated with human infection, Phlebotomus alexandrisand flies, and hare...

We constructed phylogenetic trees on the basis of marker gene sequences in this study and relevant sequences of other Leishmania spp. deposited in GenBank. We used MEGA X software (33) to infer phylogenetic trees after nucleotide sequence alignment was performed by using ClustalW software (http://www.clustal.org) and maximum-likelihood and neighbor-joining algorithms. We used 1,000 bootstrap replicates to determine percentages of replicate trees. We constructed a phylogenetic tree composed of 45 analyzed partial sequences of the ITS1 locus, including sequences of Leishmania spp. from Israel and other countries deposited in GenBank and Trypanosoma cruzi as an outgroup (Figure 2). We constructed a second tree that included 30 nearly complete ITS sequences of all relevant Leishmania spp. and T. cruzi as an outgroup (Figure 3) and an additional phylogenetic tree that included 20 K26 gene sequences of L. donovani complex–positive samples (Figure 4).

Results

We collected 22,636 Phlebotomus spp. sand fly specimens (15,720 female and 6,916 male; sex ratio 2.3) during 7 trapping nights by using 118 traps placed at 94 sites. After identifying all male and 894 (6%) female flies, we found the catches consisted of 5 species. The most abundant sand fly species were P. alexandri (80%), P. kazeruni (14.4%), P. sergenti (3.1%), P. papatasi (2.2%), and P. syriacus (0.3%) (Table 2).

Among the 4,140 unfed female sand flies tested in 210 pools,we found 41 pools were positive for Leishmania spp. In addition, 6/688 single female flies and 4/206 engorged female flies were positive for Leishmania spp. Of the 51 Leishmania-positive samples, the HRM curves of 47 (36 pools, 6 single females, and 3 engorged female flies) were similar to the HRM curve of the L. donovani control (Table 3; Appendix Figure 1). The HRM curves for 2 pooled fly samples from 2018 were identical to the HRM curve of the L. tropica control. One pooled fly sample and 1 engorged female fly collected in 2020 had an HRM curve identical to the L. major control. The ITS1–PCR sequences of 20 samples (11 pools and all 9 single and engorged females) that had HRM curves similar to the L. donovani control HRM curve were also 100% identical to the L. donovani control sequence.

Leishmaniasis was diagnosed in 4 human patients (Table 1). The ITS1 HRM curve and sequence from patient 4 with CL were similar to the L. donovani control and 47 L. donovani–positive Phlebotomus spp. samples. The ITS1 HRM and sequences from patients 1 and 2 with VL and patient 3 with CL were similar to the L. infantum control. Alignment of ITS1 sequences from L. infantum and L. donovani controls, 3 representative sand fly samples showing HRM identical to L. donovani, and the 4 patient samples showed clustering into 2 distinct groups. The first group comprised the L. donovani control, 3 sand fly samples, and patient 4. The second group comprised the L. infantum control and samples from patients 1, 2, and 3. The difference between the groups was at position 71–74 in ITS1; the L. donovani group had a 4-nt (ATAT) insertion that was missing in the L. infantum–positive samples. A comparison of ITS1 sequences with those in GenBank showed 100% query coverage and 99.65%–100% identity with GenBank sequences for L. infantum and L. donovani from various countries (data not shown).

We aligned DNA sequences from the entire ITS region obtained from Leishmania–positive P. alexandri samples from our study and the L. infantum and L. donovani controls (Appendix Figure 4). We found 2 additional regions containing polymorphic sites that distinguished between L. infantum and L. donovani: a 2-nt (GG) deletion at position 724–725 and 1-nt (G) insertion at position 817 in the L. donovani sequence.

We constructed a phylogenetic tree of ITS1 rRNA fragments of Leishmania sequences obtained from P. alexandri flies, pooled female Phlebotomus spp. flies, and patient samples from this study. We compared those sequences with Leishmania spp. controls and GenBank sequences from Israel and other countries. The tree showed substantial separate clustering of L. infantum (boostrap 94%) and L. donovani (bootstrap 89%) sequences (Figure 2). Phylogenetic analysis of the entire ITS region showed separate clustering of L. infantum (bootstrap 84%) and L. donovani (bootstrap 95%) sequences (Figure 3). K26 phylogenetic analysis also showed separation between L. infantum and L. donovani (Figure 4).

We identified the blood meal source for 182/206 (88%) engorged female sand flies that represented the 4 most abundant sand fly species within the study area. We observed 7 types of HRM curves. We compared blood meal sequences with GenBank sequences and determined similarities between HRM curves. We identified European brown hare (Lepus europaeus) blood in 126 (69.2%) flies, onager (Equus hemionus) blood in 33 (18.3%) flies, gazelle (Gazella dorcas) blood in 16 (8.8%) flies, and domestic dog (C. lupus familiaris) blood in 4 (2.2%) flies; 1 female sand fly each contained blood from either a fat sand rat (Psammomys obesus), fox (V. vulpes), or human (Table 4). Hare blood was the dominant blood meal found in all 4 Phlebotomus spp. flies: P. papatasi, 38%; P. sergenti, 67%; P. alexandri, 71%; and P. kazeruni, 89%. The 12S–16S hare blood meal sequences were 99.8% similar to L. europaeus hares and only 95.3% similar to L. capensis hares.

Of the 47 Phlebotomus spp. sand fly samples with HRM curve patterns and sequences similar to the L. donovani control, 9 were single P. alexandri female sand flies, 3 of which were engorged with hare blood. Of the 2 Phlebotomus spp. samples positive for L. major, 1 was in a single engorged P. papatasi female sand fly that had an unsuccessful blood meal identification. The 2 identified L. tropica samples were from pooled female sand flies.

Discussion

We found a fourth transmission cycle of leishmaniasis in the central Negev region of southern Israel. On the basis of molecular analysis of the ITS region and K26 gene and phylogenetic analysis, we concluded that the parasite found in patient 4, who lives in the survey area, and in P. alexandri sand flies was L. donovani sensu stricto. We found that L. infantum was the cause of illness in the other 3 patients with leishmaniasis. A case report describing patient 4 was published in 2016; the authors concluded that the infecting parasite was likely L. infantum because of prevailing knowledge of endemic Leishmania transmission in Israel (29). An earlier study reported another patient from the Arava region of central Negev, close to where patient 4 lives, who had symptoms of both CL and VL (34). The cause of infection was identified as L. donovani; the authors noted that this infection was unusual because L. donovani was not known to circulate in Israel. The earlier study substantiates our findings of L. donovani in both sand flies and another human patient within the same geographic area. L. infantum was identified as the causative agent in the other 3 patients in our study and was also described in canines in Israel (1).

The high abundance of P. alexandri sand flies within the study area and the association with L. donovani infections suggest that the P. alexandri sand fly is the putative vector of L. donovani in Israel. P. alexandri flies have been associated with L. donovani sensu latu transmission in other parts of the Old World. Natural infection by L. donovani was found in field-collected P. alexandri sand fly specimens in China, and inoculation of hamsters with those parasites caused VL (35). Another study reported the susceptibility of P. alexandri to artificial infection with L. donovani isolated from human patients in China (36).

We found blood meals from European brown hares in ≈70% of engorged female Phlebotomus sand flies in our study. The high feeding rates on hares, presence of L. donovani in female P. alexandri sand flies engorged with hare blood and illnesses reported in humans infected with L. donovani suggest a zoonotic L. donovani transmission cycle in Israel. Those data suggest that the hare could be a potential reservoir and P. alexandri flies could be the putative vector for L. donovani. The role of hares as a reservoir host for L. donovani requires further investigation; however, a related hare species, Lepus granatensis, was reported as a potential sylvatic reservoir for L. infantum in a leishmaniasis outbreak in Madrid, Spain (37,38). Furthermore, studies in Greece and Italy detected L. donovani complex infection in L. europaeus hares (39,40), providing support for hares as a potential reservoir for L. donovani in Israel. Dogs were identified as reservoirs for L. donovani in India, Sudan, and Ethiopia, and different rodent species have been identified as possible reservoirs of Leishmania spp. from the L. donovani complex (4148). However, no L. donovani infections in canines and rodents have been reported in Israel; infections in sand fly blood meals found in our study do not implicate those hosts in the local life cycle of L. donovani.

In conclusion, we found circulation of L. donovani in the Negev region of southern Israel that was associated with cutaneous lesions in humans. We determined that P. alexandri was the putative sand fly vector and that hares were the main reservoir host of L. donovani. We found 2 distinct Leishmania spp. in the L. donovani complex in Israel. Previously, the few reported human cases of CL resulting from L. donovani infections were attributed to either L. infantum or nonautochthonous infections. Analysis of patient samples in our study indicates that, in addition to L. major and L. tropica (the known agents causing CL), L. donovani is also a cause of autochthonous CL in Israel. Our results suggest that CL in Israel can be caused by L. donovani, a primary cause of VL. Therefore, prompt diagnosis, identification of the Leishmania sp., and treatment with drugs intended for visceral leishmaniasis, such as pentavalent antimonials or liposomal amphotericin B (49), are critical to prevent disease progression and death among patients with leishmaniasis.

Ms. Studentsky is a PhD student at the Koret School of Veterinary Medicine, The Hebrew University of Jerusalem, Israel, and works at the Medical Entomology Laboratory, Ministry of Health, Jerusalem. Her primary research interests focus on leishmaniasis, sand fly surveillance, and vector competence.

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Acknowledgments

We thank Simha Shilo, Anna Sarner, and Arik Levy for assisting with sand fly sorting; Aviv Rashti, Anat Berkowitz, Karin Cohen, and Alina Bazarski for assisting with human sample analysis; Itay Naveh and Dan Ish-Shalom for supporting and participating in the fieldwork; Heather Schnur for editorial remarks; Yaarit Nachum-Biala for sharing professional knowledge of phylogenetic tree construction; and Guy Nizry for helping with map creation.

This study was supported by internal funding from the Ministry of Health, Jerusalem, Israel.

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DOI: 10.3201/eid2905.221657

Original Publication Date: April 13, 2023

1Data from this study were presented at the Israeli Society for Parasitology, Protozoology and Tropical Diseases Annual Meeting; March 21, 2022; Kfar Hamaccabiah, Ramat Gan, Israel.

Table of Contents – Volume 29, Number 5—May 2023

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Liora Studentsky, Laboratory of Medical Entomology, Ministry of Health, Elaiv Yaakov 9, Jerusalem 9546208, Israel

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