We were interested to see Roberts, et. al study [1] which explored whether a hub-and-spoke model using a femtosecond laser (FL) could increase the efficiency and reduce the cost of cataract surgery.

Although the model was not cost-effective when compared to conventional phacoemulsification surgery, more efficient models should continue to be assessed. The Aravind Eye Care system uses an alternative hub-and-spoke model. Instead of separate operating theatres (OTs), the physician alternates between two beds in a single OT. This model, and the safe reuse of surgical supplies, results in phacoemulsification cataract surgery with excellent outcomes at 1/20th the cost and carbon emissions [2-4].

Roberts, et. al recommend that the ideal number of OTs to maximise the utility of an FL in a hub-and-spoke model is four. However, they were not able to evaluate the effect of adding additional OTs to their model as they only had two OTs. We suggest that adopting the Aravind model to jump to the 1:4 model without further building work could significantly alter this paper’s conclusions. We would be interested to know if elements of the Aravind model, two beds one theatre, could be adopted in their setting.

On average patients receiving FLACS spent 5.85±1.99 mins in the laser suite (LS), implying a potential throughput of between 8 and 15 cases per hour. We are interested to know the authors views on the the limits of the FL and what impact the adoption of bilateral sequential cataract surgery might have on their cost estimates, [5] assumptions about throughput and the potential viability of more intensive 1:6 or 1:8 models.

Finally, maintaining training standards while improving efficiency is a challenge and we would be interested in the authors views on how training is best catered for within their different hub and spoke models.

References
1. Roberts HW, Wagh VK, Mullens IJM, Borsci S, Ni MZ, O’Brart DPS. Evaluation of a hub-and-spoke model for the delivery of femtosecond laser-assisted cataract surgery within the context of a large randomised controlled trial. Br. J. Ophthalmol. 2018 doi: 10.1136/bjophthalmol-2017-311319
2. Thiel CL, Schehlein E, Ravilla T, et al. Cataract surgery and environmental sustainability: Waste and lifecycle assessment of phacoemulsification at a private healthcare facility. J. Cataract Refract. Surg. 2017;43(11):1391-98 doi: https://doi.org/10.1016/j.jcrs.2017.08.017
3. Hong-Gam Le JRE, Rengaraj Venkatesh, Aravind Srinivasan, Ajay Kolli, Aravind Haripriya, R. D. Ravindran, Thulasiraj Ravilla, Alan L. Robin, David W. Hutton, Joshua D. Stein. A Sustainable Model For Delivering High-Quality Efficient Cataract Surgery In Southern India. Health Aff. (Millwood). 2016;35(10):1783-90
4. Venkatesh R, van Landingham SW, Khodifad AM, et al. Carbon footprint and cost–effectiveness of cataract surgery. Curr. Opin. Ophthalmol. 2016;27(1):82-88
5. Grzybowski A, Wasinska-Borowiec W, Claoué C. Pros and cons of immediately sequential bilateral cataract surgery (ISBCS). Saudi Journal of Ophthalmology 2016;30(4):244-49 doi: 10.1016/j.sjopt.2016.09.001

Dear Editor,
We have read with interest the paper by Klimova et al. Some statements in the paper are confusing and may even mislead the readers.

The authors claim in the survival section of the paper that: "Vitreoretinal lymphoma is a life-threatening disease, with a 5-year survival rate of 71% in our study". Vitreoretinal lymphoma (VRL) may affect vision, and in very advanced cases that we rarely see in recent years, may destroy the eye. However, VRL per se is not what that kills the patients, but the associated brain lymphoma or in some case the systemic lymphoma.

According to the results in this study (and the title of the paper), "Combined (local and systemic) treatment in patients with PVRL showed favorable results in comparison with local therapy alone (p=0.695). However, the statistical significance was not reached". It is no wonder that they claim that combined treatment is better than local treatment when they have 60% relapses. However, no other study of intra-vitreal (IVit) Methotrexate showed such a high relapse rate. In our experience, the relapse rate is extremely low with IVit methotrexate alone. Actually, in summarizing our ten years results we had no recurrence of the intraocular disease (2) and summarizing now our 20-year experience with 113 eyes, we had only two cases of recurrences (unpublished data). It is difficult to explain the poor results of the authors’ patients, using either intravitreal methotrexate alone or in combination with systemic high dose methotrexate.

In their discussion, the authors write that "Vitreoretinal lymphomas are considered to be systemic disease….". It should be emphasized that this disease is in most cases a unique type of lymphoma that affects immune-privileged organs: the brain, the eye, and the testis, and only in some cases (17% in our experience), the eye disease accompanies systemic lymphoma.

References

1) Klimova A, Heissigerova J, Rihova E, et al. Combined treatment of primary vitreoretinal lymphomas significantly prolongs the time to first relapse. Br J Ophthalmol 2018, doi: 10.1136/bjophthalmol-2017-311574

2) Frenkel S, Hendler K, Siegal T, et al. Intravitreal methotrexate for treating vitreoretinal lymphoma: 10 years of experience. Br J Ophthalmol 2008;92:383-8.

Sincerely Yours,

Jacob Pe'er, M.D.
Shahar Frenkel, M.D., Ph.D.
Ocular Oncology Service
Department of Ophthalmology
Hadassah – Hebrew University Medical center
Jerusalem, Israel

Dear Sir,

We are writing this letter in response to a “letter to the editor” from Drs. Leahey and Meadows about our recently published paper “Second primary malignancies in retinoblastoma patients treated with intra-arterial chemotherapy: the first 10 years”.1 There are a number of incorrect statements in their letter and we hope this letter will clarify those errors made by them.

1) Drs. Leahey and Meadows state that…”the author’s report is profoundly misleading with regard to the risk of SPMs following OAC”. To prove that they then state that the median follow-up range is 2.5 years with a maximum follow-up of 12 years. How is that “profoundly misleading”? In the same paragraph they then state that patients failing OAC required radiation therapy and suggest that all of these second neoplasms are a consequence of radiation. That is not true. In our paper (page 273, Table 3) we documented that not one of the children who developed a second tumor had received radiation. How could radiation be the cause of a second tumor if the patients never received radiation? Dr. Leahey and Meadows also wrote that…”patients failing OAC require radiation”. That’s not true. On page 272 we stated that…”patients who received external beam radiation prior to presentation at our clinic were excluded from analysis”. None of the patients in this series received radiation after OAC and no patient in our center has received radiation in the past 10 years. We do not dispute that radiation affects the development of second cancers in germline affected retinoblastomas-but that is not the explanation for these cancers in our report.

2) In the many large series published worldwide on second cancers in retinoblastoma patients secondary AML does not appear to be a cancer that develops2,3 unless systemic chemotherapy is used4. In fact there are published series of secondary AML in retinoblastoma patients published prior to the introduction of OAC and in each case systemic chemotherapy was implicated as the cause. There has not been an increase in sAML in our patients treated with OAC and no other center has suggested or reported an increase in sAML after adopting OAC.

3) Drs. Leahey and Meadows imply that the Melphalan given for OAC is responsible for the secondary AML but that seems unlikely and is not consistent with the published, peer review literature. The Japanese used similar doses of Melphalan in their series of patients treated with intra-arterial chemotherapy (published in 2011) between 1988 and 2007.5 In their 343 patients they meticulously pointed out that long-term follow-up of these patients did not reveal an increase in second cancers and in fact all of the second cancers but one they attributed to the use of external beam radiation combined with chemotherapy. The one patient they had who developed secondary AML they attributed to the four courses of systemic chemotherapy utilizing Vincristine, Carboplatin and Etoposide. We don’t understand why Dr. Leahey and Meadows implicate the Melphalan but not the seven cycles of multiagent systemic chemotherapy they delivered. This child did not have AML while under our care. Finally, FLT3 mutations (present in this child) have usually been associated with topoisomerase induced sAML and de novo (no prior chemotherapy) sAML and not sAML from alkylating agents (e.g. Melphalan). 6 Their child’s sAML may be unrelated to any chemotherapy but more likely the systemic chemotherapy (with doses a hundred times the small amount of Melphalan delivered by OAC) is the culprit.

4) Secondary AML from chemotherapy is well known in pediatric oncology and well known by Drs. Leahey and Meadows. It is a devastating and often lethal complication of systemic chemotherapy and was the subject of a paper by Drs. Leahey and Meadows in 1999.7 They described this complication as a…”late effect of chemotherapy” in their cohort of 228 patients. We agree that secondary AML can be a late and devastating effect of systemic chemotherapy and that is why we have abandoned it for intraocular retinoblastoma and one of the reasons we developed OAC.

5) Drs. Leahey and Meadows correctly state that the goal of retinoblastoma is to cure the child of cancer (and suggest that OAC does not do that). A large, collaborative manuscript (which included their patients) was published a December 2017 on the worldwide experience with OAC8 since we introduced it in 20069. In 1139 patients who received 4396 infusions only three patients died of metastatic disease (all from Argentina and all had prior systemic chemotherapy). The conclusion is clear: using OAC to save children’s eyes and vision does not compromise patient survival.

6) Drs. Leahey and Meadows and the Philadelphia retinoblastoma team have considerable experience with OAC over the past 10 years and have published more than 20 papers on the subject. They have not published on their second tumor experience in the OAC era. We challenge them to collect and publish their data on second cancers in germline patients treated with OAC alone. If they have additional sAML cases we suggest their use of multi-agent systemic chemotherapy for retinoblastoma is the cause (as we abandoned that 12 years ago because of that well documented adverse effect).

7) We are saddened by this patient’s course but have no way of evaluating the risk/benefit discussion that Drs. Leahey and Meadows had with the family when they decided to use adjuvant multiagent chemotherapy which may have induced resistance and then a total of seven cycles of multiagent chemotherapy which are proven to cause secondary AML. The conclusion from this case is that we should all avoid systemic chemotherapy in retinoblastoma if there is a better option…and for intraocular disease fortunately there is: OAC.

References

1. Habib LA, Francis JH, Fabius AW, Gobin PY, Dunkel IJ, Abramson DH. Second primary malignancies in retinoblastoma patients treated with intra-arterial chemotherapy: the first 10 years. Br J Ophthalmol. 2018;102(2):272–275. doi:10.1136/bjophthalmol-2017-310328.

2. Kleinerman RA, Yu C-L, Little MP, et al. Variation of second cancer risk by family history of retinoblastoma among long-term survivors. J Clin Oncol. 2012;30(9):950–957. doi:10.1200/JCO.2011.37.0239.

3. Abramson DH, Frank CM. Second nonocular tumors in survivors of bilateral retinoblastoma: a possible age effect on radiation-related risk. Ophthalmology. 1998;105(4):573–9–discussion579–80. doi:10.1016/S0161-6420(98)94006-4.

4. Gombos DS, Hungerford J, Abramson DH, et al. Secondary acute myelogenous leukemia in patients with retinoblastoma: is chemotherapy a factor? Ophthalmology. 2007;114(7):1378–1383. doi:10.1016/j.ophtha.2007.03.074.

5. Suzuki S, Yamane T, Mohri M, Kaneko A. Selective ophthalmic arterial injection therapy for intraocular retinoblastoma: the long-term prognosis. Ophthalmology. 2011;118(10):2081–2087. doi:10.1016/j.ophtha.2011.03.013.

6. Godley LA, Larson RA. Therapy-related myeloid leukemia. Semin Oncol. 2008;35(4):418–429. doi:10.1053/j.seminoncol.2008.04.012.

7. Leahey AM, Teunissen H, Friedman DL, Moshang T, Lange BJ, Meadows AT. Late effects of chemotherapy compared to bone marrow transplantation in the treatment of pediatric acute myeloid leukemia and myelodysplasia. Med Pediatr Oncol. 1999;32(3):163–169.

8. Abramson DH, Shields CL, Jabbour P, et al. Metastatic deaths in retinoblastoma patients treated with intraarterial chemotherapy (ophthalmic artery chemosurgery) worldwide. Int J Retina Vitreous. 2017;3:40. doi:10.1186/s40942-017-0093-8.

9. Abramson DH, Dunkel IJ, Brodie SE, Kim JW, Gobin YP. A phase I/II study of direct intraarterial (ophthalmic artery) chemotherapy with melphalan for intraocular retinoblastoma initial results. Ophthalmology. 2008;115(8):1398–404–1404.e1. doi:10.1016/j.ophtha.2007.12.014.

Having read the article of secondary primary malignancies (SPM) in patients treated with ophthalmic artery chemosurgery (OAC) (1), we wish to update Dr. Habib’s report. A patient with unilateral Group D heritable retinoblastoma (RB) treated by their team with 5 OAC treatments in 2012 through 2013 developed acute myeloid leukemia (AML) on 4/26/2017 and died 3 months later.
Following an intraocular recurrence after OAC and subsequent enucleation the patient’s care was transferred to our institution. Despite adjuvant chemotherapy he developed widespread bone and marrow metastases 8 months after enucleation. He then underwent intensive chemotherapy and an autologous stem cell transplant. Twenty eight months later he developed AML with a fms-like tyrosine kinase 3 (FLT3) mutation. Melphalan administered during all OAC treatments and the drugs administered following that failure must be implicated in this outcome (2). By failing to eradicate retinoblastoma, metastatic disease ensued requiring further treatment and subsequently, AML.
The author’s report is profoundly misleading with regard to the risk of SPMs following OAC. Although the maximum period of follow-up is 12 years, the median is 2.5 years. Patients failing OAC required radiation therapy and are known to be 3 times more likely to develop additional cancers (3). We await that follow-up.
The goal of RB care is cure. This patient’s course illustrates the danger of failing to prevent metastatic disease with initial therapy. As Dr. Desjardins wrote in her recent review “ local administration [via OAC] cannot be used to treat micrometastases in advanced forms of the disease “ (4). Although metastatic RB can be treated if it develops (5), not all patients survive.

References:
1. Habib LA, Francis JH, Fabius A et al. Second primary malignancies in retinoblastoma patients treated with intra-arterial chemotherapy: the first 10 years. Br J Ophthalmol 2018; 102: 272-5.
2. Levine EG and Bloomfield CO. Leukemias and myelodysplastic syndromes secondary to drugs, radiation and environmental exposures. Semin Oncol 1982; 19: 471-84.
3. Kleinerman RA, Tucker MA, Tarone RE, et al. Risk of new cancers after radiotherapy in long-term survivors of retinoblastoma: an extended follow-up. J Clin Oncol 2005; 23: 2272-9.
4. Kassoux N, Lumbroso L, Levy-Gabriel C et al. Retinoblastoma: updates on current management. Asia-Pac J Ophthalmol 2017; 6: 290-5.
5. Dunkel IJ, Khakoo Y, Kernan NA et al. Intensive multi-modal therapy for patients with stage 4A metastatic retinoblastoma. Pediatr Blood Cancer 201; 55: 55-9.