Research Area/ Research Interest: Microfluidics

Research Paper Topics for Masters and Ph.D. Thesis and publication

1. Microfluidics-a review
2. The origins and the future of microfluidics
3. Physics and applications of microfluidics in biology
4.  Fundamentals and applications of microfluidics
5. The present and future role of microfluidics in biomedical research
6. Microfluidics: Fluid physics at the nanoliter scale
7. Microfluidics: basic issues, applications, and challenges
8. Droplet microfluidics
9.  Microfluidics for biotechnology
10.  Flexible methods for microfluidics
11.  Introduction to microfluidics
12.  Theoretical microfluidics
13. Inertial microfluidics
14. Magnetism and microfluidics
15. Microfluidics meets MEMS
16. Introduction: mixing in microfluidics
17. Emerging droplet microfluidics
18. Digital microfluidics
19. The digital revolution: a new paradigm for microfluidics
20. Droplet based microfluidics
21. Interplay between materials and microfluidics
22. Nonlinear microfluidics
23. Microfluidics for cell separation
24. Thermocapillarity in microfluidics—A review
25. Applications of microfluidics in chemical biology
26. Acoustic microfluidics
27. A review on mixing in microfluidics
28. A particle image velocimetry system for microfluidics
29.  Microfluidics and BioMEMS applications
30. Optical microfluidics
31. Fundamentals and applications of inertial microfluidics: A review
32. High-throughput injection with microfluidics using picoinjectors
33. Microdroplets in microfluidics: an evolving platform for discoveries in chemistry and biology
34. Lab-on-a-chip: microfluidics in drug discovery
35. 3D‐printed microfluidics
36. Rare cell isolation and analysis in microfluidics
37. Paper microfluidics goes digital
38.  Open microfluidics
39. New materials for microfluidics in biology
40. Microfluidics-based diagnostics of infectious diseases in the developing world
41. Microfluidics for manipulating cells
42. Microfluidics: reframing biological enquiry
43. Microfluidics-based systems biology
44. Microfluidics for food, agriculture and biosystems industries
45.  Suspended microfluidics
46. Droplet control for microfluidics
47. Microfluidics: applications for analytical purposes in chemistry and biochemistry
48. Discrete elements for 3D microfluidics
49. Microfluidics: the no-slip boundary condition
50. Membranes and microfluidics: a review
51. Fundamentals and applications of inertial microfluidics: A review
52. High-throughput injection with microfluidics using picoinjectors
53. Microdroplets in microfluidics: an evolving platform for discoveries in chemistry and biology
54. Lab-on-a-chip: microfluidics in drug discovery
55. 3D‐printed microfluidics
56. Rare cell isolation and analysis in microfluidics
57. Paper microfluidics goes digital
58.  Open microfluidics
59. New materials for microfluidics in biology
60. Microfluidics-based diagnostics of infectious diseases in the developing world
61. Microfluidics for manipulating cells
62. Microfluidics: reframing biological enquiry
63. Microfluidics-based systems biology
64. Microfluidics for food, agriculture and biosystems industries
65.  Suspended microfluidics
66. Droplet control for microfluidics
67. Microfluidics: applications for analytical purposes in chemistry and biochemistry
68. Discrete elements for 3D microfluidics
69. Microfluidics: the no-slip boundary condition
70. Membranes and microfluidics: a review
71. Microfluidics in inorganic chemistry
72. Microfluidics for biomedical analysis
73.  Microfluidics: modeling, mechanics and mathematics
74. Digital microfluidics: is a true lab-on-a-chip possible?
75. Microfluidics and cancer: are we there yet?
76. Microfluidics based magnetophoresis: A review
77. Reagents in microfluidics: an ‘in’and ‘out’challenge
78. Microfluidics for single cell analysis
79.  Microfluidics: technologies and applications
80. Integrating electronics and microfluidics on paper
81.  Fluid Mechanics for Chemical Engineers with Microfluidics and CFD.
82. Engineering flows in small devices: microfluidics toward a lab-on-a-chip
83.  Microfluidics for biological applications
84. Flexible microfluidics: Fundamentals, recent developments, and applications
85. The upcoming 3D-printing revolution in microfluidics
86. Cell manipulation in microfluidics
87. Surface acoustic wave microfluidics
88. Progress of inertial microfluidics in principle and application
89. Inertial focusing in microfluidics
90. Advances in microfluidics for environmental analysis
91.  Electrokinetics in microfluidics
92. 3D printed microfluidics
93. Nonlinear phenomena in microfluidics
94. Nanomaterials meet microfluidics
95. Magnetic digital microfluidics–a review
96. Microfluidics and point-of-care testing
97. Microfluidics: a new cosset for neurobiology
98. Biodegradable microfluidics
99.  Micro-drops and digital microfluidics
100. Soft lithography for microfluidics: a review
101. NutriChip: nutrition analysis meets microfluidics
102. 3D printed microfluidics for biological applications
103. Droplet microfluidics: recent developments and future applications
104. Deep learning with microfluidics for biotechnology
105. Centrifugal microfluidics for biomedical applications
106.  Microfluidics
107. Channel innovations for inertial microfluidics
108.  Viscoelastic microfluidics: Progress and challenges
109. Digital manufacturing for microfluidics
110.  Microfluidics in biotechnology
111. Microfluidics of nano-drug delivery
112.  Biological applications of microfluidics
113. Computational inertial microfluidics: A review
114. Nano/Microfluidics for diagnosis of infectious diseases in developing countries
115. Recent developments in microfluidics for cell studies
116. Thermophoresis: microfluidics characterization and separation
117. Microfluidics technology for manipulation and analysis of biological cells
118. Microscale acoustofluidics: Microfluidics driven via acoustics and ultrasonics
119. Microfluidics expanding the frontiers of microbial ecology
120. Microfluidics‐based biomaterials and biodevices
121. Microfluidics for processing surfaces and miniaturizing biological assays
122.  based microfluidics: Simplified fabrication and assay methods
123. Passive and active droplet generation with microfluidics: a review
124.  The fourth decade of microfluidics
125. Droplet microfluidics for high-throughput biological assays
126. Lattice Boltzmann method for microfluidics: models and applications
127. Optical imaging techniques in microfluidics and their applications
128. Surface acoustic wave microfluidics
129. PDMS microfluidics: A mini review
130. The potential impact of droplet microfluidics in biology
131. Bonding of thermoplastic polymer microfluidics
132. Desktop micromilled microfluidics
133. Digital microfluidics for cell-based assays
134. Microfluidics: a technology coming of age.
135. Recent advances in droplet microfluidics
136. Microfluidics for medical diagnostics and biosensors
137. The application of microfluidics in biology
138. Emerging open microfluidics for cell manipulation
139. Microfluidics: the great divide
140. Microfluidics for flow cytometric analysis of cells and particles
141. Microfluidics in structural biology: smaller, faster… better
142.  Microfluidics: fundamentals, devices, and applications
143. Surfactants in droplet-based microfluidics
144. Microfluidics and coagulation biology
145.  Encyclopedia of microfluidics and nanofluidics
146. Microfluidics for production of particles: mechanism, methodology, and applications
147. Parallel picoliter RT-PCR assays using microfluidics
148.  Designer emulsions using microfluidics
149. Discrete magnetic microfluidics
150. A perspective on paper-based microfluidics: Current status and future trends
151. Microfluidics—downsizing large-scale biology
152. Microfluidics based point‐of‐care diagnostics
153. Active droplet generation in microfluidics
154. A review on microdroplet generation in microfluidics
155. Microfluidics
156. Microfluidics in commercial applications; an industry perspective
157. Applications of microfluidics for neuronal studies
158. Analytical detection techniques for droplet microfluidics—A review
159.  Microfluidics based microsystems: fundamentals and applications
160. Microfluidics for research and applications in oncology
161. Droplet microfluidics—A tool for single‐cell analysis
162.  Droplet microfluidics for microbiology: techniques, applications and challenges
163. Why the move to microfluidics for protein analysis?
164. Particle manipulations in non-Newtonian microfluidics: A review
165. Connecting worlds–a view on microfluidics for a wider application
166. Microfluidics for advanced drug delivery systems
167. Microfluidics for drug development: From synthesis to evaluation
168. Electrochemical microfluidics
169.  Computational microfluidics for geosciences
170. Surface-chemistry technology for microfluidics
171. Co-designing electronics with microfluidics for more sustainable cooling
172. Microfluidics: on the slope of enlightenment
173.  Intelligent microfluidics: The convergence of machine learning and microfluidics in materials science and biomedicine
174. Thermoosmotic microfluidics
175. Microfluidics for sperm research
176.  Droplet microfluidics: from proof-of-concept to real-world utility?
177.  Droplet microfluidics: Fundamentals and its advanced applications
178. On the quantification of mixing in microfluidics
179. Numerical modeling of multiphase flows in microfluidics and micro process engineering: a review of methods and applications
180. Advances of microfluidics in biomedical engineering
181. Paper microfluidics for cell analysis
182.  Separation and purification of biomacromolecules based on microfluidics
183. Microfluidics: a new tool for modeling cancer–immune interactions
184. Polymer microfluidics: Simple, low-cost fabrication process bridging academic lab research to commercialized production
185. Laser processing for bio-microfluidics applications (part II)
186. Laser processing for bio-microfluidics applications (part I)
187. Dielectrophoresis in microfluidics technology
188. Developing optofluidic technology through the fusion of microfluidics and optics
189. Acoustically driven planar microfluidics
190. Shrinky-Dink microfluidics: rapid generation of deep and rounded patterns
191. Developments of 3D printing microfluidics and applications in chemistry and biology: a review
192. Digital microfluidics: a versatile tool for applications in chemistry, biology and medicine
193. Why microfluidics? Merits and trends in chemical synthesis
194. Tumors on chips: oncology meets microfluidics
195. Random design of microfluidics
196.  Progress of microfluidics for biology and medicine
197. Hydrodynamic mechanisms of cell and particle trapping in microfluidics
198. Advances in diagnostic microfluidics
199. Microfluidics for miniaturized laboratories on a chip
200. Magneto-hydrodynamics based microfluidics
201. Smartphone quantifies Salmonella from paper microfluidics
202.  Microfluidics with fluid walls
203. Emerging trends in microfluidics based devices
204. Shrinky-Dink microfluidics: 3D polystyrene chips
205. Microfluidics and microfabrication
206. Droplet-based microfluidics with nonaqueous solvents and solutions
207. Recent advances in applications of droplet microfluidics
208. 3D printed microfluidics and microelectronics
209. Single-cell analysis and sorting using droplet-based microfluidics
210.  Advancements in microfluidics for nanoparticle separation
211. Controllable preparation of particles with microfluidics
212. Multiphase flows in microfluidics
213. Microfluidics: innovations in materials and their fabrication and functionalization
214.  Microfabrication for microfluidics
215. Let’s get digital: digitizing chemical biology with microfluidics
216. Electrochemical detection for paper-based microfluidics
217. An optical toolbox for total control of droplet microfluidics
218. Future of Microfluidics in Research and in the Market
219. Stem cells in microfluidics
220. Exploring emulsion science with microfluidics
221. Generation of monodisperse particles by using microfluidics: control over size, shape, and composition
222. Droplet microfluidics in (bio) chemical analysis
223. Stem cells in microfluidics
224.  Small but perfectly formed? Successes, challenges, and opportunities for microfluidics in the chemical and biological sciences
225. Microfluidics for protein biophysics
226. Active droplet sorting in microfluidics: a review
227. The synthesis and assembly of polymeric microparticles using microfluidics
228. Microfluidics for cell-based high throughput screening platforms—A review
229. Applications of modular microfluidics technology
230.  Microfluidics and circulating tumor cells
231. Towards non-and minimally instrumented, microfluidics-based diagnostic devices
232. Microfluidics and Raman microscopy: current applications and future challenges
233.  Pressure-driven microfluidics
234.  Sample preparation: the weak link in microfluidics-based biodetection
235. Inertial microfluidics for continuous particle filtration and extraction
236.  Microfluidics as a tool for C. elegans research
237. Microfluidics
238. Hydrodynamic filtration for on-chip particle concentration and classification utilizing microfluidics
239. Recent developments of microfluidics as a tool for biotechnology and microbiology
240. Microfluidics for cryopreservation
241. Droplets formation and merging in two-phase flow microfluidics
242. Liquid metal enabled microfluidics
243.  Introduction: Microfluidics
244.  Cellular analysis using microfluidics
245. Centrifugal microfluidics for cell analysis
246. Droplet-based microfluidics at the femtolitre scale
247. Deformability study of breast cancer cells using microfluidics
248. Microfabrication and microfluidics for tissue engineering: state of the art and future opportunities
249. Advances in microfluidics in combating infectious diseases
250. Chip in a lab: Microfluidics for next generation life science research
251.  Droplet microfluidics on a planar surface
252. A review of digital microfluidics as portable platforms for lab-on a-chip applications
253. An optically driven pump for microfluidics
254. Torque-actuated valves for microfluidics
255. 3D printing: an emerging tool for novel microfluidics and lab-on-a-chip applications
256. Continuous scalable blood filtration device using inertial microfluidics
257. Microfluidics with droplets
258. Microfluidics and microbial engineering
259. Recent developments in microfluidics-based chemotaxis studies
260. Low-cost, rapid-prototyping of digital microfluidics devices
261. Microfluidics for sperm analysis and selection
262. Microfluidics for bacterial chemotaxis
263. Droplet microfluidics: A tool for biology, chemistry and nanotechnology
264. Oxygen control with microfluidics
265. Microfluidics: Honey, I shrunk the lab
266. Microfluidics in radiopharmaceutical chemistry
267. Microfluidics-based sensing of biospecies
268. Applications of microfluidics in stem cell biology
269. Review of membranes in microfluidics
270. Recent advances in microfluidics combined with mass spectrometry: technologies and applications
271. Ultrafast microfluidics using surface acoustic waves
272. Lab-on-a-Foil: microfluidics on thin and flexible films
273. Bio‐microfluidics: biomaterials and biomimetic designs
274. Printed microfluidics
275. Nonlinear microfluidics: device physics, functions, and applications
276. An integrated microfluidics-tandem mass spectrometry system for automated protein analysis
277. Electrowetting-based actuation of droplets for integrated microfluidics
278. Three-dimensional splitting microfluidics
279. Merging microfluidics with microarray-based bioassays
280. Microfluidics with foams
281. Preparation of nanoparticles by continuous-flow microfluidics
282. Gradient nanostructures for interfacing microfluidics and nanofluidics
283. Progress in the development and integration of fluid flow control tools in paper microfluidics
284. Electrochemistry, biosensors and microfluidics: a convergence of fields
285. Exploiting mechanical biomarkers in microfluidics
286. Single‐cell analysis using droplet microfluidics
287. Point-of-care diagnostics in low resource settings: present status and future role of microfluidics
288. Droplet microfluidics driven by gradients of confinement
289.  Microfluidics for biologists
290. Digital microfluidics using soft lithography
291. Multiscale phenomena in microfluidics and nanofluidics
292.  Liposome production by microfluidics: potential and limiting factors
293. Optical approach to resin formulation for 3D printed microfluidics
294.  A microfluidics-based in vitro model of the gastrointestinal human–microbe interface
295. Microfluidics-based assessment of cell deformability
296. Review and analysis of performance metrics of droplet microfluidics systems
297. Multiphase microfluidics: fundamentals, fabrication, and functions
298. Microfluidics: in search of a killer application
299. Surface-tension-confined microfluidics
300. Lights and shadows on food microfluidics
301. Probing circulating tumor cells in microfluidics
302. High-resolution dose–response screening using droplet-based microfluidics
303. Synergy of microfluidics and ultrasound
304. One-step formation of multiple emulsions in microfluidics
305. Microfluidics with ultrasound-driven bubbles
306. Passive valves based on hydrophobic microfluidics
307.  Open-source, community-driven microfluidics with Metafluidics
308. Controlled synthesis of nonspherical microparticles using microfluidics
309. Hard and soft micromachining for BioMEMS: review of techniques and examples of applications in microfluidics and drug delivery
310. Ensuring food safety: Quality monitoring using microfluidics
311. All-aqueous multiphase microfluidics
312. Microfluidics integrated biosensors: A leading technology towards lab-on-a-chip and sensing applications
313. based microfluidics for rapid diagnostics and drug delivery
314. Microfluidics with aqueous two-phase systems
315. DNA sequence analysis with droplet-based microfluidics
316. Trends in microfluidics with complex fluids
317. Building and manipulating neural pathways with microfluidics
318. Wettability control on multiphase flow in patterned microfluidics
319. Photopyroelectric microfluidics.

Research Topics Biology